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// Copyright 2019 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.
use crate::{error::Error, quicksink, tls};
use either::Either;
use futures::{future::BoxFuture, prelude::*, ready, stream::BoxStream};
use futures_rustls::rustls::pki_types::ServerName;
use futures_rustls::{client, server};
use libp2p_core::{
 multiaddr::{Multiaddr, Protocol},
 transport::{DialOpts, ListenerId, TransportError, TransportEvent},
 Transport,
};
use parking_lot::Mutex;
use soketto::{
 connection::{self, CloseReason},
 handshake,
};
use std::borrow::Cow;
use std::net::IpAddr;
use std::{collections::HashMap, ops::DerefMut, sync::Arc};
use std::{fmt, io, mem, pin::Pin, task::Context, task::Poll};
use url::Url;
/// Max. number of payload bytes of a single frame.
const MAX_DATA_SIZE: usize = 256 * 1024 * 1024;
/// A Websocket transport whose output type is a [`Stream`] and [`Sink`] of
/// frame payloads which does not implement [`AsyncRead`] or
/// [`AsyncWrite`]. See [`crate::WsConfig`] if you require the latter.
#[derive(Debug)]
pub struct WsConfig<T> {
 transport: Arc<Mutex<T>>,
 max_data_size: usize,
 tls_config: tls::Config,
 max_redirects: u8,
 /// Websocket protocol of the inner listener.
 listener_protos: HashMap<ListenerId, WsListenProto<'static>>,
}
impl<T> WsConfig<T>
where
 T: Send,
{
 /// Create a new websocket transport based on another transport.
 pub fn new(transport: T) -> Self {
 WsConfig {
 transport: Arc::new(Mutex::new(transport)),
 max_data_size: MAX_DATA_SIZE,
 tls_config: tls::Config::client(),
 max_redirects: 0,
 listener_protos: HashMap::new(),
 }
 }
/// Return the configured maximum number of redirects.
 pub fn max_redirects(&self) -> u8 {
 self.max_redirects
 }
/// Set max. number of redirects to follow.
 pub fn set_max_redirects(&mut self, max: u8) -> &mut Self {
 self.max_redirects = max;
 self
 }
/// Get the max. frame data size we support.
 pub fn max_data_size(&self) -> usize {
 self.max_data_size
 }
/// Set the max. frame data size we support.
 pub fn set_max_data_size(&mut self, size: usize) -> &mut Self {
 self.max_data_size = size;
 self
 }
/// Set the TLS configuration if TLS support is desired.
 pub fn set_tls_config(&mut self, c: tls::Config) -> &mut Self {
 self.tls_config = c;
 self
 }
}
type TlsOrPlain<T> = future::Either<future::Either<client::TlsStream<T>, server::TlsStream<T>>, T>;
impl<T> Transport for WsConfig<T>
where
 T: Transport + Send + Unpin + 'static,
 T::Error: Send + 'static,
 T::Dial: Send + 'static,
 T::ListenerUpgrade: Send + 'static,
 T::Output: AsyncRead + AsyncWrite + Unpin + Send + 'static,
{
 type Output = Connection<T::Output>;
 type Error = Error<T::Error>;
 type ListenerUpgrade = BoxFuture<'static, Result<Self::Output, Self::Error>>;
 type Dial = BoxFuture<'static, Result<Self::Output, Self::Error>>;
fn listen_on(
 &mut self,
 id: ListenerId,
 addr: Multiaddr,
 ) -> Result<(), TransportError<Self::Error>> {
 let (inner_addr, proto) = parse_ws_listen_addr(&addr).ok_or_else(|| {
 tracing::debug!(address=%addr, "Address is not a websocket multiaddr");
 TransportError::MultiaddrNotSupported(addr.clone())
 })?;
if proto.use_tls() && self.tls_config.server.is_none() {
 tracing::debug!(
 "{} address but TLS server support is not configured",
 proto.prefix()
 );
 return Err(TransportError::MultiaddrNotSupported(addr));
 }
match self.transport.lock().listen_on(id, inner_addr) {
 Ok(()) => {
 self.listener_protos.insert(id, proto);
 Ok(())
 }
 Err(e) => Err(e.map(Error::Transport)),
 }
 }
fn remove_listener(&mut self, id: ListenerId) -> bool {
 self.transport.lock().remove_listener(id)
 }
fn dial(
 &mut self,
 addr: Multiaddr,
 dial_opts: DialOpts,
 ) -> Result<Self::Dial, TransportError<Self::Error>> {
 self.do_dial(addr, dial_opts)
 }
fn poll(
 mut self: Pin<&mut Self>,
 cx: &mut Context<'_>,
 ) -> Poll<libp2p_core::transport::TransportEvent<Self::ListenerUpgrade, Self::Error>> {
 let inner_event = {
 let mut transport = self.transport.lock();
 match Transport::poll(Pin::new(transport.deref_mut()), cx) {
 Poll::Ready(ev) => ev,
 Poll::Pending => return Poll::Pending,
 }
 };
 let event = match inner_event {
 TransportEvent::NewAddress {
 listener_id,
 mut listen_addr,
 } => {
 // Append the ws / wss protocol back to the inner address.
