#actor-framework #actor #function #async #framework

nightly heph

Heph is an actor framework based on asynchronous functions

3 unstable releases

0.4.0 Apr 21, 2022
0.3.1 Aug 15, 2021
0.3.0 Apr 1, 2021
0.0.0 Dec 28, 2018

#730 in Asynchronous


Used in heph-rt

MIT license

160KB
2K SLoC

Heph

License: MIT Crates.io Docs

Heph, derived from Hephaestus, is the Greek god of blacksmiths, metalworking, carpenters, craftsmen, artisans, sculptors, metallurgy, fire, and volcanoes. Well this crate has very little to do with Greek gods, but I needed a name.

About

Heph is an actor framework based on asynchronous functions. Such an asynchronous function looks like this:

async fn actor(mut ctx: actor::Context<String, ThreadLocal>) {
    // Receive a message.
    let msg = ctx.receive_next().await;
    // Print the message.
    println!("got a message: {}", msg);
}

For more examples see the examples directory.

Design

Heph uses an event-driven, non-blocking I/O, share nothing design. But what do all those buzzwords actually mean?

  • Event-driven: Heph does nothing by itself, it must first get an event before it starts doing anything. For example when using a TcpListener it waits on a notification from the OS saying the TcpListener is ready before trying to accepted connections.
  • Non-blocking I/O: normal I/O operations need to wait (block) until the operation can complete. Using non-blocking, or asynchronous, I/O means that rather then waiting for the operation to complete we'll do some other more useful work and try the operation later.
  • Share nothing: a lot of application share data across multiple threads. To do this safely we need to protect it from data races, via a Mutex or by using atomic operations. Heph is designed to not share any data. Each actor is responsible for its own memory and cannot access memory owned by other actors. Instead communication is done via sending messages, see actor model.

Getting started

First you'll need a recent nightly compiler. The easiest way to install and manage different rust installations is via rustup. The following command will install a nightly compiler via rustup.

rustup install nightly # Install the latest nightly compiler.

# Optional:
rustup default nightly # Set the nightly compiler as default.

Second Heph needs to be added as a dependency.

[dependencies]
heph = "0.3.0"

Now you're ready to starting writing your application! Next you can look at some examples, or look at the API documentation.

Platform support

The main target platform is Linux, as a production target. But we also support macOS, but only as development target (e.g. develop on macOS and run Linux in production). Other BSDs are mostly supported (kqueue is fully supported), however no tests are run on these platforms.

Stability

Currently this project is unstable. Since the crate depends on many experimental or Nightly only Rust features. So it can only be compiled using a Nightly version of the rust compiler. Furthermore the since the crate itself is < v1, meaning the API is far from stable as well. In fact improvements to the API are very welcome!

License

Licensed under the MIT license (LICENSE or https://opensource.org/licenses/MIT).

Contribution

Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you shall be licensed as above, without any additional terms or conditions.

Inspiration

Heph is inspired by a number of other frameworks and languages. The greatest inspiration is the Erlang programming language. From Erlang the concept of processes, or rather a function as a process, is borrowed. In line with the actor model the processes (actors) can't access each others memory, instead message passing is used.

Another inspiration is the Akka framework for Scala and Java. Where Erlang is a functional language Akka is implemented in/for Scala and Java, languages more in line with Rust (both being object oriented, but having functional aspects). A lot of the API is inspired by the API provided in Akka, but there are a number of big differences. The main one being that Akka's actor are untyped (or at least can be), where Heph actors are strongly typed (just like Rust in general).

The final inspiration I would like to mention is Nginx, Nginx is a HTTP and reverse proxy server. The architecture used in Nginx is running a single master process (not a thread) that coordinates a number of workers processes (again not threads), each with their own polling instance (epoll/kqueue etc.) which all share the same TCP listeners. In early stages of development of Heph the idea was to start a new process per cpu core, must like Nginx. This would allow all atomic and locking operations to be dropped, later however this was changed to start threads instead to reduce the complexity when working with other libraries. In this design for example it wouldn't be possible to work with any libraries that started threads because then we could introduce data races, something that Rust tries very hard to avoid. Still most of the architecture was inspired by the one used in Nginx.

Building blocks

Besides the inspiration gained from the work of others, Heph is also build on top of the work of others. Three major components used in Heph are the futures task system (part of the standard library), asynchronous functions and Mio.

Dependencies

~350–520KB
~10K SLoC