BoomNet is a high-performance framework targeting development of low-latency network applications, particularly focusing on TCP stream-oriented clients that utilise various protocols.
Simply declare dependency on boomnet in your Cargo.toml and select desired features.
[dependencies]
boomnet = { version = "0.0.33", features = ["full"]}The framework is structured into multiple layers, with each subsequent layer building upon its predecessor, enhancing functionality and abstraction.
The first layer defines stream as abstraction over TCP connection, adhering to the following characteristics.
- Must implement
ReadandWritetraits for I/O operations. - Operates in a non-blocking manner.
- Integrates with TLS using
rustls. - Supports recording and replay of network byte streams.
- Allows binding to specific network interface.
- Facilitates implementation of TCP oriented client protocols such as WebSocket, HTTP, and FIX.
Streams are designed to be fully generic, avoiding dynamic dispatch, and can be composed in flexible way.,i
let stream: RecordedStream<TlsStream<TcpStream>> = TcpStream::try_from((host, port))?
.into_tls_stream()
.into_default_recorded_stream();Different protocols can then be applied on top of a stream in order to create a client.
let ws: Websocket<RecordedStream<TlsStream<TcpStream>>> = stream.into_websocket("/ws");Selector provides abstraction over OS specific mechanisms (like epoll) for efficiently monitoring socket readiness events.
Though primarily utilised internally, selectors are crucial for the IOService functionality, currently offering both
mio and direct (no-op) implementations.
let mut io_service = MioSelector::new()?.into_io_service();The last layer manages lifecycle of endpoints and provides auxiliary services (such as asynchronous DNS resolution and
auto disconnect) through the IOService.
Endpoint serves as low level construct for application logic. IOService oversees the connection lifecycle within endpoints.
The aim is to support a variety of protocols, including WebSocket, HTTP, and FIX, with WebSocket client functionality currently available.
The websocket client protocol complies with the RFC 6455 specification, offering the following features.
- Compatibility with any stream.
- TCP batch-aware frame processing.
- Not blocking on partial frame(s).
- Designed for zero-copy read and write.
- Optional masking of outbound frames.
- Standalone usage or in conjunction with
IOService.
The repository contains comprehensive list of examples.
The following example illustrates how to use multiple websocket connections with IOService in order to consume messages from the Binance cryptocurrency
exchange. First, we need to define and implement our Endpoint. The framework provides TlsWebsocketEndpoint trait
that we can use.
struct TradeEndpoint {
id: u32,
connection_info: ConnectionInfo,
ws_endpoint: String,
instrument: &'static str,
}
impl TradeEndpoint {
pub fn new(id: u32, url: &'static str, instrument: &'static str) -> TradeEndpoint {
let (connection_info, ws_endpoint, _) = boomnet::ws::util::parse_url(url).unwrap();
Self { id, connection_info, ws_endpoint, instrument, }
}
}
impl ConnectionInfoProvider for TradeEndpoint {
fn connection_info(&self) -> &ConnectionInfo {
&self.connection_info
}
}
impl TlsWebsocketEndpoint for TradeEndpoint {
type Stream = MioStream;
// called by the IO service whenever a connection has to be established for this endpoint
fn create_websocket(&mut self, addr: SocketAddr) -> io::Result<TlsWebsocket<Self::Stream>> {
let mut ws = TcpStream::try_from((&self.connection_info, addr))?
.into_mio_stream()
.into_tls_websocket(&self.ws_endpoint);
// send subscription message
ws.send_text(
true,
Some(format!(r#"{{"method":"SUBSCRIBE","params":["{}@trade"],"id":1}}"#, self.instrument).as_bytes()),
)?;
Ok(ws)
}
#[inline]
fn poll(&mut self, ws: &mut TlsWebsocket<Self::Stream>) -> io::Result<()> {
// iterate over available frames in the current batch
for frame in ws.batch_iter()? {
if let WebsocketFrame::Text(fin, data) = frame? {
println!("[{}] ({fin}) {}", self.id, String::from_utf8_lossy(data));
}
}
Ok(())
}
}After defining the endpoint, it is registered with the IOService and polled within an event loop. The service handles
Endpoint connection management and reconnection in case of disconnection.
fn main() -> anyhow::Result<()> {
let mut io_service = MioSelector::new()?.into_io_service();
let endpoint_btc = TradeEndpoint::new(0, "wss://stream1.binance.com:443/ws", "btcusdt");
let endpoint_eth = TradeEndpoint::new(1, "wss://stream2.binance.com:443/ws", "ethusdt");
let endpoint_xrp = TradeEndpoint::new(2, "wss://stream3.binance.com:443/ws", "xrpusdt");
io_service.register(endpoint_btc);
io_service.register(endpoint_eth);
io_service.register(endpoint_xrp);
loop {
// will never block
io_service.poll()?;
}
}It is often required to expose shared state to the Endpoint. This can be achieved with user defined Context.
struct FeedContext;
// use the marker trait
impl Context for FeedContext {}When implementing our TradeEndpoint we can use TlsWebsocketEndpointWithContext trait instead.
impl TlsWebsocketEndpointWithContext<FeedContext> for TradeEndpoint {
type Stream = MioStream;
fn url(&self) -> &str {
self.url
}
fn create_websocket(&mut self, addr: SocketAddr, ctx: &mut FeedContext) -> io::Result<TlsWebsocket<Self::Stream>> {
// we now have access to context
}
#[inline]
fn poll(&mut self, ws: &mut TlsWebsocket<Self::Stream>, ctx: &mut FeedContext) -> io::Result<()> {
// we now have access to context
}
}We will also need to create IOService that is Context aware.
let mut context = FeedContext::new(static_data);
let mut io_service = MioSelector::new()?.into_io_service_with_context(&mut context);The Context must now be passed to the service poll method.
loop {
io_service.poll(&mut context)?;
}BoomNet feature set is modular, allowing for tailored functionality based on project needs. The full feature enables
all available features, while individual components can be enabled as needed.
Adds dependency on mio crate and enables MioSelector and MioStream.
Adds dependency on rustls crate with rustls-native-certs and enables TlsStream as well as more flexible TlsReadyStream.
Adds dependency on rustls crate with webpki-roots and enables TlsStream as well as more flexible TlsReadyStream.
Adds support for Websocket protocol.