 self.listener_protos
 .get(&listener_id)
 .expect("Protocol was inserted in Transport::listen_on.")
 .append_on_addr(&mut listen_addr);
 tracing::debug!(address=%listen_addr, "Listening on address");
 TransportEvent::NewAddress {
 listener_id,
 listen_addr,
 }
 }
 TransportEvent::AddressExpired {
 listener_id,
 mut listen_addr,
 } => {
 self.listener_protos
 .get(&listener_id)
 .expect("Protocol was inserted in Transport::listen_on.")
 .append_on_addr(&mut listen_addr);
 TransportEvent::AddressExpired {
 listener_id,
 listen_addr,
 }
 }
 TransportEvent::ListenerError { listener_id, error } => TransportEvent::ListenerError {
 listener_id,
 error: Error::Transport(error),
 },
 TransportEvent::ListenerClosed {
 listener_id,
 reason,
 } => {
 self.listener_protos
 .remove(&listener_id)
 .expect("Protocol was inserted in Transport::listen_on.");
 TransportEvent::ListenerClosed {
 listener_id,
 reason: reason.map_err(Error::Transport),
 }
 }
 TransportEvent::Incoming {
 listener_id,
 upgrade,
 mut local_addr,
 mut send_back_addr,
 } => {
 let proto = self
 .listener_protos
 .get(&listener_id)
 .expect("Protocol was inserted in Transport::listen_on.");
 let use_tls = proto.use_tls();
 proto.append_on_addr(&mut local_addr);
 proto.append_on_addr(&mut send_back_addr);
 let upgrade = self.map_upgrade(upgrade, send_back_addr.clone(), use_tls);
 TransportEvent::Incoming {
 listener_id,
 upgrade,
 local_addr,
 send_back_addr,
 }
 }
 };
 Poll::Ready(event)
 }
}
impl<T> WsConfig<T>
where
 T: Transport + Send + Unpin + 'static,
 T::Error: Send + 'static,
 T::Dial: Send + 'static,
 T::ListenerUpgrade: Send + 'static,
 T::Output: AsyncRead + AsyncWrite + Unpin + Send + 'static,
{
 fn do_dial(
 &mut self,
 addr: Multiaddr,
 dial_opts: DialOpts,
 ) -> Result<<Self as Transport>::Dial, TransportError<<Self as Transport>::Error>> {
 let mut addr = match parse_ws_dial_addr(addr) {
 Ok(addr) => addr,
 Err(Error::InvalidMultiaddr(a)) => {
 return Err(TransportError::MultiaddrNotSupported(a))
 }
 Err(e) => return Err(TransportError::Other(e)),
 };
// We are looping here in order to follow redirects (if any):
 let mut remaining_redirects = self.max_redirects;
let transport = self.transport.clone();
 let tls_config = self.tls_config.clone();
 let max_redirects = self.max_redirects;
let future = async move {
 loop {
 match Self::dial_once(transport.clone(), addr, tls_config.clone(), dial_opts).await
 {
 Ok(Either::Left(redirect)) => {
 if remaining_redirects == 0 {
 tracing::debug!(%max_redirects, "Too many redirects");
 return Err(Error::TooManyRedirects);
 }
 remaining_redirects -= 1;
 addr = parse_ws_dial_addr(location_to_multiaddr(&redirect)?)?
