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Library
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val sexp_of_t : t -> Ppx_sexp_conv_lib.Sexp.t
module Heartbeat_config : sig ... end
module Client_implementations : sig ... end
val create :
?implementations:'s Async_rpc_kernel__.Implementations.t ->
connection_state:(t -> 's) ->
?handshake_timeout:Core_kernel.Time_ns.Span.t ->
?heartbeat_config:Heartbeat_config.t ->
?description:Core_kernel.Info.t ->
?time_source:Async_kernel.Synchronous_time_source.t ->
Async_rpc_kernel__.Transport.t ->
(t, Core_kernel.Exn.t) Core_kernel.Result.t Async_kernel.Deferred.t
Initiate an Rpc connection on the given transport. implementations
should be the bag of implementations that the calling side implements; it defaults to Implementations.null
(i.e., "I implement no RPCs").
connection_state
will be called once, before create
's result is determined, on the same connection that create
returns. Its output will be provided to the implementations
when queries arrive.
WARNING: If specifying a custom heartbeat_config
, make sure that both ends of the Rpc connection use compatible settings for timeout and send frequency. Otherwise, your Rpc connections might close unexpectedly.
description
can be used to give some extra information about the connection, which will then show up in error messages and the connection's sexp. If you have lots of connections in your program, this can be useful for distinguishing them.
time_source
can be given to define the time_source for which the heartbeating events will be scheduled. Defaults to wall-clock.
As of Feb 2017, the RPC protocol started to contain a magic number so that one can identify RPC communication. The bool returned by contains_magic_prefix
says whether this magic number was observed.
val description : t -> Core_kernel.Info.t
val add_heartbeat_callback : t -> (unit -> unit) -> unit
After add_heartbeat_callback t f
, f ()
will be called on every subsequent heartbeat to t
.
val close :
?streaming_responses_flush_timeout:Core_kernel.Time_ns.Span.t ->
?reason:Core_kernel.Info.t ->
t ->
unit Async_kernel.Deferred.t
close
starts closing the connection's transport, and returns a deferred that becomes determined when its close completes. It is ok to call close
multiple times on the same t
; calls subsequent to the initial call will have no effect, but will return the same deferred as the original call.
Before closing the underlying transport's writer, close
waits for all streaming reponses to be Pipe.upstream_flushed
with a timeout of streaming_responses_flush_timeout
.
The reason
for closing the connection will be passed to callers of close_reason
.
val close_finished : t -> unit Async_kernel.Deferred.t
close_finished
becomes determined after the close of the connection's transport completes, i.e. the same deferred that close
returns. close_finished
differs from close
in that it does not have the side effect of initiating a close.
val close_reason :
t ->
on_close:[ `started | `finished ] ->
Core_kernel.Info.t Async_kernel.Deferred.t
close_reason ~on_close t
becomes determined when close starts or finishes based on on_close
, but additionally returns the reason that the connection was closed.
val is_closed : t -> bool
is_closed t
returns true
iff close t
has been called. close
may be called internally upon errors or timeouts.
val bytes_to_write : t -> int
bytes_to_write
and flushed
just call the similarly named functions on the Transport.Writer.t
within a connection.
val flushed : t -> unit Async_kernel.Deferred.t
val with_close :
?implementations:'s Async_rpc_kernel__.Implementations.t ->
?handshake_timeout:Core_kernel.Time_ns.Span.t ->
?heartbeat_config:Heartbeat_config.t ->
connection_state:(t -> 's) ->
Async_rpc_kernel__.Transport.t ->
dispatch_queries:(t -> 'a Async_kernel.Deferred.t) ->
on_handshake_error:
[ `Raise | `Call of Core_kernel.Exn.t -> 'a Async_kernel.Deferred.t ] ->
'a Async_kernel.Deferred.t
with_close
tries to create a t
using the given transport. If a handshake error is the result, it calls on_handshake_error
, for which the default behavior is to raise an exception. If no error results, dispatch_queries
is called on t
.
After dispatch_queries
returns, if server
is None, the t
will be closed and the deferred returned by dispatch_queries
wil be determined immediately. Otherwise, we'll wait until the other side closes the connection and then close t
and determine the deferred returned by dispatch_queries
.
When the deferred returned by with_close
becomes determined, Transport.close
has finished.
NOTE: Because this connection is closed when the Deferred.t
returned by dispatch_queries
is determined, you should be careful when using this with Pipe_rpc
. For example, simply returning the pipe when you get it will close the pipe immediately. You should instead either use the pipe inside dispatch_queries
and not determine its result until you are done with the pipe, or use a different function like create
.
val server_with_close :
?handshake_timeout:Core_kernel.Time_ns.Span.t ->
?heartbeat_config:Heartbeat_config.t ->
Async_rpc_kernel__.Transport.t ->
implementations:'s Async_rpc_kernel__.Implementations.t ->
connection_state:(t -> 's) ->
on_handshake_error:
[ `Raise
| `Ignore
| `Call of Core_kernel.Exn.t -> unit Async_kernel.Deferred.t ] ->
unit Async_kernel.Deferred.t
Runs with_close
but dispatches no queries. The implementations are required because this function doesn't let you dispatch any queries (i.e., act as a client), it would be pointless to call it if you didn't want to act as a server.
type ('rest, 'implementations) client_t =
?uri:Async_js__.Ocaml_uri.Uri.t ->
?heartbeat_config:Heartbeat_config.t ->
?description:Core_kernel.Info.t ->
?implementations:'implementations Client_implementations.t ->
'rest
This type of client connects to the websocket at the root of some host and port, i.e. ws://<address>/
.
val client : (unit -> t Async_kernel.Deferred.Or_error.t, 's) client_t
val client_exn : (unit -> t Async_kernel.Deferred.t, 's) client_t