package rpclib-async
Install
Dune Dependency
Authors
Maintainers
Sources
sha256=aaa93cc249d95a119f834d7d2cdc47ea820af242065bb7f7841222ccd1936a39
sha512=0aa4a87535dde610b48c553e6de90f0d31233adf6a53424c34b5282b1ba1e1e223fd37f3e8d23efc4f165dfd2a4ed609c2692672ae04f9cadb35b04411e53e85
Description
ocaml-rpc
is a library that provides remote procedure calls (RPC)
using XML or JSON as transport encodings, and multiple generators
for documentations, clients, servers, javascript bindings, python
bindings, ...
The transport mechanism itself is outside the scope of this library as all conversions are from and to strings.
README
OCaml-RPC -- remote procedure calls (RPC) library
ocaml-rpc
is a library that provides remote procedure calls (RPC) using XML or JSON as transport encodings. The transport mechanism itself is outside the scope of this library as all conversions are from and to strings. The odoc
generated documentation is available at mirage.github.io/ocaml-rpc/rpclib.
RPC types
An RPC value is defined as follow:
type t =
Int of int64
| Int32 of int32
| Bool of bool
| Float of float
| String of string
| DateTime of string
| Enum of t list
| Dict of (string * t) list
| Base64 of string
| Null
Generating code
The idea behind ocaml-rpc
is to generate type definitions that can be used to convert values of a given type to and from their RPC representations.
In order to do so, it is sufficient to add [@@deriving rpcty]
to the corresponding type definition. Hence :
type t = ... [@@deriving rpcty]
This will give a value typ_of_t
of type Rpc.Types.typ
, which can be used in conjunction with the Rpcmarshal
module to:
Convert values of type
t
to values of typeRpc.t
:let rpc_of_t t = Rpcmarshal.marshal typ_of_t t
Convert values of type
Rpc.t
to values of typet
:let t_of_rpc rpc = Rpcmarshal.unmarshal typ_of_t rpc
Optionally, it is possible to have different field name in the OCaml type (if it is a record) and in the dictionary argument (the first elements of Dict
):
type t = { foo: int [@key "type"]; bar: int [@key "let"]; } [@@deriving rpcty]
This will replace "foo" by "type" and "bar" by "let" in the RPC representation. This is particularly useful when you want to integrate with an existing API and the field names are not valid OCaml identifiers.
The library also provides the [@@deriving rpc]
ppx, which is similar to rpcty
, but directly generates the conversion functions.
type t = ... [@@deriving rpc]
will give two functions:
A function to convert values of type
t
to values of typeRpc.t
:val rpc_of_t : t -> Rpc.t
A function to convert values of type
Rpc.t
to values of typet
:val t_of_rpc : Rpc.t -> (t,string) Result.result
It also supports the @key
annotations for having different field names:
type t = { foo: int [@key "type"]; bar: int [@key "let"]; } [@@deriving rpc]
Conversion functions
ocaml-rpc
currently support two protocols: XMLRPC and JSON(RPC). Function signatures are:
val Xmlrpc.to_string : Rpc.t -> string
val Xmlrpc.of_string : string -> Rpc.t
val Jsonrpc.to_string : Rpc.t -> string
val Jsonrpc.of_string : string -> Rpc.t
So if you want to marshal a value x of type t to JSON, you can use the following function:
Jsonrpc.to_string (rpc_of_t x)
IDL generator
The Idl
module makes it possible to define an abstract interface in OCaml using the following pattern:
module CalcInterface(R : Idl.RPC) = struct
open R
let int_p = Idl.Param.mk Rpc.Types.int
let add = R.declare "add"
["Add two numbers"]
(int_p @-> int_p @-> returning int_p Idl.DefaultError.err)
let mul = R.declare "mul"
["Multiply two numbers"]
(int_p @-> int_p @-> returning int_p Idl.DefaultError.err)
let implementation = implement
{ Idl.Interface.name = "Calc"; namespace = Some "Calc"; description = ["Calculator supporting addition and multiplication"]; version = (1,0,0) }
end
Then we can generate various "bindings" from it by passing a module implementing the RPC
signature to this functor:
OCaml bindings for clients or servers can be generated using one of the
GenClient*
orGenServer*
functors, respectively.For example one can generate an RPC client this way:
module CalcClient : sig val add : (Rpc.call -> Rpc.response) -> int -> int -> (int, Idl.DefaultError.t) result val mul : (Rpc.call -> Rpc.response) -> int -> int -> (int, Idl.DefaultError.t) result end = CalcInterface(Idl.GenClient ())
The functions in the resulting
CalcClient
module can be used to call their corresponding RPC methods.CalcClient
does not implement the transport mechanism itself, that should be provided by passing an a rpc function of typeRpc.call -> Rpc.response
.CalcClient.add rpc 4 5
will marshal the parameters4
and5
into their RPC representations, construct anRpc.call
, pass that call to the givenrpc