 }
 Ok(Either::Right(conn)) => return Ok(conn),
 Err(e) => return Err(e),
 }
 }
 };
Ok(Box::pin(future))
 }
/// Attempts to dial the given address and perform a websocket handshake.
 async fn dial_once(
 transport: Arc<Mutex<T>>,
 addr: WsAddress,
 tls_config: tls::Config,
 dial_opts: DialOpts,
 ) -> Result<Either<String, Connection<T::Output>>, Error<T::Error>> {
 tracing::trace!(address=?addr, "Dialing websocket address");
let dial = transport
 .lock()
 .dial(addr.tcp_addr, dial_opts)
 .map_err(|e| match e {
 TransportError::MultiaddrNotSupported(a) => Error::InvalidMultiaddr(a),
 TransportError::Other(e) => Error::Transport(e),
 })?;
let stream = dial.map_err(Error::Transport).await?;
 tracing::trace!(port=%addr.host_port, "TCP connection established");
let stream = if addr.use_tls {
 // begin TLS session
 tracing::trace!(?addr.server_name, "Starting TLS handshake");
 let stream = tls_config
 .client
 .connect(addr.server_name.clone(), stream)
 .map_err(|e| {
 tracing::debug!(?addr.server_name, "TLS handshake failed: {}", e);
 Error::Tls(tls::Error::from(e))
 })
 .await?;
let stream: TlsOrPlain<_> = future::Either::Left(future::Either::Left(stream));
 stream
 } else {
 // continue with plain stream
 future::Either::Right(stream)
 };
tracing::trace!(port=%addr.host_port, "Sending websocket handshake");
let mut client = handshake::Client::new(stream, &addr.host_port, addr.path.as_ref());
match client
 .handshake()
 .map_err(|e| Error::Handshake(Box::new(e)))
 .await?
 {
 handshake::ServerResponse::Redirect {
 status_code,
 location,
 } => {
 tracing::debug!(
 %status_code,
 %location,
 "received redirect"
 );
 Ok(Either::Left(location))
 }
 handshake::ServerResponse::Rejected { status_code } => {
 let msg = format!("server rejected handshake; status code = {status_code}");
 Err(Error::Handshake(msg.into()))
 }
 handshake::ServerResponse::Accepted { .. } => {
 tracing::trace!(port=%addr.host_port, "websocket handshake successful");
 Ok(Either::Right(Connection::new(client.into_builder())))
 }
 }
 }
fn map_upgrade(
 &self,
 upgrade: T::ListenerUpgrade,
 remote_addr: Multiaddr,
 use_tls: bool,
 ) -> <Self as Transport>::ListenerUpgrade {
 let remote_addr2 = remote_addr.clone(); // used for logging
 let tls_config = self.tls_config.clone();
 let max_size = self.max_data_size;
async move {
 let stream = upgrade.map_err(Error::Transport).await?;
 tracing::trace!(address=%remote_addr, "incoming connection from address");
let stream = if use_tls {
 // begin TLS session
 let server = tls_config
 .server
 .expect("for use_tls we checked server is not none");
tracing::trace!(address=%remote_addr, "awaiting TLS handshake with address");
let stream = server
 .accept(stream)
 .map_err(move |e| {
 tracing::debug!(address=%remote_addr, "TLS handshake with address failed: {}", e);
 Error::Tls(tls::Error::from(e))
 })
 .await?;
let stream: TlsOrPlain<_> = future::Either::Left(future::Either::Right(stream));
stream
 } else {
 // continue with plain stream
 future::Either::Right(stream)
 };
tracing::trace!(
