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use std::fmt; use std::io::{self, Read, Write}; use std::mem; use std::net::{self, Shutdown, SocketAddr}; use std::time::Duration; use bytes::{Buf, BufMut}; use futures::{Async, Future, Poll}; use iovec::IoVec; use mio; use tokio_io::{AsyncRead, AsyncWrite}; use tokio_reactor::{Handle, PollEvented}; /// An I/O object representing a TCP stream connected to a remote endpoint. /// /// A TCP stream can either be created by connecting to an endpoint, via the /// [`connect`] method, or by [accepting] a connection from a [listener]. /// /// [`connect`]: struct.TcpStream.html#method.connect /// [accepting]: struct.TcpListener.html#method.accept /// [listener]: struct.TcpListener.html /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use futures::Future; /// use tokio::io::AsyncWrite; /// use tokio::net::TcpStream; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:34254".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|mut stream| { /// // Attempt to write bytes asynchronously to the stream /// stream.poll_write(&[1]); /// }); /// # Ok(()) /// # } /// ``` pub struct TcpStream { io: PollEvented<mio::net::TcpStream>, } /// Future returned by `TcpStream::connect` which will resolve to a `TcpStream` /// when the stream is connected. #[must_use = "futures do nothing unless polled"] #[derive(Debug)] pub struct ConnectFuture { inner: ConnectFutureState, } #[must_use = "futures do nothing unless polled"] #[derive(Debug)] enum ConnectFutureState { Waiting(TcpStream), Error(io::Error), Empty, } impl TcpStream { /// Create a new TCP stream connected to the specified address. /// /// This function will create a new TCP socket and attempt to connect it to /// the `addr` provided. The returned future will be resolved once the /// stream has successfully connected, or it will return an error if one /// occurs. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use futures::Future; /// use tokio::net::TcpStream; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:34254".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr) /// .map(|stream| /// println!("successfully connected to {}", stream.local_addr().unwrap())); /// # Ok(()) /// # } /// ``` pub fn connect(addr: &SocketAddr) -> ConnectFuture { use self::ConnectFutureState::*; let inner = match mio::net::TcpStream::connect(addr) { Ok(tcp) => Waiting(TcpStream::new(tcp)), Err(e) => Error(e), }; ConnectFuture { inner } } pub(crate) fn new(connected: mio::net::TcpStream) -> TcpStream { let io = PollEvented::new(connected); TcpStream { io } } /// Create a new `TcpStream` from a `net::TcpStream`. /// /// This function will convert a TCP stream created by the standard library /// to a TCP stream ready to be used with the provided event loop handle. /// Use `Handle::default()` to lazily bind to an event loop, just like `connect` does. /// /// # Examples /// /// ```no_run /// # extern crate tokio; /// # extern crate tokio_reactor; /// use tokio::net::TcpStream; /// use std::net::TcpStream as StdTcpStream; /// use tokio_reactor::Handle; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let std_stream = StdTcpStream::connect("127.0.0.1:34254")?; /// let stream = TcpStream::from_std(std_stream, &Handle::default())?; /// # Ok(()) /// # } /// ``` pub fn from_std(stream: net::TcpStream, handle: &Handle) -> io::Result<TcpStream> { let io = mio::net::TcpStream::from_stream(stream)?; let io = PollEvented::new_with_handle(io, handle)?; Ok(TcpStream { io }) } /// Creates a new `TcpStream` from the pending socket inside the given /// `std::net::TcpStream`, connecting it to the address specified. /// /// This constructor allows configuring the socket before it's actually /// connected, and this function will transfer ownership to the returned /// `TcpStream` if successful. An unconnected `TcpStream` can be created /// with the `net2::TcpBuilder` type (and also configured via that route). /// /// The platform specific behavior of this function looks like: /// /// * On Unix, the socket is placed into nonblocking mode and then a /// `connect` call is issued. /// /// * On Windows, the address is stored internally and the connect operation /// is issued when the returned `TcpStream` is registered with an event /// loop. Note that on Windows you must `bind` a socket before it can be /// connected, so if a custom `TcpBuilder` is used it should be bound /// (perhaps to `INADDR_ANY`) before this method is called. pub fn connect_std( stream: net::TcpStream, addr: &SocketAddr, handle: &Handle, ) -> ConnectFuture { use self::ConnectFutureState::*; let io = mio::net::TcpStream::connect_stream(stream, addr) .and_then(|io| PollEvented::new_with_handle(io, handle)); let inner = match io { Ok(io) => Waiting(TcpStream { io }), Err(e) => Error(e), }; ConnectFuture { inner: inner } } /// Check the TCP stream's read readiness state. /// /// The mask argument allows specifying what readiness to notify on. This /// can be any value, including platform specific readiness, **except** /// `writable`. HUP is always implicitly included on platforms that support /// it. /// /// If the resource is not ready for a read then `Async::NotReady` is /// returned and the current task is notified once a new event is received. /// /// The stream will remain in a read-ready state until calls to `poll_read` /// return `NotReady`. /// /// # Panics /// /// This function panics if: /// /// * `ready` includes writable. /// * called from outside of a task context. /// /// # Examples /// /// ``` /// # extern crate mio; /// # extern crate tokio; /// # extern crate futures; /// use mio::Ready; /// use futures::Async; /// use futures::Future; /// use tokio::net::TcpStream; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:34254".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// match stream.poll_read_ready(Ready::readable()) { /// Ok(Async::Ready(_)) => println!("read ready"), /// Ok(Async::NotReady) => println!("not read ready"), /// Err(e) => eprintln!("got error: {}", e), /// } /// }); /// # Ok(()) /// # } /// ``` pub fn poll_read_ready(&self, mask: mio::Ready) -> Poll<mio::Ready, io::Error> { self.io.poll_read_ready(mask) } /// Check the TCP stream's write readiness state. /// /// This always checks for writable readiness and also checks for HUP /// readiness on platforms that support it. /// /// If the resource is not ready for a write then `Async::NotReady` is /// returned and the current task is notified once a new event is received. /// /// The I/O resource will remain in a write-ready state until calls to /// `poll_write` return `NotReady`. /// /// # Panics /// /// This function panics if called from outside of a task context. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use futures::Async; /// use futures::Future; /// use tokio::net::TcpStream; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:34254".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// match stream.poll_write_ready() { /// Ok(Async::Ready(_)) => println!("write ready"), /// Ok(Async::NotReady) => println!("not write ready"), /// Err(e) => eprintln!("got error: {}", e), /// } /// }); /// # Ok(()) /// # } /// ``` pub fn poll_write_ready(&self) -> Poll<mio::Ready, io::Error> { self.io.poll_write_ready() } /// Returns the local address that this stream is bound to. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::{Ipv4Addr, SocketAddr, SocketAddrV4}; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// assert_eq!(stream.local_addr().unwrap(), /// SocketAddr::V4(SocketAddrV4::new(Ipv4Addr::new(127, 0, 0, 1), 8080))); /// }); /// # Ok(()) /// # } /// ``` pub fn local_addr(&self) -> io::Result<SocketAddr> { self.io.get_ref().local_addr() } /// Returns the remote address that this stream is connected to. /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::{Ipv4Addr, SocketAddr, SocketAddrV4}; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// assert_eq!