package lwt_eio
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README.md.html
Lwt_eio - run Lwt code from within Eio
Lwt_eio is a Lwt engine that uses Eio. It can be used to run Lwt and Eio code in a single domain. It allows converting existing code to Eio incrementally.
See lib/lwt_eio.mli
for the API.
The examples directory contains some example programs and instructions on using them.
Porting a Lwt Application to Eio
This guide will show how to migrate an existing Lwt application or library to Eio. We'll start with this Lwt program, which reads in a list of lines, sorts them, and writes the result to stdout:
# #require "lwt.unix";;
# open Lwt.Syntax;;
# let process_lines src fn =
let stream = Lwt_io.read_lines src in
let* lines = Lwt_stream.to_list stream in
let* lines = fn lines in
let rec write = function
| [] -> Lwt.return_unit
| x :: xs ->
let* () = Lwt_io.(write_line stdout) x in
write xs
in
let* () = write lines in
Lwt_io.(flush stdout);;
val process_lines :
Lwt_io.input_channel -> (string list -> string list Lwt.t) -> unit Lwt.t =
<fun>
# let sort src =
process_lines src @@ fun lines ->
let* () = Lwt.pause () in (* Simulate async work *)
Lwt.return (List.sort String.compare lines);;
val sort : Lwt_io.input_channel -> unit Lwt.t = <fun>
# Lwt_main.run begin
let input = Lwt_io.(of_bytes ~mode:input)
(Lwt_bytes.of_bytes (Bytes.of_string "b\na\nd\nc\n")) in
sort input
end;;
a
b
c
d
- : unit = ()
The first step is to replace Lwt_main.run
, and check that the program still works:
# #require "eio_main";;
# #require "lwt_eio";;
# open Eio.Std;;
# Eio_main.run @@ fun env ->
Lwt_eio.with_event_loop ~clock:env#clock @@ fun _ ->
Lwt_eio.run_lwt @@ fun () ->
let input = Lwt_io.(of_bytes ~mode:input)
(Lwt_bytes.of_bytes (Bytes.of_string "b\na\nd\nc\n")) in
sort input;;
a
b
c
d
- : unit = ()
Here, we're using the Eio event loop instead of the normal Lwt one, but everything else stays the same:
Eio_main.run
starts the Eio event loop, replacingLwt_main.run
.Lwt_eio.with_event_loop
starts the Lwt event loop, using Eio as its backend.Lwt_eio.run_lwt
switches from Eio context to Lwt context.
Any piece of code is either Lwt code or Eio code. You use run_lwt
and run_eio
to switch back and forth as necessary (run_lwt
lets Eio code call Lwt code, while run_eio
lets Lwt code call Eio).
Note: When I first tried the conversion, it failed with Fatal error: exception Unhandled
because I'd forgotten to flush stdout in the Lwt code. That meant that sort
returned before Lwt had completely finished and then it tried to flush lazily after the Eio loop had finished, which is an error.
We can now start converting code to Eio. There are several places we could start. Here we'll begin with the process_lines
function. We'll take an Eio flow instead of a Lwt_io input:
# let process_lines src fn =
let* lines =
Lwt_eio.run_eio @@ fun () ->
Eio.Buf_read.of_flow src ~max_size:max_int
|> Eio.Buf_read.lines
|> List.of_seq
in
let* lines = fn lines in
let rec write = function
| [] -> Lwt.return_unit
| x :: xs ->
let* () = Lwt_io.(write_line stdout) x in
write xs
in
let* () = write lines in
Lwt_io.(flush stdout);;
val process_lines :
[> Eio__Flow.source_ty ] r ->
(string list -> string list Lwt.t) -> unit Lwt.t = <fun>
Note that process_lines
is still a Lwt function, but it now uses run_eio
internally to read from the input using Eio.
Warning: It's important not to call Eio functions directly from Lwt, but instead wrap such code with run_eio
. If you replace the Lwt_eio.run_eio @@ fun () ->
line with Lwt.return @@
then it will appear to work in simple cases, but it will act as a blocking read from Lwt's point of view. It's similar to trying to turn a blocking call like Stdlib.input_line
into an asynchronous one using Lwt.return
. It doesn't actually make it concurrent. Using Lwt_eio.with_event_loop ~debug:true
will detect these problems, by blocking effects when in Lwt mode.