 address=%remote_addr2,
 "receiving websocket handshake request from address"
 );
let mut server = handshake::Server::new(stream);
let ws_key = {
 let request = server
 .receive_request()
 .map_err(|e| Error::Handshake(Box::new(e)))
 .await?;
 request.key()
 };
tracing::trace!(
 address=%remote_addr2,
 "accepting websocket handshake request from address"
 );
let response = handshake::server::Response::Accept {
 key: ws_key,
 protocol: None,
 };
server
 .send_response(&response)
 .map_err(|e| Error::Handshake(Box::new(e)))
 .await?;
let conn = {
 let mut builder = server.into_builder();
 builder.set_max_message_size(max_size);
 builder.set_max_frame_size(max_size);
 Connection::new(builder)
 };
Ok(conn)
 }
 .boxed()
 }
}
#[derive(Debug, PartialEq)]
pub(crate) enum WsListenProto<'a> {
 Ws(Cow<'a, str>),
 Wss(Cow<'a, str>),
 TlsWs(Cow<'a, str>),
}
impl<'a> WsListenProto<'a> {
 pub(crate) fn append_on_addr(&self, addr: &mut Multiaddr) {
 match self {
 WsListenProto::Ws(path) => {
 addr.push(Protocol::Ws(path.clone()));
 }
 // `/tls/ws` and `/wss` are equivalend, however we regenerate
 // the one that user passed at `listen_on` for backward compatibility.
 WsListenProto::Wss(path) => {
 addr.push(Protocol::Wss(path.clone()));
 }
 WsListenProto::TlsWs(path) => {
 addr.push(Protocol::Tls);
 addr.push(Protocol::Ws(path.clone()));
 }
 }
 }
pub(crate) fn use_tls(&self) -> bool {
 match self {
 WsListenProto::Ws(_) => false,
 WsListenProto::Wss(_) => true,
 WsListenProto::TlsWs(_) => true,
 }
 }
pub(crate) fn prefix(&self) -> &'static str {
 match self {
 WsListenProto::Ws(_) => "/ws",
 WsListenProto::Wss(_) => "/wss",
 WsListenProto::TlsWs(_) => "/tls/ws",
 }
 }
}
#[derive(Debug)]
struct WsAddress {
 host_port: String,
 path: String,
 server_name: ServerName<'static>,
 use_tls: bool,
 tcp_addr: Multiaddr,
}
/// Tries to parse the given `Multiaddr` into a `WsAddress` used
/// for dialing.
///
/// Fails if the given `Multiaddr` does not represent a TCP/IP-based
/// websocket protocol stack.
fn parse_ws_dial_addr<T>(addr: Multiaddr) -> Result<WsAddress, Error<T>> {
 // The encapsulating protocol must be based on TCP/IP, possibly via DNS.
 // We peek at it in order to learn the hostname and port to use for
 // the websocket handshake.
 let mut protocols = addr.iter();
 let mut ip = protocols.next();
 let mut tcp = protocols.next();
 let (host_port, server_name) = loop {
 match (ip, tcp) {
 (Some(Protocol::Ip4(ip)), Some(Protocol::Tcp(port))) => {
 let server_name = ServerName::IpAddress(IpAddr::V4(ip).into());
 break (format!("{ip}:{port}"), server_name);
 }
 (Some(Protocol::Ip6(ip)), Some(Protocol::Tcp(port))) => {
 let server_name = ServerName::IpAddress(IpAddr::V6(ip).into());
 break (format!("[{ip}]:{port}"), server_name);
 }
 (Some(Protocol::Dns(h)), Some(Protocol::Tcp(port)))
 | (Some(Protocol::Dns4(h)), Some(Protocol::Tcp(port)))
 | (Some(Protocol::Dns6(h)), Some(Protocol::Tcp(port)))
 | (Some(Protocol::Dnsaddr(h)), Some(Protocol::Tcp(port))) => {
 break (format!("{h}:{port}"), tls::dns_name_ref(&h)?)
