πͺ A protobuf compiler for OCaml πͺ.
- Introduction
- Simple Example
- Install and Build
- Runtime library
- All Generated Files and Encodings
- Protobuf <-> OCaml mapping
- Services
- Compiler Internals
- Protobuf extensions
- Benchmarking
β¨ ocaml-protoc
compiles protobuf message files into
OCaml types along with serialization functions for a variety of encodings.
β¨ ocaml-protoc
supports both proto syntax 2 and 3 as well as binary and JSON encodings.
β¨ ocaml-protoc
supports JavaScript object encoding through the BuckleScript
compiler. See here for complete example.
This example generates the binary encoding, if you are more interested in a JavaScript example, go here
- Write in
example.proto
message Person {
required string name = 1;
required int32 id = 2;
optional string email = 3;
repeated string phone = 4;
}
- Run:
$ ocaml-protoc --binary --ml_out ./ example.proto
.. Generating example.mli
.. Generating example.ml
- example.mli:
(** example.proto Generated Types *)
(** {2 Types} *)
type person = {
name : string;
id : int32;
email : string;
phone : string list;
}
(** {2 Default values} *)
val default_person :
?name:string ->
?id:int32 ->
?email:string ->
?phone:string list ->
unit ->
person
(** [default_person ()] is the default value for type [person] *)
(** {2 Protobuf Encoding} *)
val encode_pb_person : person -> Pbrt.Encoder.t -> unit
(** [encode_pb_person v encoder] encodes [v] with the given [encoder] *)
(** {2 Protobuf Decoding} *)
val decode_pb_person : Pbrt.Decoder.t -> person
(** [decode_pb_person decoder] decodes a [person] binary value from [decoder] *)
- in
main.ml
, write the following to encode a person value and save it to a file:
let () =
(* Create OCaml value of generated type *)
let person = Example.({
name = "John Doe";
id = 1234l;
email = Some "jdoe@example.com";
phone = ["123-456-7890"];
}) in
(* Create a Protobuf encoder and encode value *)
let encoder = Pbrt.Encoder.create () in
Example.encode_pb_person person encoder;
(* Output the protobuf message to a file *)
let oc = open_out "myfile" in
output_bytes oc (Pbrt.Encoder.to_bytes encoder);
close_out oc
- then in the same
main.ml
append the following to read from the same file:
let () =
(* Read bytes from the file *)
let bytes =
let ic = open_in "myfile" in
let len = in_channel_length ic in
let bytes = Bytes.create len in
really_input ic bytes 0 len;
close_in ic;
bytes
in
(* Decode the person and Pretty-print it *)
Example.decode_pb_person (Pbrt.Decoder.of_bytes bytes)
- β Int32 vs int
OCaml users will immediately point to the use of int32
type in the generated code which might not be the most convenient choice.
One can modify this behavior using custom extensions.
Prerequesite
ocaml-protoc
only depends on
- the OCaml compiler distribution (byte code/native compiler).
- dune
- stdlib-shims for the compiler itself
- a C99 compiler for the runtime library's stubs
Intall from OPAM
$ opam install ocaml-protoc
Or from source
$ mkdir -p tmp/bin
$ export PREFIX=`pwd`/tmp
$ make install
Build your program
Using dune, the program can be compiled with:
(executable
(name main)
(modules main example)
(libraries pbrt))
More manually, the program can be built directly using ocamlfind:
$ ocamlfind ocamlopt -linkpkg -package pbrt \
-o example \
example.mli example.ml \
main.ml
π You can now run the example
$ ./example
The generated code depends on the opam package "pbrt", defining
a module Pbrt
.
Online documentation here
Command line switch | Description | Runtime |
---|---|---|
Type definition along with a default constructor function to conveniently create values of that type |
||
--make | make constructor functions |
|
--binary | Binary encodings | pbrt |
--yojson | JSON encoding using the widely popular yojson library | pbrt_yojson |
--bs | BuckleScript encoding using the BuckleScript core binding to JS json library | bs-ocaml-protoc-json |
--pp | pretty printing functions based on the Format module. | pbrt |
--services | RPC definitions. | pbrt_services |
see here.
With the --services
option, ocaml-protoc now generates stubs for service
declarations.
