#module #norgopolis #database-access #parser #api #connection #own

norgopolis-module

A library for creating your own Norgopolis modules in Rust

8 releases (5 stable)

2.0.3 Feb 21, 2024
2.0.2 Feb 18, 2024
2.0.1 Dec 31, 2023
1.0.0 Dec 31, 2023
0.1.0 Jul 8, 2023

#878 in Parser implementations

Download history 35/week @ 2024-09-22 1/week @ 2024-09-29

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MIT license

20KB
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A Library for Creating Norgopolis Modules

For information about Norgopolis, consult https://github.com/nvim-neorg/norgopolis.

This library exposes an API for creating and maintaining a connection to the Norgopolis router. Norgopolis modules provide specific sets of functionality, for example multithreaded parsing, database access, etc. All of the default modules created by the Neorg team are built on top of this library.

[!NOTE] This is a library for developers. If you are a general user, feel free to check out the mainline Neorg repository or Norgopolis itself.

Setup

cargo add norgopolis-module

Modules are asynchronous applications that communicate with Norgopolis over stdin/stdout. The format transmitted across stdin/stdout is gRPC + MessagePack. For this reason it is highly recommended to add both tokio and tokio-stream to your dependencies.

Data that is transmitted over gRPC must be serializable. Be sure to add serde to your dependency list too!

Planning

The first phase of creating a module is deciding:

  • What sort of functionality the module will provide
  • What sort of inputs it will receive and what sort of data it will return

Input/output data is not enforced at the transmit layer - that is, an application has no idea what sort of data you expect as input and what sort of data you will return. This is a natural technical detail of dynamic gRPC + mpack communication. For this reason it is recommended to describe your API in a technical document somewhere in your repository for others to see.

Usage

General Setup

First, create a struct for your module. Name it whatever you'd like:

use norgopolis_module::{
    invoker_service::Service, module_communication::MessagePack, Code, Module, Status,
};

#[derive(Default)]
struct MyModule {
    // add any data or state you might need to maintain here...
}

Second, implement the norgopolis_module::invoker_service::Service trait for your struct. This forces you to implement a call function which will be invoked any time someone routes a message to your module. Since async traits are not stabilized within Rust yet, tag your trait implementation with #[norgopolis_module::async_trait]:

use tokio_stream::wrappers::UnboundedReceiverStream;

#[norgopolis_module::async_trait]
impl Service for MyModule {
    type Stream = UnboundedReceiverStream<Result<MessagePack, Status>>;

    async fn call(
        &self,
        function: String,
        args: Option<MessagePack>,
    ) -> Result<Self::Stream, Status> {
        todo!()
    }
}
Stream

The Stream type defines what sort of data will be returned back via gRPC. We recommend that you set it to UnboundedReceiverStream<Result<MessagePack, Status>>. This means that given one request your module will be able to return an infinite amount of MessagePack responses, or a status code in case something went wrong.

call

The call function gets invoked whenever a client routes a message to you. The message contains:

  • The function that they would like to invoke
  • An optional set of parameters they would like to supply to the function.

Creating the Basic Glue

In the call function it's recommended to match over all possible function names that your module supports and returning an error code if it's unsupported:

match function.as_str() {
    "my-function" => todo!(),
    _ => Err(Status::new(Code::NotFound, "Requested function not found!")),
}

[!IMPORTANT] It's always better to return some sort of status code over panicking. Panicking will terminate the connection to Norgopolis and the user will not receive any sort of error or warning.

Decoding the Parameters

If your function takes in any amount of parameters then now is the time to decode them. If your parameter is complex (e.g. a dictionary) then it's recommended to create a struct designated for it. Be sure to derive serde::Serialize:

#[derive(serde::Serialize)]
struct MyParameters {
    name: String,
}

Aftewards, it's a simple matter of running decode on your arguments:

match function.as_str() {
    "my-function" => {
        let args: MyParameters = args
            .unwrap() // WARNING: Don't actually use unwrap() in your code :)
            .decode()
            .map_err(|err| Status::new(Code::InvalidArgument, err.to_string()))?;

        // TODO: Do something with the parameters...
    },
}

We manually provide the type of args so that Rust knows what type to serialize to. Afterwards we wrap any possible errors into a status code which can be returned back to the client.

Sending Data back to the Client

Now that we have all of the input data in check we can process our data and return it back to the client. The way we do this is in the form of a data stream. Thanks to data streams we can return long segments of data over time instead of having to return the whole data upfront. When we return a segment of data, we also return it in the form of a Result<>. This is because individual segments of data may contain errors, but the whole process can complete succesfully. You should return errors from the call function when there is an irrecoverable error, but should send back an error packet when a portion of the internal logic fails.

Let's showcase all of this via an example:

match function.as_str() {
    "my-function" => {
        let args: MyParameters = args
            .unwrap() // WARNING: Don't actually use unwrap() in your code :)
            .decode()
            .map_err(|err| Status::new(Code::InvalidArgument, err.to_string()))?;

        let (tx, rx) = tokio::sync::mpsc::unbounded_channel();

        // We send back an Ok() packet to the client with an encoded message of our choice
        // (it can be anything that's serializable with serde!)
        tx.send(Ok(MessagePack::encode(format!("Hello, {}!", args.name)))).unwrap();

        Ok(UnboundedReceiverStream::new(rx))
    },
}

First, we create a sender and receiver via tokio's unbounded_channel(). This allows us to send data to the client and for the client to read data from the module. All return messages have to be encoded via MessagePack::encode.

Running the Module

Now that we have all of the code set up, create an asynchronous main function. In here we will instantiate our module and kick it into full gear:

#[tokio::main]
async fn main() {
    Module::new().start(MyModule::default())
        .await
        .unwrap()
}

Voila! You now have a fundamental understanding of how modules communicate with Norgopolis and how to write your own norgopolis module. Happy coding!

Dependencies

~7–16MB
~201K SLoC