 }
 (Some(_), Some(p)) => {
 ip = Some(p);
 tcp = protocols.next();
 }
 _ => return Err(Error::InvalidMultiaddr(addr)),
 }
 };
// Now consume the `Ws` / `Wss` protocol from the end of the address,
 // preserving the trailing `P2p` protocol that identifies the remote,
 // if any.
 let mut protocols = addr.clone();
 let mut p2p = None;
 let (use_tls, path) = loop {
 match protocols.pop() {
 p @ Some(Protocol::P2p(_)) => p2p = p,
 Some(Protocol::Ws(path)) => match protocols.pop() {
 Some(Protocol::Tls) => break (true, path.into_owned()),
 Some(p) => {
 protocols.push(p);
 break (false, path.into_owned());
 }
 None => return Err(Error::InvalidMultiaddr(addr)),
 },
 Some(Protocol::Wss(path)) => break (true, path.into_owned()),
 _ => return Err(Error::InvalidMultiaddr(addr)),
 }
 };
// The original address, stripped of the `/ws` and `/wss` protocols,
 // makes up the address for the inner TCP-based transport.
 let tcp_addr = match p2p {
 Some(p) => protocols.with(p),
 None => protocols,
 };
Ok(WsAddress {
 host_port,
 server_name,
 path,
 use_tls,
 tcp_addr,
 })
}
fn parse_ws_listen_addr(addr: &Multiaddr) -> Option<(Multiaddr, WsListenProto<'static>)> {
 let mut inner_addr = addr.clone();
match inner_addr.pop()? {
 Protocol::Wss(path) => Some((inner_addr, WsListenProto::Wss(path))),
 Protocol::Ws(path) => match inner_addr.pop()? {
 Protocol::Tls => Some((inner_addr, WsListenProto::TlsWs(path))),
 p => {
 inner_addr.push(p);
 Some((inner_addr, WsListenProto::Ws(path)))
 }
 },
 _ => None,
 }
}
// Given a location URL, build a new websocket [`Multiaddr`].
fn location_to_multiaddr<T>(location: &str) -> Result<Multiaddr, Error<T>> {
 match Url::parse(location) {
 Ok(url) => {
 let mut a = Multiaddr::empty();
 match url.host() {
 Some(url::Host::Domain(h)) => a.push(Protocol::Dns(h.into())),
 Some(url::Host::Ipv4(ip)) => a.push(Protocol::Ip4(ip)),
 Some(url::Host::Ipv6(ip)) => a.push(Protocol::Ip6(ip)),
 None => return Err(Error::InvalidRedirectLocation),
 }
 if let Some(p) = url.port() {
 a.push(Protocol::Tcp(p))
 }
 let s = url.scheme();
 if s.eq_ignore_ascii_case("https") | s.eq_ignore_ascii_case("wss") {
 a.push(Protocol::Tls);
 a.push(Protocol::Ws(url.path().into()));
 } else if s.eq_ignore_ascii_case("http") | s.eq_ignore_ascii_case("ws") {
 a.push(Protocol::Ws(url.path().into()))
 } else {
 tracing::debug!(scheme=%s, "unsupported scheme");
 return Err(Error::InvalidRedirectLocation);
 }
 Ok(a)
 }
 Err(e) => {
 tracing::debug!("failed to parse url as multi-address: {:?}", e);
 Err(Error::InvalidRedirectLocation)
 }
 }
}
/// The websocket connection.
pub struct Connection<T> {
 receiver: BoxStream<'static, Result<Incoming, connection::Error>>,
 sender: Pin<Box<dyn Sink<OutgoingData, Error = quicksink::Error<connection::Error>> + Send>>,
 _marker: std::marker::PhantomData<T>,
}
/// Data or control information received over the websocket connection.
#[derive(Debug, Clone)]
pub enum Incoming {
 /// Application data.
 Data(Data),
 /// PONG control frame data.
 Pong(Vec<u8>),
 /// Close reason.
 Closed(CloseReason),
}
/// Application data received over the websocket connection
#[derive(Debug, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum Data {
 /// UTF-8 encoded textual data.
