// Copyright 2017 Parity Technologies (UK) Ltd. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the "Software"), // to deal in the Software without restriction, including without limitation // the rights to use, copy, modify, merge, publish, distribute, sublicense, // and/or sell copies of the Software, and to permit persons to whom the // Software is furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER // DEALINGS IN THE SOFTWARE. //! Protocol negotiation strategies for the peer acting as the dialer. use crate::protocol::{HeaderLine, Message, MessageIO, Protocol, ProtocolError}; use crate::{Negotiated, NegotiationError, Version}; use futures::prelude::*; use std::{ convert::TryFrom as _, iter, mem, pin::Pin, task::{Context, Poll}, }; /// Returns a `Future` that negotiates a protocol on the given I/O stream /// for a peer acting as the _dialer_ (or _initiator_). /// /// This function is given an I/O stream and a list of protocols and returns a /// computation that performs the protocol negotiation with the remote. The /// returned `Future` resolves with the name of the negotiated protocol and /// a [`Negotiated`] I/O stream. /// /// Within the scope of this library, a dialer always commits to a specific /// multistream-select [`Version`], whereas a listener always supports /// all versions supported by this library. Frictionless multistream-select /// protocol upgrades may thus proceed by deployments with updated listeners, /// eventually followed by deployments of dialers choosing the newer protocol. pub fn dialer_select_proto( inner: R, protocols: I, version: Version, ) -> DialerSelectFuture where R: AsyncRead + AsyncWrite, I: IntoIterator, I::Item: AsRef, { let protocols = protocols.into_iter().peekable(); DialerSelectFuture { version, protocols, state: State::SendHeader { io: MessageIO::new(inner), }, } } /// A `Future` returned by [`dialer_select_proto`] which negotiates /// a protocol iteratively by considering one protocol after the other. #[pin_project::pin_project] pub struct DialerSelectFuture { // TODO: It would be nice if eventually N = I::Item = Protocol. protocols: iter::Peekable, state: State, version: Version, } enum State { SendHeader { io: MessageIO }, SendProtocol { io: MessageIO, protocol: N }, FlushProtocol { io: MessageIO, protocol: N }, AwaitProtocol { io: MessageIO, protocol: N }, Done, } impl Future for DialerSelectFuture where // The Unpin bound here is required because we produce a `Negotiated` as the output. // It also makes the implementation considerably easier to write. R: AsyncRead + AsyncWrite + Unpin, I: Iterator, I::Item: AsRef, { type Output = Result<(I::Item, Negotiated), NegotiationError>; fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { let this = self.project(); loop { match mem::replace(this.state, State::Done) { State::SendHeader { mut io } => { match Pin::new(&mut io).poll_ready(cx)? { Poll::Ready(()) => {} Poll::Pending => { *this.state = State::SendHeader { io }; return Poll::Pending; } } let h = HeaderLine::from(*this.version); if let Err(err) = Pin::new(&mut io).start_send(Message::Header(h)) { return Poll::Ready(Err(From::from(err))); } let protocol = this.protocols.next().ok_or(NegotiationError::Failed)?; // The dialer always sends the header and the first protocol // proposal in one go for efficiency. *this.state = State::SendProtocol { io, protocol }; } State::SendProtocol { mut io, protocol } => { match Pin::new(&mut io).poll_ready(cx)? { Poll::Ready(()) => {} Poll::Pending => { *this.state = State::SendProtocol { io, protocol }; return Poll::Pending; } } let p = Protocol::try_from(protocol.as_ref())?; if let Err(err) = Pin::new(&mut io).start_send(Message::Protocol(p.clone())) { return Poll::Ready(Err(From::from(err))); } tracing::debug!(protocol=%p, "Dialer: Proposed protocol"); if this.protocols.peek().is_some() { *this.state = State::FlushProtocol { io, protocol } } else { match this.version { Version::V1 => *this.state = State::FlushProtocol { io, protocol }, // This is the only effect that `V1Lazy` has compared to `V1`: // Optimistically settling on the only protocol that // the dialer supports for this negotiation. Notably, // the dialer expects a regular `V1` response. Version::V1Lazy => { tracing::debug!(protocol=%p, "Dialer: Expecting proposed protocol"); let hl = HeaderLine::from(Version::V1Lazy); let io = Negotiated::expecting(io.into_reader(), p, Some(hl)); return Poll::Ready(Ok((protocol, io))); } } } } State::FlushProtocol { mut io, protocol } => { match Pin::new(&mut io).poll_flush(cx)? { Poll::Ready(()) => *this.state = State::AwaitProtocol { io, protocol }, Poll::Pending => { *this.state = State::FlushProtocol { io, protocol }; return Poll::Pending; } } } State::AwaitProtocol { mut io, protocol } => { let msg = match Pin::new(&mut io).poll_next(cx)? { Poll::Ready(Some(msg)) => msg, Poll::Pending => { *this.state = State::AwaitProtocol { io, protocol }; return Poll::Pending; } // Treat EOF error as [`NegotiationError::Failed`], not as // [`NegotiationError::ProtocolError`], allowing dropping or closing an I/O // stream as a permissible way to "gracefully" fail a negotiation. Poll::Ready(None) => return Poll::Ready(Err(NegotiationError::Failed)), }; match msg { Message::Header(v) if v == HeaderLine::from(*this.version) => { *this.state = State::AwaitProtocol { io, protocol }; } Message::Protocol(ref p) if p.as_ref() == protocol.as_ref() => { tracing::debug!