(stream.peer_addr().unwrap(), /// SocketAddr::V4(SocketAddrV4::new(Ipv4Addr::new(127, 0, 0, 1), 8080))); /// }); /// # Ok(()) /// # } /// ``` pub fn peer_addr(&self) -> io::Result<SocketAddr> { self.io.get_ref().peer_addr() } #[deprecated(since = "0.1.2", note = "use poll_peek instead")] #[doc(hidden)] pub fn peek(&mut self, buf: &mut [u8]) -> io::Result<usize> { match self.poll_peek(buf)? { Async::Ready(n) => Ok(n), Async::NotReady => Err(io::ErrorKind::WouldBlock.into()), } } /// Receives data on the socket from the remote address to which it is /// connected, without removing that data from the queue. On success, /// returns the number of bytes peeked. /// /// Successive calls return the same data. This is accomplished by passing /// `MSG_PEEK` as a flag to the underlying recv system call. /// /// # Return /// /// On success, returns `Ok(Async::Ready(num_bytes_read))`. /// /// If no data is available for reading, the method returns /// `Ok(Async::NotReady)` and arranges for the current task to receive a /// notification when the socket becomes readable or is closed. /// /// # Panics /// /// This function will panic if called from outside of a task context. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Async; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|mut stream| { /// let mut buf = [0; 10]; /// match stream.poll_peek(&mut buf) { /// Ok(Async::Ready(len)) => println!("read {} bytes", len), /// Ok(Async::NotReady) => println!("no data available"), /// Err(e) => eprintln!("got error: {}", e), /// } /// }); /// # Ok(()) /// # } /// ``` pub fn poll_peek(&mut self, buf: &mut [u8]) -> Poll<usize, io::Error> { try_ready!(self.io.poll_read_ready(mio::Ready::readable())); match self.io.get_ref().peek(buf) { Ok(ret) => Ok(ret.into()), Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => { self.io.clear_read_ready(mio::Ready::readable())?; Ok(Async::NotReady) } Err(e) => Err(e), } } /// Shuts down the read, write, or both halves of this connection. /// /// This function will cause all pending and future I/O on the specified /// portions to return immediately with an appropriate value (see the /// documentation of `Shutdown`). /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::{Shutdown, SocketAddr}; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.shutdown(Shutdown::Both) /// }); /// # Ok(()) /// # } /// ``` pub fn shutdown(&self, how: Shutdown) -> io::Result<()> { self.io.get_ref().shutdown(how) } /// Gets the value of the `TCP_NODELAY` option on this socket. /// /// For more information about this option, see [`set_nodelay`]. /// /// [`set_nodelay`]: #method.set_nodelay /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_nodelay(true).expect("set_nodelay call failed");; /// assert_eq!(stream.nodelay().unwrap_or(false), true); /// }); /// # Ok(()) /// # } /// ``` pub fn nodelay(&self) -> io::Result<bool> { self.io.get_ref().nodelay() } /// Sets the value of the `TCP_NODELAY` option on this socket. /// /// If set, this option disables the Nagle algorithm. This means that /// segments are always sent as soon as possible, even if there is only a /// small amount of data. When not set, data is buffered until there is a /// sufficient amount to send out, thereby avoiding the frequent sending of /// small packets. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_nodelay(true).expect("set_nodelay call failed"); /// }); /// # Ok(()) /// # } /// ``` pub fn set_nodelay(&self, nodelay: bool) -> io::Result<()> { self.io.get_ref().set_nodelay(nodelay) } /// Gets the value of the `SO_RCVBUF` option on this socket. /// /// For more information about this option, see [`set_recv_buffer_size`]. /// /// [`set_recv_buffer_size`]: #tymethod.set_recv_buffer_size /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_recv_buffer_size(100).expect("set_recv_buffer_size failed"); /// assert_eq!