function, and return either anOk
containing the unmarshalled result or anError
with the error description depending on the response returned byrpc
.There are variations of the
GenClient
module:GenClientExn
raises an exception in case the response indicates a failure, instead of returning aresult
:module CalcClient : sig val add : (Rpc.call -> Rpc.response) -> int -> int -> int val mul : (Rpc.call -> Rpc.response) -> int -> int -> int end = CalcInterface(Idl.GenClientExn ())
and
GenClientExnRpc
allows one to specify the rpc function once when constructing the client module:module CalcClient : sig val add : int -> int -> int val mul : int -> int -> int end = CalcInterface(Idl.GenClientExnRpc (struct let rpc = rpc end))
Bindings for a server can be generated in a similar way:
module CalcServer : sig val add : (int -> int -> (int, Idl.DefaultError.t) result) -> unit val mul : (int -> int -> (int, Idl.DefaultError.t) result) -> unit val implementation : Idl.server_implementation end = CalcInterface(Idl.GenServer ())
The implementations of each RPC method should be specified by passing it to the corresponding function in
CalcServer
:CalcServer.add (fun a b -> Ok (a + b)); CalcServer.mul (fun a b -> Ok (a * b));
Then we can generate our server from the
implementation
(in case ofGenClient
,implementation
is unused):let rpc : (Rpc.call -> Rpc.response) = Idl.server CalcServer.implementation
Again, the transport mechanism is not implemented by
CalcServer
. We just get an rpc function that, given anRpc.call
, calls the implementation of that RPC method and performs the marshalling and unmarshalling. It is up to the user of this library to connect thisrpc
function to a real server that responds to client requests.Here we also have a
GenServerExn
functor, for server implementations that raise exceptions instead of returning aresult
.The
rpclib-lwt
andrpclib-async
packages provide similar client and server generators that useLwt
andAsync
, respectively.The
Xmlrpc
andJsonrpc
modules can be helpful when implementing therpc
function for an XML-RPC or JSON-RPC client/server: they provide functions for converting rpc requests and responses to/from their respective wire formats.Commandline interfaces can be generated using
Cmdlinergen
:module CalcCli : sig val implementation : unit -> ((Rpc.call -> Rpc.response) -> (unit -> unit) Cmdliner.Term.t * Cmdliner.Term.info) list end = CalcInterface(Cmdlinergen.Gen ())
We can use the
implementation
to construct the CLI. Again, we need to pass anrpc
function that knows how to make RPC calls.let () = let cmds = (List.map (fun t -> t rpc) (CalcCli.implementation ())) in let open Cmdliner in Term.(exit @@ eval_choice default_cmd cmds)
Some generators use the output of
Codegen
. This functor generates a structure that contains information about the methods, their parameters, return types, etc. Currently these generators that use the output ofCodegen
require the method parameters to be named.module CalcInterface(R : Idl.RPC) = struct open R let int_p_1 = Idl.Param.mk ~name:"int1" Rpc.Types.int let int_p_2 = Idl.Param.mk ~name:"int2" Rpc.Types.int let int_p = Idl.Param.mk Rpc.Types.int let add = R.declare "add" ["Add two numbers"] (int_p_1 @-> int_p_2 @-> returning int_p Idl.DefaultError.err) let implementation = implement { Idl.Interface.name = "Calc"; namespace = Some "Calc"; description = ["Calculator supporting addition and multiplication"]; version = (1,0,0) } end module CalcCode : sig val implementation : unit -> Codegen.Interface.t end = CalcInterface(Codegen.Gen ()) let interfaces = Codegen.Interfaces.create ~name:"calc" ~title:"Calculator" ~description:["Interface for a Calculator"] ~interfaces:[CalcCode.implementation ()]
Markdowngen
can generate a markdown file documenting these interfaces:let md = Markdowngen.to_string interfaces
Pythongen
can generate Python code that contains various classes wrapping a Python implementation, providing typechecking & method dispatch, and a CLI.let code = Pythongen.of_interfaces interfaces |> Pythongen.string_of_ts
The possibilities are not limited to the above generators provided by ocaml-rpc
. Any third-party module implementing the RPC
signature can be used to generate something from an interface defined following the above pattern. For example, it is possible to write an RPC
implementation that generates a GUI for a given interface.
Building
To build, first install the dependencies:
opam install dune base64 ppxlib async js_of_ocaml-ppx lwt cow cmdliner rresult yojson xmlm
For tests:
opam install alcotest alcotest-lwt
Dev Dependencies (2)
-
ppx_deriving_rpc
with-test & = version
-
alcotest
with-test
Used by (1)
-
ppx_deriving_rpc
>= "6.1.0" & < "7.1.0"
Conflicts
None