(protocol=%p, "Dialer: Received confirmation for protocol"); let io = Negotiated::completed(io.into_inner()); return Poll::Ready(Ok((protocol, io))); } Message::NotAvailable => { tracing::debug!( protocol=%protocol.as_ref(), "Dialer: Received rejection of protocol" ); let protocol = this.protocols.next().ok_or(NegotiationError::Failed)?; *this.state = State::SendProtocol { io, protocol } } _ => return Poll::Ready(Err(ProtocolError::InvalidMessage.into())), } } State::Done => panic!("State::poll called after completion"), } } } } #[cfg(test)] mod tests { use super::*; use crate::listener_select_proto; use async_std::future::timeout; use async_std::net::{TcpListener, TcpStream}; use quickcheck::{Arbitrary, Gen, GenRange}; use std::time::Duration; use tracing::metadata::LevelFilter; use tracing_subscriber::EnvFilter; #[test] fn select_proto_basic() { async fn run(version: Version) { let (client_connection, server_connection) = futures_ringbuf::Endpoint::pair(100, 100); let server = async_std::task::spawn(async move { let protos = vec!["/proto1", "/proto2"]; let (proto, mut io) = listener_select_proto(server_connection, protos) .await .unwrap(); assert_eq!(proto, "/proto2"); let mut out = vec![0; 32]; let n = io.read(&mut out).await.unwrap(); out.truncate(n); assert_eq!(out, b"ping"); io.write_all(b"pong").await.unwrap(); io.flush().await.unwrap(); }); let client = async_std::task::spawn(async move { let protos = vec!["/proto3", "/proto2"]; let (proto, mut io) = dialer_select_proto(client_connection, protos, version) .await .unwrap(); assert_eq!(proto, "/proto2"); io.write_all(b"ping").await.unwrap(); io.flush().await.unwrap(); let mut out = vec![0; 32]; let n = io.read(&mut out).await.unwrap(); out.truncate(n); assert_eq!(out, b"pong"); }); server.await; client.await; } async_std::task::block_on(run(Version::V1)); async_std::task::block_on(run(Version::V1Lazy)); } /// Tests the expected behaviour of failed negotiations. #[test] fn negotiation_failed() { fn prop( version: Version, DialerProtos(dial_protos): DialerProtos, ListenerProtos(listen_protos): ListenerProtos, DialPayload(dial_payload): DialPayload, ) { let _ = tracing_subscriber::fmt() .with_env_filter( EnvFilter::builder() .with_default_directive(LevelFilter::DEBUG.into()) .from_env_lossy(), ) .try_init(); async_std::task::block_on(async move { let listener = TcpListener::bind("0.0.0.0:0").await.unwrap(); let addr = listener.local_addr().unwrap(); let server = async_std::task::spawn(async move { let server_connection = listener.accept().await.unwrap().0; let io = match timeout( Duration::from_secs(2), listener_select_proto(server_connection, listen_protos), ) .await .unwrap() { Ok((_, io)) => io, Err(NegotiationError::Failed) => return, Err(NegotiationError::ProtocolError(e)) => { panic!("Unexpected protocol error {e}") } }; match io.complete().await { Err(NegotiationError::Failed) => {} _ => panic!(), } }); let client = async_std::task::spawn(async move { let client_connection = TcpStream::connect(addr).await.unwrap(); let mut io = match timeout( Duration::from_secs(2), dialer_select_proto(client_connection, dial_protos, version), ) .await .unwrap() { Err(NegotiationError::Failed) => return, Ok((_, io)) => io, Err(_) => panic!(), }; // The dialer may write a payload that is even sent before it // got confirmation of the last proposed protocol, when `V1Lazy` // is used. tracing::info!("Writing early data"); io.write_all(&dial_payload).await.unwrap(); match io.complete().await { Err(NegotiationError::Failed) => {} _ => panic!(), } }); server.await; client.await; tracing::info!("---------------------------------------") }); } quickcheck::QuickCheck::new() .tests(1000) .quickcheck(prop as fn(_, _, _, _)); } #[async_std::test] async fn v1_lazy_do_not_wait_for_negotiation_on_poll_close() { let (client_connection, _server_connection) = futures_ringbuf::Endpoint::pair(1024 * 1024, 1); let client = async_std::task::spawn(async move { // Single protocol to allow for lazy (or optimistic) protocol negotiation. let protos = vec!["/proto1"]; let (proto, mut io) = dialer_select_proto(client_connection, protos, Version::V1Lazy) .await .unwrap(); assert_eq!(proto, "/proto1"); // client can close the connection even though protocol negotiation is not yet done, i.e. // `_server_connection` had been untouched. io.close().await.unwrap(); }); async_std::future::timeout(Duration::from_secs(10), client) .await .unwrap(); } #[derive(Clone, Debug)] struct DialerProtos(Vec<&'static str>); impl Arbitrary for DialerProtos { fn arbitrary(g: &mut Gen) -> Self { if bool::arbitrary(g) { DialerProtos(vec!["/proto1"]) } else { DialerProtos(vec!["/proto1", "/proto2"]) } } } #[derive(Clone, Debug)] struct ListenerProtos(Vec<&'static str>); impl Arbitrary for ListenerProtos { fn arbitrary(g: &mut Gen) -> Self { if bool::arbitrary(g) { ListenerProtos(vec!["/proto3"]) } else { ListenerProtos(vec!["/proto3", "/proto4"]) } } } #[derive(Clone, Debug)] struct DialPayload(Vec); impl Arbitrary for DialPayload { fn arbitrary(g: &mut Gen) -> Self { DialPayload( (0..g.gen_range(0..2u8)) .map(|_| g.gen_range(1..255)) // We can generate 0 as that will produce a different error. .collect(), ) } } }