Library
Module
Module type
Parameter
Class
Class type
Module Lwt
: cooperative light-weight threads.
This module defines cooperative light-weight threads with their primitives. A light-weight thread represent a computation that may be not terminated, for example because it is waiting for some event to happen.
Lwt threads are cooperative in the sense that switching to another thread is awlays explicit (with wakeup
or wakeup_exn
). When a thread is running, it executes as much as possible, and then returns (a value or an error) or sleeps.
Note that inside a Lwt thread, exceptions must be raised with fail
instead of raise
. Also the try ... with ...
construction will not catch Lwt errors. You must use catch
instead. You can also use wrap
for functions that may raise normal exception.
Lwt also provides the syntax extension Pa_lwt
to make code using Lwt more readable.
val return : 'a -> 'a t
return e
is a thread whose return value is the value of the expression e
.
val fail : exn -> 'a t
fail e
is a thread that fails with the exception e
.
val fail_with : string -> 'a t
fail_with msg
is a thread that fails with the exception Failure msg
.
val fail_invalid_arg : string -> 'a t
fail_invalid_arg msg
is a thread that fails with the exception Invalid_argument msg
.
bind t f
is a thread which first waits for the thread t
to terminate and then, if the thread succeeds, behaves as the application of function f
to the return value of t
. If the thread t
fails, bind t f
also fails, with the same exception.
The expression bind t (fun x -> t')
can intuitively be read as let x = t in t'
, and if you use the lwt.syntax syntax extension, you can write a bind operation like that: lwt x = t in t'
.
Note that bind
is also often used just for synchronization purpose: t'
will not execute before t
is terminated.
The result of a thread can be bound several times.
Note that bind
will not propagate backtraces correctly. See <<a_api project="lwt" | The manual>> for how to enable backtraces.
map f m
maps the result of a thread. This is the same as bind
m (fun x -> return (f x))
val return_unit : unit t
return_unit = return ()
val return_none : 'a option t
return_none = return None
val return_some : 'a -> 'a option t
return_some x = return (Some x)
val return_nil : 'a list t
return_nil = return []
val return_true : bool t
return_true = return true
val return_false : bool t
return_false = return false
val new_key : unit -> 'a key
new_key ()
creates a new key.
val get : 'a key -> 'a option
get key
returns the value associated with key
in the current thread.
val with_value : 'a key -> 'a option -> (unit -> 'b) -> 'b
with_value key value f
executes f
with value
associated to key
. key
is restored to its previous value after f
terminates.
catch t f
is a thread that behaves as the thread t ()
if this thread succeeds. If the thread t ()
fails with some exception, catch t f
behaves as the application of f
to this exception.
try_bind t f g
behaves as bind (t ()) f
if t
does not fail. Otherwise, it behaves as the application of g
to the exception associated to t ()
.
finalize f g
returns the same result as f ()
whether it fails or not. In both cases, g ()
is executed after f
.
val wrap : (unit -> 'a) -> 'a t
wrap f
calls f
and transforms the result into an Lwt thread. If f
raises an exception, it is caught and converted to an Lwt exception.
This is actually the same as:
try
return (f ())
with exn ->
fail exn
val wrap1 : ('a -> 'b) -> 'a -> 'b t
wrap1 f x
applies f
on x
and returns the result as a thread. If the application of f
to x
raise an exception it is catched and a thread is returned.
Note that you must use wrap
instead of wrap1
if the evaluation of x
may raise an exception.
For example, the following code is incorrect:
wrap1 f (Hashtbl.find table key)
and should be written as:
wrap (fun () -> f (Hashtbl.find table key))
val wrap2 : ('a -> 'b -> 'c) -> 'a -> 'b -> 'c t
val wrap3 : ('a -> 'b -> 'c -> 'd) -> 'a -> 'b -> 'c -> 'd t
val wrap4 : ('a -> 'b -> 'c -> 'd -> 'e) -> 'a -> 'b -> 'c -> 'd -> 'e t
val wrap5 :
('a -> 'b -> 'c -> 'd -> 'e -> 'f) ->
'a ->
'b ->
'c ->
'd ->
'e ->
'f t
val wrap6 :
('a -> 'b -> 'c -> 'd -> 'e -> 'f -> 'g) ->
'a ->
'b ->
'c ->
'd ->
'e ->
'f ->
'g t
val wrap7 :
('a -> 'b -> 'c -> 'd -> 'e -> 'f -> 'g -> 'h) ->
'a ->
'b ->
'c ->
'd ->
'e ->
'f ->
'g ->
'h t
choose l
behaves as the first thread in l
to terminate. If several threads are already terminated, one is chosen at random.
