[][src]Struct tokio::net::UnixDatagram

pub struct UnixDatagram { /* fields omitted */ }
This is supported on crate feature net only.

An I/O object representing a Unix datagram socket.

A socket can be either named (associated with a filesystem path) or unnamed.

This type does not provide a split method, because this functionality can be achieved by wrapping the socket in an Arc. Note that you do not need a Mutex to share the UnixDatagram — an Arc<UnixDatagram> is enough. This is because all of the methods take &self instead of &mut self.

Note: named sockets are persisted even after the object is dropped and the program has exited, and cannot be reconnected. It is advised that you either check for and unlink the existing socket if it exists, or use a temporary file that is guaranteed to not already exist.

Examples

Using named sockets, associated with a filesystem path:

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// We use a temporary directory so that the socket
// files left by the bound sockets will get cleaned up.
let tmp = tempdir()?;

// Bind each socket to a filesystem path
let tx_path = tmp.path().join("tx");
let tx = UnixDatagram::bind(&tx_path)?;
let rx_path = tmp.path().join("rx");
let rx = UnixDatagram::bind(&rx_path)?;

let bytes = b"hello world";
tx.send_to(bytes, &rx_path).await?;

let mut buf = vec![0u8; 24];
let (size, addr) = rx.recv_from(&mut buf).await?;

let dgram = &buf[..size];
assert_eq!(dgram, bytes);
assert_eq!(addr.as_pathname().unwrap(), &tx_path);

Using unnamed sockets, created as a pair

use tokio::net::UnixDatagram;

// Create the pair of sockets
let (sock1, sock2) = UnixDatagram::pair()?;

// Since the sockets are paired, the paired send/recv
// functions can be used
let bytes = b"hello world";
sock1.send(bytes).await?;

let mut buff = vec![0u8; 24];
let size = sock2.recv(&mut buff).await?;

let dgram = &buff[..size];
assert_eq!(dgram, bytes);

Implementations

impl UnixDatagram[src]

pub async fn ready(&self, interest: Interest) -> Result<Ready>[src]

Wait for any of the requested ready states.

This function is usually paired with try_recv() or try_send(). It can be used to concurrently recv / send to the same socket on a single task without splitting the socket.

The function may complete without the socket being ready. This is a false-positive and attempting an operation will return with io::ErrorKind::WouldBlock.

Examples

Concurrently receive from and send to the socket on the same task without splitting.

use tokio::io::Interest;
use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;
    socket.connect(&server_path)?;

    loop {
        let ready = socket.ready(Interest::READABLE | Interest::WRITABLE).await?;

        if ready.is_readable() {
            let mut data = [0; 1024];
            match socket.try_recv(&mut data[..]) {
                Ok(n) => {
                    println!("received {:?}", &data[..n]);
                }
                // False-positive, continue
                Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {}
                Err(e) => {
                    return Err(e);
                }
            }
        }

        if ready.is_writable() {
            // Write some data
            match socket.try_send(b"hello world") {
                Ok(n) => {
                    println!("sent {} bytes", n);
                }
                // False-positive, continue
                Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {}
                Err(e) => {
                    return Err(e);
                }
            }
        }
    }
}

pub async fn writable(&self) -> Result<()>[src]

Wait for the socket to become writable.

This function is equivalent to ready(Interest::WRITABLE) and is usually paired with try_send() or try_send_to().

The function may complete without the socket being writable. This is a false-positive and attempting a try_send() will return with io::ErrorKind::WouldBlock.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;
    socket.connect(&server_path)?;

    loop {
        // Wait for the socket to be writable
        socket.writable().await?;

        // Try to send data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_send(b"hello world") {
            Ok(n) => {
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub async fn readable(&self) -> Result<()>[src]

Wait for the socket to become readable.

This function is equivalent to ready(Interest::READABLE) and is usually paired with try_recv().

The function may complete without the socket being readable. This is a false-positive and attempting a try_recv() will return with io::ErrorKind::WouldBlock.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    // Connect to a peer
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;
    socket.connect(&server_path)?;

    loop {
        // Wait for the socket to be readable
        socket.readable().await?;

        // The buffer is **not** included in the async task and will
        // only exist on the stack.
        let mut buf = [0; 1024];

        // Try to recv data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_recv(&mut buf) {
            Ok(n) => {
                println!("GOT {:?}", &buf[..n]);
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub fn bind<P>(path: P) -> Result<UnixDatagram> where
    P: AsRef<Path>, 
[src]

Creates a new UnixDatagram bound to the specified path.