(stream.recv_buffer_size().unwrap_or(0), 100); /// }); /// # Ok(()) /// # } /// ``` pub fn recv_buffer_size(&self) -> io::Result<usize> { self.io.get_ref().recv_buffer_size() } /// Sets the value of the `SO_RCVBUF` option on this socket. /// /// Changes the size of the operating system's receive buffer associated /// with the socket. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_recv_buffer_size(100).expect("set_recv_buffer_size failed"); /// }); /// # Ok(()) /// # } /// ``` pub fn set_recv_buffer_size(&self, size: usize) -> io::Result<()> { self.io.get_ref().set_recv_buffer_size(size) } /// Gets the value of the `SO_SNDBUF` option on this socket. /// /// For more information about this option, see [`set_send_buffer`]. /// /// [`set_send_buffer`]: #tymethod.set_send_buffer /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_send_buffer_size(100).expect("set_send_buffer_size failed"); /// assert_eq!(stream.send_buffer_size().unwrap_or(0), 100); /// }); /// # Ok(()) /// # } /// ``` pub fn send_buffer_size(&self) -> io::Result<usize> { self.io.get_ref().send_buffer_size() } /// Sets the value of the `SO_SNDBUF` option on this socket. /// /// Changes the size of the operating system's send buffer associated with /// the socket. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_send_buffer_size(100).expect("set_send_buffer_size failed"); /// }); /// # Ok(()) /// # } /// ``` pub fn set_send_buffer_size(&self, size: usize) -> io::Result<()> { self.io.get_ref().set_send_buffer_size(size) } /// Returns whether keepalive messages are enabled on this socket, and if so /// the duration of time between them. /// /// For more information about this option, see [`set_keepalive`]. /// /// [`set_keepalive`]: #tymethod.set_keepalive /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_keepalive(None).expect("set_keepalive failed"); /// assert_eq!(stream.keepalive().unwrap(), None); /// }); /// # Ok(()) /// # } /// ``` pub fn keepalive(&self) -> io::Result<Option<Duration>> { self.io.get_ref().keepalive() } /// Sets whether keepalive messages are enabled to be sent on this socket. /// /// On Unix, this option will set the `SO_KEEPALIVE` as well as the /// `TCP_KEEPALIVE` or `TCP_KEEPIDLE` option (depending on your platform). /// On Windows, this will set the `SIO_KEEPALIVE_VALS` option. /// /// If `None` is specified then keepalive messages are disabled, otherwise /// the duration specified will be the time to remain idle before sending a /// TCP keepalive probe. /// /// Some platforms specify this value in seconds, so sub-second /// specifications may be omitted. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_keepalive(None).expect("set_keepalive failed"); /// }); /// # Ok(()) /// # } /// ``` pub fn set_keepalive(&self, keepalive: Option<Duration>) -> io::Result<()> { self.io.get_ref().set_keepalive(keepalive) } /// Gets the value of the `IP_TTL` option for this socket. /// /// For more information about this option, see [`set_ttl`]. /// /// [`set_ttl`]: #tymethod.set_ttl /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_ttl(100).expect("set_ttl failed"); /// assert_eq!(stream.ttl().unwrap_or(0), 100); /// }); /// # Ok(()) /// # } /// ``` pub fn ttl(&self) -> io::Result<u32> { self.io.get_ref().ttl() } /// Sets the value for the `IP_TTL` option on this socket. /// /// This value sets the time-to-live field that is used in every packet sent /// from this socket. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_ttl(100).expect("set_ttl failed"); /// }); /// # Ok(()) /// # } /// ``` pub fn set_ttl(&self, ttl: u32) -> io::Result<()> { self.io.get_ref().set_ttl(ttl) } /// Reads the linger duration for this socket by getting the `SO_LINGER` /// option. /// /// For more information about this option, see [`set_linger`]. /// /// [`set_linger`]: #tymethod.set_linger /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_linger(None).expect("set_linger failed"); /// assert_eq!(stream.linger().unwrap(), None); /// }); /// # Ok(()) /// # } /// ``` pub fn linger(&self) -> io::Result<Option<Duration>> { self.io.get_ref().linger() } /// Sets the linger duration of this socket by setting the `SO_LINGER` /// option. /// /// This option controls the action taken when a stream has unsent messages /// and the stream is closed. If `SO_LINGER` is set, the system /// shall block the process until it can transmit the data or until the /// time expires. /// /// If `SO_LINGER` is not specified, and the stream is closed, the system /// handles the call in a way that allows the process to continue as quickly /// as possible. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// stream.set_linger(None).expect("set_linger failed"); /// }); /// # Ok(()) /// # } /// ``` pub fn set_linger(&self, dur: Option<Duration>) -> io::Result<()> { self.io.get_ref().set_linger(dur) } /// Creates a new independently owned handle to the underlying socket. /// /// The returned `TcpStream` is a reference to the same stream that this /// object references. Both handles will read and write the same stream of /// data, and options set on one stream will be propagated to the other /// stream. /// /// # Examples /// /// ``` /// # extern crate tokio; /// # extern crate futures; /// use tokio::net::TcpStream; /// use futures::Future; /// use std::net::SocketAddr; /// /// # fn main() -> Result<(), Box<std::error::Error>> { /// let addr = "127.0.0.1:8080".parse::<SocketAddr>()?; /// let stream = TcpStream::connect(&addr); /// stream.map(|stream| { /// let clone = stream.try_clone().unwrap(); /// }); /// # Ok(()) /// # } /// ``` #[deprecated(since = "0.1.14", note = "use `split()` instead")] #[doc(hidden)] pub fn try_clone(&self) -> io::Result<TcpStream> { // Rationale for deprecation: // - https://github.com/tokio-rs/tokio/pull/824 // - https://github.com/tokio-rs/tokio/issues/774#issuecomment-451059317 let msg = "`TcpStream::try_clone()` is deprecated because it doesn't work as intended"; Err(io::Error::new(io::ErrorKind::Other, msg)) } } // ===== impl Read / Write ===== impl Read for TcpStream { fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> { self.io.read(buf) } } impl Write for TcpStream { fn write(&mut self, buf: &[u8]) -> io::Result<usize> { self.io.write(buf) } fn flush(&mut self) -> io::Result<()> { Ok(()) } } impl AsyncRead for TcpStream { unsafe fn prepare_uninitialized_buffer(&self, _: &mut [u8]) -> bool { false } fn read_buf<B: BufMut>(&mut self, buf: &mut B) -> Poll<usize, io::Error> { <&TcpStream>::read_buf(&mut &*self, buf) } } impl AsyncWrite for TcpStream { fn shutdown(&mut self) -> Poll<(), io::Error> { <&TcpStream>::shutdown(&mut &*self) } fn write_buf<B: Buf>(&mut self, buf: &mut B) -> Poll<usize, io::Error> { <&TcpStream>::write_buf(&mut &*self, buf) } } // ===== impl Read / Write for &'a ===== impl<'a> Read for &'a TcpStream { fn read(&mut self, buf: &mut [u8]) -> io::Result<usize> { (&self.io).read(buf) } } impl<'a> Write for &'a TcpStream { fn write(&mut self, buf: &[u8]) -> io::Result<usize> { (&self.io).write(buf) } fn flush(&mut self) -> io::Result<()> { (&self.io).flush() } } impl<'a> AsyncRead for &'a TcpStream { unsafe fn prepare_uninitialized_buffer(&self, _: &mut [u8]) -> bool { false } fn read_buf<B: BufMut>(&mut self, buf: &mut B) -> Poll<usize, io::Error> { if let Async::NotReady = self.io.poll_read_ready(mio::Ready::readable())? { return Ok(Async::NotReady); } let r = unsafe { // The `IoVec` type can't have a 0-length size, so we create a bunch // of dummy