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async-tungstenite/examples/client.rs

108 lines
3.9 KiB

//! A simple example of hooking up stdin/stdout to a WebSocket stream.
//!
//! This example will connect to a server specified in the argument list and
//! then forward all data read on stdin to the server, printing out all data
//! received on stdout.
//!
//! Note that this is not currently optimized for performance, especially around
//! buffer management. Rather it's intended to show an example of working with a
//! client.
//!
//! You can use this example together with the `server` example.
extern crate futures;
extern crate tokio;
extern crate tokio_tungstenite;
extern crate tungstenite;
extern crate url;
use std::env;
use std::io::{self, Read, Write};
use std::thread;
use futures::sync::mpsc;
use futures::{Future, Sink, Stream};
use tungstenite::protocol::Message;
use tokio_tungstenite::connect_async;
use tokio_tungstenite::stream::PeerAddr;
fn main() {
// Specify the server address to which the client will be connecting.
let connect_addr = env::args().nth(1).unwrap_or_else(|| {
panic!("this program requires at least one argument")
});
let url = url::Url::parse(&connect_addr).unwrap();
// Right now Tokio doesn't support a handle to stdin running on the event
// loop, so we farm out that work to a separate thread. This thread will
// read data from stdin and then send it to the event loop over a standard
// futures channel.
let (stdin_tx, stdin_rx) = mpsc::channel(0);
thread::spawn(|| read_stdin(stdin_tx));
let stdin_rx = stdin_rx.map_err(|_| panic!()); // errors not possible on rx
// After the TCP connection has been established, we set up our client to
// start forwarding data.
//
// First we do a WebSocket handshake on a TCP stream, i.e. do the upgrade
// request.
//
// Half of the work we're going to do is to take all data we receive on
// stdin (`stdin_rx`) and send that along the WebSocket stream (`sink`).
// The second half is to take all the data we receive (`stream`) and then
// write that to stdout. Currently we just write to stdout in a synchronous
// fashion.
//
// Finally we set the client to terminate once either half of this work
// finishes. If we don't have any more data to read or we won't receive any
// more work from the remote then we can exit.
let mut stdout = io::stdout();
let client = connect_async(url).and_then(move |(ws_stream, _)| {
println!("WebSocket handshake has been successfully completed");
let addr = ws_stream.peer_addr().expect("connected streams should have a peer address");
println!("Peer address: {}", addr);
// `sink` is the stream of messages going out.
// `stream` is the stream of incoming messages.
let (sink, stream) = ws_stream.split();
// We forward all messages, composed out of the data, entered to
// the stdin, to the `sink`.
let send_stdin = stdin_rx.forward(sink);
let write_stdout = stream.for_each(move |message| {
stdout.write_all(&message.into_data()).unwrap();
Ok(())
});
// Wait for either of futures to complete.
send_stdin.map(|_| ())
.select(write_stdout.map(|_| ()))
.then(|_| Ok(()))
}).map_err(|e| {
println!("Error during the websocket handshake occurred: {}", e);
io::Error::new(io::ErrorKind::Other, e)
});
// And now that we've got our client, we execute it in the event loop!
tokio::runtime::run(client.map_err(|_e| ()));
}
// Our helper method which will read data from stdin and send it along the
// sender provided.
fn read_stdin(mut tx: mpsc::Sender<Message>) {
let mut stdin = io::stdin();
loop {
let mut buf = vec![0; 1024];
let n = match stdin.read(&mut buf) {
Err(_) |
Ok(0) => break,
Ok(n) => n,
};
buf.truncate(n);
tx = tx.send(Message::binary(buf)).wait().unwrap();
}
}