 Text(Vec<u8>),
 /// Binary data.
 Binary(Vec<u8>),
}
impl Data {
 pub fn into_bytes(self) -> Vec<u8> {
 match self {
 Data::Text(d) => d,
 Data::Binary(d) => d,
 }
 }
}
impl AsRef<[u8]> for Data {
 fn as_ref(&self) -> &[u8] {
 match self {
 Data::Text(d) => d,
 Data::Binary(d) => d,
 }
 }
}
impl Incoming {
 pub fn is_data(&self) -> bool {
 self.is_binary() || self.is_text()
 }
pub fn is_binary(&self) -> bool {
 matches!(self, Incoming::Data(Data::Binary(_)))
 }
pub fn is_text(&self) -> bool {
 matches!(self, Incoming::Data(Data::Text(_)))
 }
pub fn is_pong(&self) -> bool {
 matches!(self, Incoming::Pong(_))
 }
pub fn is_close(&self) -> bool {
 matches!(self, Incoming::Closed(_))
 }
}
/// Data sent over the websocket connection.
#[derive(Debug, Clone)]
pub enum OutgoingData {
 /// Send some bytes.
 Binary(Vec<u8>),
 /// Send a PING message.
 Ping(Vec<u8>),
 /// Send an unsolicited PONG message.
 /// (Incoming PINGs are answered automatically.)
 Pong(Vec<u8>),
}
impl<T> fmt::Debug for Connection<T> {
 fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
 f.write_str("Connection")
 }
}
impl<T> Connection<T>
where
 T: AsyncRead + AsyncWrite + Send + Unpin + 'static,
{
 fn new(builder: connection::Builder<TlsOrPlain<T>>) -> Self {
 let (sender, receiver) = builder.finish();
 let sink = quicksink::make_sink(sender, |mut sender, action| async move {
 match action {
 quicksink::Action::Send(OutgoingData::Binary(x)) => {
 sender.send_binary_mut(x).await?
 }
 quicksink::Action::Send(OutgoingData::Ping(x)) => {
 let data = x[..].try_into().map_err(|_| {
 io::Error::new(io::ErrorKind::InvalidInput, "PING data must be < 126 bytes")
 })?;
 sender.send_ping(data).await?
 }
 quicksink::Action::Send(OutgoingData::Pong(x)) => {
 let data = x[..].try_into().map_err(|_| {
 io::Error::new(io::ErrorKind::InvalidInput, "PONG data must be < 126 bytes")
 })?;
 sender.send_pong(data).await?
 }
 quicksink::Action::Flush => sender.flush().await?,
 quicksink::Action::Close => sender.close().await?,
 }
 Ok(sender)
 });
 let stream = stream::unfold((Vec::new(), receiver), |(mut data, mut receiver)| async {
 match receiver.receive(&mut data).await {
 Ok(soketto::Incoming::Data(soketto::Data::Text(_))) => Some((
 Ok(Incoming::Data(Data::Text(mem::take(&mut data)))),
 (data, receiver),
 )),
 Ok(soketto::Incoming::Data(soketto::Data::Binary(_))) => Some((
 Ok(Incoming::Data(Data::Binary(mem::take(&mut data)))),
 (data, receiver),
 )),
 Ok(soketto::Incoming::Pong(pong)) => {
 Some((Ok(Incoming::Pong(Vec::from(pong))), (data, receiver)))
 }
 Ok(soketto::Incoming::Closed(reason)) => {
 Some((Ok(Incoming::Closed(reason)), (data, receiver)))
 }
 Err(connection::Error::Closed) => None,
 Err(e) => Some((Err(e), (data, receiver))),
 }
 });
 Connection {
 receiver: stream.boxed(),
 sender: Box::pin(sink),
 _marker: std::marker::PhantomData,
 }
 }
/// Send binary application data to the remote.
 pub fn send_data(&mut self, data: Vec<u8>) -> sink::Send<'_, Self, OutgoingData> {
 self.send(OutgoingData::Binary(data))
 }
/// Send a PING to the remote.