For example with the given calculator.proto
file:
syntax = "proto3";
message I32 {
int32 value = 0;
}
message AddReq {
int32 a = 1;
int32 b = 2;
}
service Calculator {
rpc add(AddReq) returns (I32);
rpc add_stream(stream I32) returns (I32);
}
Using ocaml-protoc --binary --services --ml_out=. calculator.proto
, we get the normal
type definitions, but also this service definition:
(** Calculator service *)
module Calculator : sig
open Pbrt_services
open Pbrt_services.Value_mode
module Client : sig
val add : (add_req, unary, i32, unary) Client.rpc
val add_stream : (i32, stream, i32, unary) Client.rpc
end
module Server : sig
(** Produce a server implementation from handlers *)
val make :
add:((add_req, unary, i32, unary) Server.rpc -> 'handler) ->
add_stream:((add_req, stream, i32, unary) Server.rpc -> 'handler) ->
unit -> 'handler Pbrt_services.Server.t
end
end
This can then potentially be used with libraries that implement specific protobuf-based network protocols, such as ocaml-grpc or ocaml-twirp, or other custom protocols.
Protobuf service endpoints take a single type and return a single type, but they have the ability
to stream either side. We represent this ability with the Pbrt_services.Value_mode
types:
(** Whether there's a single value or a stream of them *)
module Value_mode = struct
type unary
type stream
end
A (req, req_kind, res, res_kind) Client.rpc
is a bundle describing a single RPC endpoint,
from the client perspective. It contains the RPC name, service, etc. alongside encoders for
the request type req
, and decoders for the response type res
.
The phantom types req_kind
and res_kind
represent the value mode for request,
respectively response. Here we see that Calculator.Client.add
is unary for both
(it takes a single argument and returns a single value)
but Calculator.Client.add_stream
takes a string of i32
as parameters before
returning a single result.
With transports such as grpc, all 4 combinations are possible. With twirp over HTTP 1.1, only unary mode is supported.
On the server side, ocaml-protoc generates individual stubs,
like on the client side; but it also generates services as bundles
of endpoints. One service corresponds to a service
declaration
in the .proto
file.
Detailed explanation of how server-side services work
In practice, in something like twirp, a service could be added to a web server by adding each endpoint to a single HTTP route; or a twirp-aware router could directly map incoming HTTP queries to services.
The trickiest part here is that the type 'handler Pbrt_services.Server.t
is
parametric. Indeed it'd be hard for the generated code to cater to every possible
combination of network transport and concurrency library (eio, lwt, async, etc.).
Instead, the code is generic over 'handler
(the type of a query handler for a single
endpoint; e.g. a HTTP endpoint for a single route). The function
module Server : sig
val make :
add:((add_req, unary, i32, unary) Server.rpc -> 'handler) ->
add_stream:((add_req, stream, i32, unary) Server.rpc -> 'handler) ->
unit -> 'handler Pbrt_services.Server.t
end
seen previously is used to build the 'handler service
by asking the user
to provide a handler for each method. The builder for add
is given a
description of the add
endpoint (with decoders for requests; and encoders
for responses), and must return a handler that knows how to decode the request,
add numbers, and turn that back into a response.
Libraries will provide facilities to build such handlers, so that the user
only has to provide the actual logic (here, adding numbers). For example
in twirp_tiny_httpd
(part of ocaml-twirp
), implementing a
server looks like this1:
syntax = "proto3";
message I32 {
int32 value = 0;
}
message AddReq {
int32 a = 1;
int32 b = 2;
}
message AddAllReq {
repeated int32 ints = 1;
}
service Calculator {
rpc add(AddReq) returns (I32);
rpc add_all(AddAllReq) returns (I32);
}
let add (a : add_req) : i32 = default_i32 ~value:Int32.(add a.a a.b) ()
let add_all (a : add_all_req) : i32 =
let l = ref 0l in
List.iter (fun x -> l := Int32.add !l x) a.ints;
default_i32 ~value:!l ()
let calc_service : Twirp_tiny_httpd.handler Pbrt_services.Server.t =
Calculator.Server.make
~add:(fun rpc -> Twirp_tiny_httpd.mk_handler rpc add)
~add_all:(fun rpc -> Twirp_tiny_httpd.mk_handler rpc add_all)
()
let() =
let server = Tiny_httpd.create ~port:1234 () in
Twirp_tiny_httpd.add_service ~prefix:(Some "twirp") server calc_service;
Tiny_httpd.run_exn server
Here we see that all the logic is in add
and add_all
, which know nothing
about protobuf or serialization. A calc_service
bundle, using the Twirp_tiny_httpd.handler
type for each handler, is built from them. Finally, a HTTP server is created,
the service is added to it (binding some routes), and we enter the
server's main loop.
see here
see here
see here
Footnotes
-
we use a different
.proto
because twirp doesn't handle streams. β©