A value that will become determined asynchronously.
A deferred can be "undetermined" or "determined". A deferred that is undetermined may at some point become determined with value v, and will henceforth always be determined with value v.
include sig ... end
val sexp_of_t : ('a ‑> Base.Sexp.t) ‑> 'a t ‑> Base.Sexp.t
include Core_kernel.Invariant.S1 with type a t := a t
val invariant : 'a Base__.Invariant_intf.inv ‑> 'a t Base__.Invariant_intf.inv
sexp_of_t t f
returns a sexp of the deferred's value, if it is determined, or an
informative string otherwise.
This is just for display purposes. There is no t_of_sexp
.
create f
calls f i
, where i
is an empty ivar. create
returns a deferred that
becomes determined when f
fills i
.
val upon : 'a t ‑> ('a ‑> unit) ‑> unit
upon t f
will run f v
at some point after t
becomes determined with value
v
.
val value_exn : 'a t ‑> 'a
value_exn t
returns v
if t
is determined with value v
, and raises
otherwise.
Deferreds form a monad.
let%bind v = t in f v
returns a deferred t'
that waits until t
is determined
with value v
, at which point it waits for f v
to become determined with value
v'
, to which t'
will become determined.
return v
returns a deferred that is immediately determined with value v.
Note that:
upon t f
is more efficient than:
ignore (let%bind a = t in f a; return ())
because upon
, unlike let%bind
, does not create a deferred to hold the result.
For example, one can write a loop that has good constant factors with:
let rec loop () =
upon t (fun a -> ... loop () ... )
although often forever
or repeat_until_finished
is more clear.
The same loop written with let%bind
would allocate deferreds that would be
immediately garbage collected. (In the past, this loop would have also used linear
space in recursion depth!)
In general, for deferreds that are allocated by let%bind
to be garbage collected
quickly, it is sufficient that the allocating bind be executed in tail-call position
of the right-hand side of an outer bind.
include Core_kernel.Monad with type a t := a t
include Base__.Monad_intf.S_without_syntax with type a t := a t
include Base__.Monad_intf.Infix with type a t := a t
module Monad_infix : Base__.Monad_intf.Infix with type a t := a t
module Infix : sig ... end
all ts
returns a deferred that becomes determined when every t
in t
s is
determined. The output is in the same order as the input.
val don't_wait_for : unit t ‑> unit
don't_wait_for t
ignores t
. It is like Fn.ignore
, but is more constrained
because it requires a unit Deferred.t
.
Rather than ignore (t : _ t)
, do don't_wait_for (Deferred.ignore t)
.
We chose to give don't_wait_for
type unit t
rather than _ t
to catch errors
where a value is accidentally ignored.
module Choice : sig ... end
A Choice.t
is used to produce an argument to enabled
or choose
. See below.
enabled [choice t1 f1; ... choice tn fn;]
returns a deferred d
that becomes
determined when any of the ti
becomes determined. The value of d
is a function
f
that when called, for each ti
that is enabled, applies fi
to ti
, and returns
a list of the results. It is guaranteed that the list is in the same order as the
choices supplied to enabled
, but of course it may be shorter than the input list if
not all ti
are determined.
choose [ choice t1 f1
; ...
; choice tn fn ]
returns a deferred t
that becomes determined with value fi ai
after some ti
becomes determined with value ai
. It is guaranteed that choose
calls at most one
of the fi
s, the one that determines its result. There is no guarantee
that the ti
that becomes determined earliest in time will be the one whose value
determines the choose
. Nor is it guaranteed that the value in t
is the first value
(in place order) from choices
that is determined at the time t
is examined.
For example, in:
choose [ choice t1 (fun () -> `X1)
; choice t2 (fun () -> `X2) ]
>>> function
| `X1 -> e1
| `X2 -> e2
it may be the case that both t1
and t2
become determined, yet e2
actually runs.
It is guaranteed that if multiple choices are determined with no intervening
asynchrony, then the earliest choice in the list will become the value of the
choose
.
val repeat_until_finished : 'state ‑> ('state ‑> [ `Repeat of 'state | `Finished of 'result ] t) ‑> 'result t
repeat_until_finished initial_state f
repeatedly runs f
until f
returns
`Finished
. The first call to f
happens immediately when repeat_until_finished
is called.
val forever : 'state ‑> ('state ‑> 'state t) ‑> unit
forever initial_state f
repeatedly runs f
, supplying the state returned to the
next call to f
.
val ok : 'a t ‑> ('a, _) Core_kernel.Result.t t
Useful for lifting values from the Deferred.t
monad to the Result.t Deferred.t
monad.
These contain operations for iterating in a deferred manner over different collection types.
module Array = Async_kernel__.Deferred_array
module List = Async_kernel__.Deferred_list
module Map = Async_kernel__.Deferred_map
module Memo = Async_kernel__.Deferred_memo
module Queue = Async_kernel__.Deferred_queue
module Sequence = Async_kernel__.Deferred_sequence
These contain interfaces for working with deferred type containing error-aware types,
like 'a Option.t Deferred.t
, or 'a Or_error.t Deferred.t
. These all include
support for monadic programming.
module Option = Async_kernel__.Deferred_option
module Or_error = Async_kernel__.Deferred_or_error
module Result = Async_kernel__.Deferred_result