Note: choose
leaves the local values of the current thread unchanged.
nchoose l
returns the value of all that have succcessfully terminated. If all threads are sleeping, it waits for at least one to terminates. If one the threads of l
fails, nchoose
fails with the same exception.
Note: nchoose
leaves the local values of the current thread unchanged.
nchoose_split l
does the same as nchoose
but also retrurns the list of threads that have not yet terminated.
join l
waits for all threads in l
to terminate. If one of the threads fails, then join l
will fails with the same exception as the first one to terminate.
Note: join
leaves the local values of the current thread unchanged.
val async : (unit -> 'a t) -> unit
async f
starts a thread without waiting for the result. If it fails (now or later), the exception is given to async_exception_hook
.
You should use this function if you want to start a thread that might fail and don't care what its return value is, nor when it terminates (for instance, because it is looping).
val ignore_result : 'a t -> unit
ignore_result t
is like Pervasives.ignore t
except that:
t
already failed, it raises the exception now,t
is sleeping and fails later, the exception will be given to async_exception_hook
.Function called when a asynchronous exception is thrown.
The default behavior is to print an error message with a backtrace if available and to exit the program.
The behavior is undefined if this function raise an exception.
See <<a_api project="lwt" | The manual>> for how to enable backtraces.
wait ()
is a pair of a thread which sleeps forever (unless it is resumed by one of the functions wakeup
, wakeup_exn
below) and the corresponding wakener. This thread does not block the execution of the remainder of the program (except of course, if another thread tries to wait for its termination).
val wakeup : 'a u -> 'a -> unit
wakeup t e
makes the sleeping thread t
terminate and return the value of the expression e
.
val wakeup_exn : 'a u -> exn -> unit
wakeup_exn t e
makes the sleeping thread t
fail with the exception e
.
val wakeup_later : 'a u -> 'a -> unit
Same as wakeup
but it is not guaranteed that the thread will be woken up immediately.
val wakeup_later_exn : 'a u -> exn -> unit
Same as wakeup_exn
but it is not guaranteed that the thread will be woken up immediately.
val make_value : 'a -> 'a result
value x
creates a result containing the value x
.
val make_error : exn -> 'a result
error e
creates a result containing the exception e
.
wakeup_result t r
makes the sleeping thread t
terminate with the result r
.
Same as wakeup_result
but it is not guaranteed that the thread will be woken up immediately.
val is_sleeping : 'a t -> bool
is_sleeping t
returns true
iff t
is sleeping.
Cancelable threads are the same as regular threads except that they can be canceled.
task ()
is the same as wait ()
except that threads created with task
can be canceled.
val on_cancel : 'a t -> (unit -> unit) -> unit
on_cancel t f
executes f
when t
is canceled. f
will be executed before all other threads waiting on t
.
If f
raises an exception it is given to async_exception_hook
.
val add_task_r : 'a u Lwt_sequence.t -> 'a t
add_task_r seq
creates a sleeping thread, adds its wakener to the right of seq
and returns its waiter. When the thread is canceled, it is removed from seq
.
val add_task_l : 'a u Lwt_sequence.t -> 'a t
add_task_l seq
creates a sleeping thread, adds its wakener to the left of seq
and returns its waiter. When the thread is canceled, it is removed from seq
.
val cancel : 'a t -> unit
protected thread
creates a new cancelable thread which behave as thread
except that cancelling it does not cancel thread
.
no_cancel thread
creates a thread which behave as thread
except that it cannot be canceled.
val pause : unit -> unit t
pause ()
is a sleeping thread which is wake up on the next call to wakeup_paused
. A thread created with pause
can be canceled.
wakeup_paused ()
wakes up all threads which suspended themselves with pause
.
This function is called by the scheduler, before entering the main loop. You usually do not have to call it directly, except if you are writing a custom scheduler.
Note that if a paused thread resumes and pauses again, it will not be woken up at this point.
register_pause_notifier f
register a function f
that will be called each time pause is called. The parameter passed to f
is the new number of threads paused. It is usefull to be able to call wakeup_paused
when there is no scheduler
val on_success : 'a t -> ('a -> unit) -> unit
on_success t f
executes f
when t
terminates without failing. If f
raises an exception it is given to async_exception_hook
.
val on_failure : 'a t -> (exn -> unit) -> unit
on_failure t f
executes f
when t
terminates and fails. If f
raises an exception it is given to async_exception_hook
.
val on_termination : 'a t -> (unit -> unit) -> unit
on_termination t f
executes f
when t
terminates. If f
raises an exception it is given to async_exception_hook
.
val on_any : 'a t -> ('a -> unit) -> (exn -> unit) -> unit
on_any t f g
executes f
or g
when t
terminates. If f
or g
raises an exception it is given to async_exception_hook
.
module Infix : sig ... end
Infix operators. You should open only this module.