//!run with //! ```bash //! RUST_BACKTRACE=1 cargo run --example chat -- --trace=info --port 15006 //! RUST_BACKTRACE=1 cargo run --example chat -- --trace=info --port 15006 --mode=client //! ``` use clap::{App, Arg}; use std::{sync::Arc, thread, time::Duration}; use tokio::{io, io::AsyncBufReadExt, runtime::Runtime, sync::RwLock}; use tracing::*; use tracing_subscriber::EnvFilter; use veloren_network::{Network, Participant, Pid, Promises, ProtocolAddr}; ///This example contains a simple chatserver, that allows to send messages /// between participants, it's neither pretty nor perfect, but it should show /// how to integrate network fn main() { let matches = App::new("Chat example") .version("0.1.0") .author("Marcel Märtens ") .about("example chat implemented with veloren-network") .arg( Arg::with_name("mode") .short("m") .long("mode") .takes_value(true) .possible_values(&["server", "client", "both"]) .default_value("both") .help( "choose whether you want to start the server or client or both needed for \ this program", ), ) .arg( Arg::with_name("port") .short("p") .long("port") .takes_value(true) .default_value("52000") .help("port to listen on"), ) .arg( Arg::with_name("ip") .long("ip") .takes_value(true) .default_value("127.0.0.1") .help("ip to listen and connect to"), ) .arg( Arg::with_name("protocol") .long("protocol") .takes_value(true) .default_value("tcp") .possible_values(&["tcp", "upd", "mpsc"]) .help( "underlying protocol used for this test, mpsc can only combined with mode=both", ), ) .arg( Arg::with_name("trace") .short("t") .long("trace") .takes_value(true) .default_value("warn") .possible_values(&["trace", "debug", "info", "warn", "error"]) .help("set trace level, not this has a performance impact!"), ) .get_matches(); let trace = matches.value_of("trace").unwrap(); let filter = EnvFilter::from_default_env().add_directive(trace.parse().unwrap()); tracing_subscriber::FmtSubscriber::builder() .with_max_level(Level::TRACE) .with_env_filter(filter) .init(); let port: u16 = matches.value_of("port").unwrap().parse().unwrap(); let ip: &str = matches.value_of("ip").unwrap(); let address = match matches.value_of("protocol") { Some("tcp") => ProtocolAddr::Tcp(format!("{}:{}", ip, port).parse().unwrap()), Some("udp") => ProtocolAddr::Udp(format!("{}:{}", ip, port).parse().unwrap()), _ => panic!("invalid mode, run --help!"), }; let mut background = None; match matches.value_of("mode") { Some("server") => server(address), Some("client") => client(address), Some("both") => { let address1 = address.clone(); background = Some(thread::spawn(|| server(address1))); thread::sleep(Duration::from_millis(200)); //start client after server client(address) }, _ => panic!("invalid mode, run --help!"), }; if let Some(background) = background { background.join().unwrap(); } } fn server(address: ProtocolAddr) { let r = Arc::new(Runtime::new().unwrap()); let server = Network::new(Pid::new(), &r); let server = Arc::new(server); let participants = Arc::new(RwLock::new(Vec::new())); r.block_on(async { server.listen(address).await.unwrap(); loop { let p1 = Arc::new(server.connected().await.unwrap()); let server1 = server.clone(); participants.write().await.push(p1.clone()); tokio::spawn(client_connection(server1, p1, participants.clone())); } }); } async fn client_connection( _network: Arc, participant: Arc, participants: Arc>>>, ) { let mut s1 = participant.opened().await.unwrap(); let username = s1.recv::().await.unwrap(); println!("[{}] connected", username); loop { match s1.recv::().await { Err(_) => { break; }, Ok(msg) => { println!("[{}]: {}", username, msg); for p in participants.read().await.iter() { match p .open(4, Promises::ORDERED | Promises::CONSISTENCY, 0) .await { Err(_) => info!("error talking to client, //TODO drop it"), Ok(mut s) => s.send((username.clone(), msg.clone())).unwrap(), }; } }, } } println!("[{}] disconnected", username); } fn client(address: ProtocolAddr) { let r = Arc::new(Runtime::new().unwrap()); let client = Network::new(Pid::new(), &r); r.block_on(async { let p1 = client.connect(address.clone()).await.unwrap(); //remote representation of p1 let mut s1 = p1 .open(4, Promises::ORDERED | Promises::CONSISTENCY, 0) .await .unwrap(); //remote representation of s1 let mut input_lines = io::BufReader::new(io::stdin()); println!("Enter your username:"); let mut username = String::new(); input_lines.read_line(&mut username).await.unwrap(); username = username.split_whitespace().collect(); println!("Your username is: {}", username); println!("write /quit to close"); tokio::spawn(read_messages(p1)); s1.send(username).unwrap(); loop { let mut line = String::new(); input_lines.read_line(&mut line).await.unwrap(); line = line.split_whitespace().collect(); if line.as_str() == "/quit" { println!("goodbye"); break; } else { s1.send(line).unwrap(); } } }); thread::sleep(Duration::from_millis(30)); // TODO: still needed for correct shutdown } // I am quite lazy, the sending is done in a single stream above, but for // receiving i open and close a stream per message. this can be done easier but // this allows me to be quite lazy on the server side and just get a list of // all participants and send to them... async fn read_messages(participant: Participant) { while let Ok(mut s) = participant.opened().await { let (username, message) = s.recv::<(String, String)>().await.unwrap(); println!("[{}]: {}", username, message); } println!("gracefully shut down"); }