We can now test it using an Eio flow:
# let sort src =
process_lines src @@ fun lines ->
let* () = Lwt.pause () in (* Simulate async work *)
Lwt.return (List.sort String.compare lines);;
val sort : [> Eio__Flow.source_ty ] r -> unit Lwt.t = <fun>
# Eio_main.run @@ fun env ->
Lwt_eio.with_event_loop ~debug:true ~clock:env#clock @@ fun _ ->
Lwt_eio.run_lwt @@ fun () ->
sort (Eio.Flow.string_source "b\na\nd\nc\n");;
a
b
c
d
- : unit = ()
Let's finish converting process_lines
:
# let process_lines ~src ~dst fn =
Eio.Buf_read.of_flow src ~max_size:max_int
|> Eio.Buf_read.lines
|> List.of_seq
|> fn
|> List.iter (fun line ->
Eio.Flow.copy_string (line ^ "\n") dst
);;
val process_lines :
src:[> Eio__Flow.source_ty ] r ->
dst:[> Eio.Flow.sink_ty ] r -> (string list -> string list) -> unit = <fun>
Now process_lines
is an Eio function. The Lwt.t
types have disappeared from its signature.
Note that we now take an extra dst
argument for the output: Eio functions should always receive access to external resources explicitly.
To use the new version, we'll have to update sort
to wrap its Lwt callback:
# let sort ~src ~dst =
process_lines ~src ~dst @@ fun lines ->
Lwt_eio.run_lwt @@ fun () ->
let* () = Lwt.pause () in (* Simulate async work *)
Lwt.return (List.sort String.compare lines);;
val sort :
src:[> Eio__Flow.source_ty ] r -> dst:[> Eio.Flow.sink_ty ] r -> unit =
<fun>
sort
itself now looks like a normal Eio function from its signature. We can therefore now call it directly from Eio:
# Eio_main.run @@ fun env ->
Lwt_eio.with_event_loop ~debug:true ~clock:env#clock @@ fun _ ->
sort
~src:(Eio.Flow.string_source "b\na\nd\nc\n")
~dst:env#stdout;;
a
b
c
d
- : unit = ()
Finally, we can convert sort
's callback to Eio code and drop the use of Lwt
and Lwt_eio
completely:
# let sort ~src ~dst =
process_lines ~src ~dst @@ fun lines ->
Fiber.yield (); (* Simulate async work *)
List.sort String.compare lines;;
val sort :
src:[> Eio__Flow.source_ty ] r -> dst:[> Eio.Flow.sink_ty ] r -> unit =
<fun>
# Eio_main.run @@ fun env ->
sort
~src:(Eio.Flow.string_source "b\na\nd\nc\n")
~dst:env#stdout;;
a
b
c
d
- : unit = ()
Key points:
Start by replacing
Lwt_main.run
while keeping the rest of the code the same.Update your program piece by piece, using
Lwt_eio
when moving between Eio and Lwt contexts.Never call Eio code directly from Lwt code. Wrap it with
Lwt_eio.run_eio
. Simply wrapping the result of an Eio call withLwt.return
is NOT safe.Almost all uses of Lwt promises (
Lwt.t
) should disappear (do not blindly replace Lwt promises with Eio promises).You don't have to do the conversion in any particular order.
You may need to make other changes to your API. In particular:
External resources (such as
stdout
, the network and the filesystem) should be passed as inputs to Eio code.Take a
Switch.t
argument if your function creates fibers or file handles that out-live the function.If you are writing a library that requires
Lwt_eio
, consider having its main function (if any) take a value of typeLwt_eio.Token.t
. This will remind users of the library to initialise Lwt_eio first.
For a more in-depth example, see the ICFP 2023 Lwt-to-Eio porting tutorial.
Limitations
Lwt code can only run in a single domain, and using
Lwt_eio
does not change this. You can only run Lwt code in the domain that ranLwt_eio.with_event_loop
.Lwt_eio
does not make your Lwt programs run faster than before. Lwt jobs are still run by Lwt, and do not take advantage of Eio'sio_uring
support, for example.Lwt_unix.fork
internally usesUnix.fork
, and therefore cannot be used when multiple domains are active.
How it works
Integration with Lwt is quite simple, as Lwt already has support for pluggable event loops. When Lwt wants to wait for a file descriptor to become ready, it calls Lwt_eio, which forks a new Eio fiber to perform the appropriate operation (Eio_unix.await_readable
, etc) and then calls Lwt's callback.
If Lwt wants to run a blocking operation, it will use a thread from its pool of systhreads to do that. When the operation is complete, the systhread signals the main thread by making a notification file descriptor become ready, and this is then picked up by the main event loop in the usual way.
Signals registered with Lwt_unix.on_signal
likewise work by waking the main thread.
What all of this means is that Lwt threads and Eio fibers are scheduled using a single queue and do not starve each other (any more than cooperative threads would do when not mixing concurrency systems).
If an Eio fiber is cancelled while running run_lwt
, it cancels the Lwt promise too. If the Lwt promise returned by run_eio
is cancelled, the Eio fiber is cancelled too.
See test/test.md for some tests of this.