 pub fn send_ping(&mut self, data: Vec<u8>) -> sink::Send<'_, Self, OutgoingData> {
 self.send(OutgoingData::Ping(data))
 }
/// Send an unsolicited PONG to the remote.
 pub fn send_pong(&mut self, data: Vec<u8>) -> sink::Send<'_, Self, OutgoingData> {
 self.send(OutgoingData::Pong(data))
 }
}
impl<T> Stream for Connection<T>
where
 T: AsyncRead + AsyncWrite + Send + Unpin + 'static,
{
 type Item = io::Result<Incoming>;
fn poll_next(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Option<Self::Item>> {
 let item = ready!(self.receiver.poll_next_unpin(cx));
 let item = item.map(|result| result.map_err(|e| io::Error::new(io::ErrorKind::Other, e)));
 Poll::Ready(item)
 }
}
impl<T> Sink<OutgoingData> for Connection<T>
where
 T: AsyncRead + AsyncWrite + Send + Unpin + 'static,
{
 type Error = io::Error;
fn poll_ready(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> {
 Pin::new(&mut self.sender)
 .poll_ready(cx)
 .map_err(|e| io::Error::new(io::ErrorKind::Other, e))
 }
fn start_send(mut self: Pin<&mut Self>, item: OutgoingData) -> io::Result<()> {
 Pin::new(&mut self.sender)
 .start_send(item)
 .map_err(|e| io::Error::new(io::ErrorKind::Other, e))
 }
fn poll_flush(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> {
 Pin::new(&mut self.sender)
 .poll_flush(cx)
 .map_err(|e| io::Error::new(io::ErrorKind::Other, e))
 }
fn poll_close(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<io::Result<()>> {
 Pin::new(&mut self.sender)
 .poll_close(cx)
 .map_err(|e| io::Error::new(io::ErrorKind::Other, e))
 }
}
#[cfg(test)]
mod tests {
 use super::*;
 use libp2p_identity::PeerId;
 use std::io;
#[test]
 fn listen_addr() {
 let tcp_addr = "/ip4/0.0.0.0/tcp/2222".parse::<Multiaddr>().unwrap();
// Check `/tls/ws`
 let addr = tcp_addr
 .clone()
 .with(Protocol::Tls)
 .with(Protocol::Ws("/".into()));
 let (inner_addr, proto) = parse_ws_listen_addr(&addr).unwrap();
 assert_eq!(&inner_addr, &tcp_addr);
 assert_eq!(proto, WsListenProto::TlsWs("/".into()));
let mut listen_addr = tcp_addr.clone();
 proto.append_on_addr(&mut listen_addr);
 assert_eq!(listen_addr, addr);
// Check `/wss`
 let addr = tcp_addr.clone().with(Protocol::Wss("/".into()));
 let (inner_addr, proto) = parse_ws_listen_addr(&addr).unwrap();
 assert_eq!(&inner_addr, &tcp_addr);
 assert_eq!(proto, WsListenProto::Wss("/".into()));
let mut listen_addr = tcp_addr.clone();
 proto.append_on_addr(&mut listen_addr);
 assert_eq!(listen_addr, addr);
// Check `/ws`
 let addr = tcp_addr.clone().with(Protocol::Ws("/".into()));
 let (inner_addr, proto) = parse_ws_listen_addr(&addr).unwrap();
 assert_eq!(&inner_addr, &tcp_addr);
 assert_eq!(proto, WsListenProto::Ws("/".into()));
let mut listen_addr = tcp_addr.clone();
 proto.append_on_addr(&mut listen_addr);
 assert_eq!(listen_addr, addr);
 }
#[test]
 fn dial_addr() {
 let peer_id = PeerId::random();
// Check `/tls/ws`
 let addr = "/dns4/example.com/tcp/2222/tls/ws"
 .parse::<Multiaddr>()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "example.com:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "example.com".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/dns4/example.com/tcp/2222".parse().unwrap());
// Check `/tls/ws` with `/p2p`
 let addr = format!("/dns4/example.com/tcp/2222/tls/ws/p2p/{peer_id}")
 .parse()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "example.com:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "example.com".try_into().unwrap());
 assert_eq!(
 info.tcp_addr,
 format!("/dns4/example.com/tcp/2222/p2p/{peer_id}")
 .parse()
 .unwrap()
 );
// Check `/tls/ws` with `/ip4`
