package async_kernel

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module T1 : sig ... end

A time source has a phantom read-write parameter, where write gives permission to call advance and fire_past_alarms.

module Read_write : sig ... end
include sig ... end
val sexp_of_t : t -> Sexplib.Sexp.t
include Core_kernel.Invariant.S with type t := t
val invariant : t -> unit
val read_only : [> Core_kernel.read ] T1.t -> t
val create : ?timing_wheel_config:Core_kernel.Timing_wheel_ns.Config.t -> now:Core_kernel.Int63.t -> unit -> Core_kernel.read_write T1.t
val wall_clock : unit -> t

A time source with now t given by wall-clock time (i.e. Time_ns.now) and that is advanced automatically as time passes (specifically, at the start of each Async cycle). There is only one wall-clock time source; every call to wall_clock () returns the same value. The behavior of now is special for wall_clock (); it always calls Time_ns.now (), so it can return times that the time source has not yet been advanced to.

Accessors. now (wall_clock ()) behaves specially; see wall_clock above.

val next_alarm_fires_at : [> Core_kernel.read ] T1.t -> Core_kernel.Int63.t option
val timing_wheel_now : [> Core_kernel.read ] T1.t -> Core_kernel.Int63.t

Removes the special behavior of now for wall_clock; it always returns the timing_wheel's notion of now.

val advance : [> Core_kernel.write ] T1.t -> to_:Core_kernel.Int63.t -> unit

Unlike in Synchronous_time_source, advance function here only approximately determines the set of events to fire. You should also call fire_past_alarms if you want precision (see docs for Timing_wheel_ns.advance_clock vs Timing_wheel_ns.fire_past_alarms).

val fire_past_alarms : [> Core_kernel.write ] T1.t -> unit
val advance_by_alarms : [> Core_kernel.write ] T1.t -> to_:Core_kernel.Int63.t -> unit Async_kernel__.Types.Deferred.t

advance_by_alarms t repeatedly calls advance t to drive the time forward in steps, where each step is the minimum of to_ and the next alarm time. After each step, advance_by_alarms waits on Scheduler.yield () to allow a chance for the triggered alarms to run before moving forward, which also allows triggered timers to execute and potentially rearm for subsequent steps. The returned deferred is filled when to_ is reached.

advance_by_alarms is useful in simulation when one wants to efficiently advance to a time in the future while giving periodic timers (e.g. resulting from every) a chance to fire with approximately the same timing as they would live.

module Continue : sig ... end
val run_repeatedly : ?start:unit Async_kernel__.Types.Deferred.t -> ?stop:unit Async_kernel__.Types.Deferred.t -> ?continue_on_error:bool -> ?finished:unit Ivar.t -> [> Core_kernel.read ] T1.t -> f:(unit -> unit Async_kernel__.Types.Deferred.t) -> continue:Continue.t -> unit

See Clock.every' for documentation.

The functions below here are the same as in clock_intf.ml, except they take an explicit t argument. See clock_intf.ml for documentation.

val run_at : [> Core_kernel.read ] T1.t -> Core_kernel.Int63.t -> ('a -> unit) -> 'a -> unit
val run_after : [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> ('a -> unit) -> 'a -> unit
val at : [> Core_kernel.read ] T1.t -> Core_kernel.Int63.t -> unit Async_kernel__.Types.Deferred.t
val after : [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> unit Async_kernel__.Types.Deferred.t
val with_timeout : [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> 'a Async_kernel__.Types.Deferred.t -> [ `Timeout | `Result of 'a ] Async_kernel__.Types.Deferred.t
module Event : sig ... end
val at_varying_intervals : ?stop:unit Async_kernel__.Types.Deferred.t -> [> Core_kernel.read ] T1.t -> (unit -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t) -> unit Tail.Stream.t
val at_intervals : ?start:Core_kernel.Int63.t -> ?stop:unit Async_kernel__.Types.Deferred.t -> [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> unit Tail.Stream.t
val every' : ?start:unit Async_kernel__.Types.Deferred.t -> ?stop:unit Async_kernel__.Types.Deferred.t -> ?continue_on_error:bool -> ?finished:unit Ivar.t -> [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> (unit -> unit Async_kernel__.Types.Deferred.t) -> unit

See Clock.every' for documentation.

val every : ?start:unit Async_kernel__.Types.Deferred.t -> ?stop:unit Async_kernel__.Types.Deferred.t -> ?continue_on_error:bool -> [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> (unit -> unit) -> unit
val run_at_intervals' : ?start:Core_kernel.Int63.t -> ?stop:unit Async_kernel__.Types.Deferred.t -> ?continue_on_error:bool -> [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> (unit -> unit Async_kernel__.Types.Deferred.t) -> unit
val run_at_intervals : ?start:Core_kernel.Int63.t -> ?stop:unit Async_kernel__.Types.Deferred.t -> ?continue_on_error:bool -> [> Core_kernel.read ] T1.t -> Core_kernel.Core_kernel_private.Time_ns_alternate_sexp.Span.t -> (unit -> unit) -> unit
val of_synchronous : 'a Synchronous_time_source.T1.t -> 'a T1.t

Time_source and Synchronous_time_source are the same data structure and use the same underlying timing wheel. The types are freely interchangeable.

val to_synchronous : 'a T1.t -> 'a Synchronous_time_source.T1.t
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