Görevler
Rust has a task system, which is a form of lightweight threading.
A task has a single top-level future which the executor polls to make progress. That future may have one or more nested futures that its poll
method polls, corresponding loosely to a call stack. Concurrency within a task is possible by polling multiple child futures, such as racing a timer and an I/O operation.
use tokio::io::{self, AsyncReadExt, AsyncWriteExt}; use tokio::net::TcpListener; #[tokio::main] async fn main() -> io::Result<()> { let listener = TcpListener::bind("127.0.0.1:0").await?; println!("listening on port {}", listener.local_addr()?.port()); loop { let (mut socket, addr) = listener.accept().await?; println!("connection from {addr:?}"); tokio::spawn(async move { socket.write_all(b"Who are you?\n").await.expect("socket error"); let mut buf = vec![0; 1024]; let name_size = socket.read(&mut buf).await.expect("socket error"); let name = std::str::from_utf8(&buf[..name_size]).unwrap().trim(); let reply = format!("Thanks for dialing in, {name}!\n"); socket.write_all(reply.as_bytes()).await.expect("socket error"); }); } }
Copy this example into your prepared src/main.rs
and run it from there.
Try connecting to it with a TCP connection tool like nc or telnet.
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Ask students to visualize what the state of the example server would be with a few connected clients. What tasks exist? What are their Futures?
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This is the first time we've seen an
async
block. This is similar to a closure, but does not take any arguments. Its return value is a Future, similar to anasync fn
. -
Refactor the async block into a function, and improve the error handling using
?
.