 let addr = "/ip4/127.0.0.1/tcp/2222/tls/ws"
 .parse::<Multiaddr>()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "127.0.0.1:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "127.0.0.1".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/ip4/127.0.0.1/tcp/2222".parse().unwrap());
// Check `/tls/ws` with `/ip6`
 let addr = "/ip6/::1/tcp/2222/tls/ws".parse::<Multiaddr>().unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "[::1]:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "::1".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/ip6/::1/tcp/2222".parse().unwrap());
// Check `/wss`
 let addr = "/dns4/example.com/tcp/2222/wss"
 .parse::<Multiaddr>()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "example.com:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "example.com".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/dns4/example.com/tcp/2222".parse().unwrap());
// Check `/wss` with `/p2p`
 let addr = format!("/dns4/example.com/tcp/2222/wss/p2p/{peer_id}")
 .parse()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "example.com:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "example.com".try_into().unwrap());
 assert_eq!(
 info.tcp_addr,
 format!("/dns4/example.com/tcp/2222/p2p/{peer_id}")
 .parse()
 .unwrap()
 );
// Check `/wss` with `/ip4`
 let addr = "/ip4/127.0.0.1/tcp/2222/wss".parse::<Multiaddr>().unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "127.0.0.1:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "127.0.0.1".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/ip4/127.0.0.1/tcp/2222".parse().unwrap());
// Check `/wss` with `/ip6`
 let addr = "/ip6/::1/tcp/2222/wss".parse::<Multiaddr>().unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "[::1]:2222");
 assert_eq!(info.path, "/");
 assert!(info.use_tls);
 assert_eq!(info.server_name, "::1".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/ip6/::1/tcp/2222".parse().unwrap());
// Check `/ws`
 let addr = "/dns4/example.com/tcp/2222/ws"
 .parse::<Multiaddr>()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "example.com:2222");
 assert_eq!(info.path, "/");
 assert!(!info.use_tls);
 assert_eq!(info.server_name, "example.com".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/dns4/example.com/tcp/2222".parse().unwrap());
// Check `/ws` with `/p2p`
 let addr = format!("/dns4/example.com/tcp/2222/ws/p2p/{peer_id}")
 .parse()
 .unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "example.com:2222");
 assert_eq!(info.path, "/");
 assert!(!info.use_tls);
 assert_eq!(info.server_name, "example.com".try_into().unwrap());
 assert_eq!(
 info.tcp_addr,
 format!("/dns4/example.com/tcp/2222/p2p/{peer_id}")
 .parse()
 .unwrap()
 );
// Check `/ws` with `/ip4`
 let addr = "/ip4/127.0.0.1/tcp/2222/ws".parse::<Multiaddr>().unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "127.0.0.1:2222");
 assert_eq!(info.path, "/");
 assert!(!info.use_tls);
 assert_eq!(info.server_name, "127.0.0.1".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/ip4/127.0.0.1/tcp/2222".parse().unwrap());
// Check `/ws` with `/ip6`
 let addr = "/ip6/::1/tcp/2222/ws".parse::<Multiaddr>().unwrap();
 let info = parse_ws_dial_addr::<io::Error>(addr).unwrap();
 assert_eq!(info.host_port, "[::1]:2222");
 assert_eq!(info.path, "/");
 assert!(!info.use_tls);
 assert_eq!(info.server_name, "::1".try_into().unwrap());
 assert_eq!(info.tcp_addr, "/ip6/::1/tcp/2222".parse().unwrap());
// Check non-ws address
 let addr = "/ip4/127.0.0.1/tcp/2222".parse::<Multiaddr>().unwrap();
 parse_ws_dial_addr::<io::Error>(addr).unwrap_err();
 }
}