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expose an optional Pool argument in most Future\'s combinators;

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handlers of a future are scheduled in pool rather than sequentially (to avoid
possible deadlocks among them)
This commit is contained in:
Simon Cruanes 2013-03-21 10:15:35 +01:00
parent 08d33095f6
commit e6eb9a79eb
2 changed files with 50 additions and 42 deletions
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80
future.ml
View file

@ -25,25 +25,6 @@ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
(** {1 Futures for concurrency} *)
type 'a t = {
mutable content : 'a result;
mutable handlers : 'a handler list; (* handlers *)
mutex : Mutex.t;
condition : Condition.t;
} (** A future value of type 'a *)
and 'a result =
| NotKnown
| Success of 'a
| Failure of exn
(** Result of a computation *)
and 'a handler =
| OnSuccess of ('a -> unit)
| OnFailure of (exn -> unit)
| OnFinish of (unit -> unit)
exception SendTwice
(** Exception raised when a future is evaluated several time *)
(** {2 MVar: a zero-or-one element thread-safe box} *)
module MVar = struct
@ -268,11 +249,34 @@ end
let default_pool = Pool.create ?timeout:None ~size:100
(** Default pool of threads, should be ok for most uses. *)
(** {2 Futures} *)
type 'a t = {
mutable content : 'a result;
mutable handlers : 'a handler list; (* handlers *)
pool : Pool.t;
mutex : Mutex.t;
condition : Condition.t;
} (** A future value of type 'a *)
and 'a result =
| NotKnown
| Success of 'a
| Failure of exn
(** Result of a computation *)
and 'a handler =
| OnSuccess of ('a -> unit)
| OnFailure of (exn -> unit)
| OnFinish of (unit -> unit)
exception SendTwice
(** Exception raised when a future is evaluated several time *)
(** {2 Basic Future functions} *)
let make () =
let make pool =
{ content = NotKnown;
handlers = [];
pool;
mutex = Mutex.create ();
condition = Condition.create ();
}
@ -305,8 +309,8 @@ let send future x =
Condition.broadcast future.condition;
List.iter
(function
| OnSuccess f -> f x
| OnFinish f -> f ()
| OnSuccess f -> Pool.run future.pool (fun () -> f x)
| OnFinish f -> Pool.run future.pool (fun () -> f ())
| OnFailure _ -> ())
future.handlers;
Mutex.unlock future.mutex
@ -348,7 +352,7 @@ let on_success future k =
(match future.content with
| NotKnown ->
future.handlers <- (OnSuccess k) :: future.handlers; (* wait *)
| Success x -> k x
| Success x -> Pool.run future.pool (fun () -> k x)
| Failure _ -> ());
Mutex.unlock future.mutex
@ -358,7 +362,7 @@ let on_failure future k =
| NotKnown ->
future.handlers <- (OnFailure k) :: future.handlers; (* wait *)
| Success _ -> ()
| Failure e -> k e);
| Failure e -> Pool.run future.pool (fun () -> k e));
Mutex.unlock future.mutex
let on_finish future k =
@ -366,11 +370,12 @@ let on_finish future k =
(match future.content with
| NotKnown ->
future.handlers <- (OnFinish k) :: future.handlers; (* wait *)
| Success _ | Failure _ -> k ());
| Success _ | Failure _ -> Pool.run future.pool (fun () -> k ()));
Mutex.unlock future.mutex
let flatMap f future =
let future' = make () in
let flatMap ?pool f future =
let pool = match pool with | Some p -> p | None -> future.pool in
let future' = make pool in
(* if [future] succeeds with [x], we spawn a new job to compute [f x] *)
on_success future
(fun x ->
@ -384,14 +389,14 @@ let flatMap f future =
(fun e -> fail future' e);
future'
let andThen future f =
flatMap (fun _ -> f ()) future
let andThen ?pool future f =
flatMap ?pool (fun _ -> f ()) future
let sequence futures =
let sequence ?(pool=default_pool) futures =
let a = Array.of_list futures in
let n = Array.length a in
let results = Array.make n NotKnown in
let future' = make () in
let future' = make default_pool in
(* state: how many remain to finish *)
let count = MVar.full (Array.length a) in
(* when all futures returned, collect results for future' *)
@ -425,8 +430,8 @@ let sequence futures =
done;
future'
let choose futures =
let future' = make () in
let choose ?(pool=default_pool) futures =
let future' = make default_pool in
let one_finished = MVar.full false in
(* handlers. The first handler to be called will update [one_finished]
to true, see that it was false (hence know it is the first)
@ -446,8 +451,8 @@ let choose futures =
futures;
future'
let map f future =
let future' = make () in
let map ?(pool=default_pool) f future =
let future' = make pool in
on_success future (fun x -> let y = f x in send future' y);
on_failure future (fun e -> fail future' e);
future'
@ -457,12 +462,13 @@ let map f future =
let return x =
{ content = Success x;
handlers = [];
pool = default_pool;
mutex = Mutex.create ();
condition = Condition.create ();
}
let spawn ?(pool=default_pool) f =
let future = make () in
let future = make pool in
(* schedule computation *)
Pool.run pool
(fun () ->
@ -508,6 +514,8 @@ let spawn_process ?(pool=default_pool) ?(stdin="") ~cmd =
| Unix.WSTOPPED i -> i in
(returncode, out', err'))
(* TODO a global scheduler for timed events *)
let sleep ?(pool=default_pool) time =
spawn ~pool
(fun () -> Thread.delay time; ())

12
future.mli
View file

@ -83,7 +83,7 @@ val default_pool : Pool.t
(** {2 Basic low-level Future functions} *)
val make : unit -> 'a t
val make : Pool.t -> 'a t
(** Create a future, representing a value that is not known yet. *)
val get : 'a t -> 'a
@ -111,19 +111,19 @@ val on_failure : _ t -> (exn -> unit) -> unit
val on_finish : _ t -> (unit -> unit) -> unit
(** Attach a handler to be called when the future is evaluated *)
val flatMap : ('a -> 'b t) -> 'a t -> 'b t
val flatMap : ?pool:Pool.t -> ('a -> 'b t) -> 'a t -> 'b t
(** Monadic combination of futures *)
val andThen : 'a t -> (unit -> 'b t) -> 'b t
val andThen : ?pool:Pool.t -> 'a t -> (unit -> 'b t) -> 'b t
(** Wait for the first future to succeed, then launch the second *)
val sequence : 'a t list -> 'a list t
val sequence : ?pool:Pool.t -> 'a t list -> 'a list t
(** Future that waits for all previous sequences to terminate *)
val choose : 'a t list -> 'a t
val choose : ?pool:Pool.t -> 'a t list -> 'a t
(** Choose among those futures (the first to terminate) *)
val map : ('a -> 'b) -> 'a t -> 'b t
val map : ?pool:Pool.t -> ('a -> 'b) -> 'a t -> 'b t
(** Maps the value inside the future *)
(** {2 Future constructors} *)