versions on the stack with 1 length which we'll quickly // overwrite. let b1: &mut [u8] = &mut [0]; let b2: &mut [u8] = &mut [0]; let b3: &mut [u8] = &mut [0]; let b4: &mut [u8] = &mut [0]; let b5: &mut [u8] = &mut [0]; let b6: &mut [u8] = &mut [0]; let b7: &mut [u8] = &mut [0]; let b8: &mut [u8] = &mut [0]; let b9: &mut [u8] = &mut [0]; let b10: &mut [u8] = &mut [0]; let b11: &mut [u8] = &mut [0]; let b12: &mut [u8] = &mut [0]; let b13: &mut [u8] = &mut [0]; let b14: &mut [u8] = &mut [0]; let b15: &mut [u8] = &mut [0]; let b16: &mut [u8] = &mut [0]; let mut bufs: [&mut IoVec; 16] = [ b1.into(), b2.into(), b3.into(), b4.into(), b5.into(), b6.into(), b7.into(), b8.into(), b9.into(), b10.into(), b11.into(), b12.into(), b13.into(), b14.into(), b15.into(), b16.into(), ]; let n = buf.bytes_vec_mut(&mut bufs); self.io.get_ref().read_bufs(&mut bufs[..n]) }; match r { Ok(n) => { unsafe { buf.advance_mut(n); } Ok(Async::Ready(n)) } Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => { self.io.clear_read_ready(mio::Ready::readable())?; Ok(Async::NotReady) } Err(e) => Err(e), } } } impl<'a> AsyncWrite for &'a TcpStream { fn shutdown(&mut self) -> Poll<(), io::Error> { Ok(().into()) } fn write_buf<B: Buf>(&mut self, buf: &mut B) -> Poll<usize, io::Error> { if let Async::NotReady = self.io.poll_write_ready()? { return Ok(Async::NotReady); } let r = { // The `IoVec` type can't have a zero-length size, so create a dummy // version from a 1-length slice which we'll overwrite with the // `bytes_vec` method. static DUMMY: &[u8] = &[0]; let iovec = <&IoVec>::from(DUMMY); let mut bufs = [iovec; 64]; let n = buf.bytes_vec(&mut bufs); self.io.get_ref().write_bufs(&bufs[..n]) }; match r { Ok(n) => { buf.advance(n); Ok(Async::Ready(n)) } Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => { self.io.clear_write_ready()?; Ok(Async::NotReady) } Err(e) => Err(e), } } } impl fmt::Debug for TcpStream { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { self.io.get_ref().fmt(f) } } impl Future for ConnectFuture { type Item = TcpStream; type Error = io::Error; fn poll(&mut self) -> Poll<TcpStream, io::Error> { self.inner.poll() } } impl ConnectFutureState { fn poll_inner<F>(&mut self, f: F) -> Poll<TcpStream, io::Error> where F: FnOnce(&mut PollEvented<mio::net::TcpStream>) -> Poll<mio::Ready, io::Error>, { { let stream = match *self { ConnectFutureState::Waiting(ref mut s) => s, ConnectFutureState::Error(_) => { let e = match mem::replace(self, ConnectFutureState::Empty) { ConnectFutureState::Error(e) => e, _ => panic!(), }; return Err(e); } ConnectFutureState::Empty => panic!("can't poll TCP stream twice"), }; // Once we've connected, wait for the stream to be writable as // that's when the actual connection has been initiated. Once we're // writable we check for `take_socket_error` to see if the connect // actually hit an error or not. // // If all that succeeded then we ship everything on up. if let Async::NotReady = f(&mut stream.io)? { return Ok(Async::NotReady); } if let Some(e) = stream.io.get_ref().take_error()? { return Err(e); } } match mem::replace(self, ConnectFutureState::Empty) { ConnectFutureState::Waiting(stream) => Ok(Async::Ready(stream)), _ => panic!(), } } } impl Future for ConnectFutureState { type Item = TcpStream; type Error = io::Error; fn poll(&mut self) -> Poll<TcpStream, io::Error> { self.poll_inner(|io| io.poll_write_ready()) } } #[cfg(unix)] mod sys { use super::TcpStream; use std::os::unix::prelude::*; impl AsRawFd for TcpStream { fn as_raw_fd(&self) -> RawFd { self.io.get_ref().as_raw_fd() } } } #[cfg(windows)] mod sys { // TODO: let's land these upstream with mio and then we can add them here. // // use std::os::windows::prelude::*; // use super::TcpStream; // // impl AsRawHandle for TcpStream { // fn as_raw_handle(&self) -> RawHandle { // self.io.get_ref().as_raw_handle() // } // } }