Examples

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// We use a temporary directory so that the socket
// files left by the bound sockets will get cleaned up.
let tmp = tempdir()?;

// Bind the socket to a filesystem path
let socket_path = tmp.path().join("socket");
let socket = UnixDatagram::bind(&socket_path)?;

pub fn pair() -> Result<(UnixDatagram, UnixDatagram)>[src]

Creates an unnamed pair of connected sockets.

This function will create a pair of interconnected Unix sockets for communicating back and forth between one another.

Examples

use tokio::net::UnixDatagram;

// Create the pair of sockets
let (sock1, sock2) = UnixDatagram::pair()?;

// Since the sockets are paired, the paired send/recv
// functions can be used
let bytes = b"hail eris";
sock1.send(bytes).await?;

let mut buff = vec![0u8; 24];
let size = sock2.recv(&mut buff).await?;

let dgram = &buff[..size];
assert_eq!(dgram, bytes);

pub fn from_std(datagram: UnixDatagram) -> Result<UnixDatagram>[src]

Creates new UnixDatagram from a std::os::unix::net::UnixDatagram.

This function is intended to be used to wrap a UnixDatagram from the standard library in the Tokio equivalent. The conversion assumes nothing about the underlying datagram; it is left up to the user to set it in non-blocking mode.

Panics

This function panics if thread-local runtime is not set.

The runtime is usually set implicitly when this function is called from a future driven by a Tokio runtime, otherwise runtime can be set explicitly with Runtime::enter function.

Examples

use tokio::net::UnixDatagram;
use std::os::unix::net::UnixDatagram as StdUDS;
use tempfile::tempdir;

// We use a temporary directory so that the socket
// files left by the bound sockets will get cleaned up.
let tmp = tempdir()?;

// Bind the socket to a filesystem path
let socket_path = tmp.path().join("socket");
let std_socket = StdUDS::bind(&socket_path)?;
std_socket.set_nonblocking(true)?;
let tokio_socket = UnixDatagram::from_std(std_socket)?;

pub fn unbound() -> Result<UnixDatagram>[src]

Creates a new UnixDatagram which is not bound to any address.

Examples

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// Create an unbound socket
let tx = UnixDatagram::unbound()?;

// Create another, bound socket
let tmp = tempdir()?;
let rx_path = tmp.path().join("rx");
let rx = UnixDatagram::bind(&rx_path)?;

// Send to the bound socket
let bytes = b"hello world";
tx.send_to(bytes, &rx_path).await?;

let mut buf = vec![0u8; 24];
let (size, addr) = rx.recv_from(&mut buf).await?;

let dgram = &buf[..size];
assert_eq!(dgram, bytes);

pub fn connect<P: AsRef<Path>>(&self, path: P) -> Result<()>[src]

Connects the socket to the specified address.

The send method may be used to send data to the specified address. recv and recv_from will only receive data from that address.

Examples

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// Create an unbound socket
let tx = UnixDatagram::unbound()?;

// Create another, bound socket
let tmp = tempdir()?;
let rx_path = tmp.path().join("rx");
let rx = UnixDatagram::bind(&rx_path)?;

// Connect to the bound socket
tx.connect(&rx_path)?;

// Send to the bound socket
let bytes = b"hello world";
tx.send(bytes).await?;

let mut buf = vec![0u8; 24];
let (size, addr) = rx.recv_from(&mut buf).await?;

let dgram = &buf[..size];
assert_eq!(dgram, bytes);

pub async fn send(&self, buf: &[u8]) -> Result<usize>[src]

Sends data on the socket to the socket's peer.

Examples

use tokio::net::UnixDatagram;

// Create the pair of sockets
let (sock1, sock2) = UnixDatagram::pair()?;

// Since the sockets are paired, the paired send/recv
// functions can be used
let bytes = b"hello world";
sock1.send(bytes).await?;

let mut buff = vec![0u8; 24];
let size = sock2.recv(&mut buff).await?;

let dgram = &buff[..size];
assert_eq!(dgram, bytes);

pub fn try_send(&self, buf: &[u8]) -> Result<usize>[src]

Try to send a datagram to the peer without waiting.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;
    socket.connect(&server_path)?;

    loop {
        // Wait for the socket to be writable
        socket.writable().await?;

        // Try to send data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_send(b"hello world") {
            Ok(n) => {
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub fn try_send_to<P>(&self, buf: &[u8], target: P) -> Result<usize> where
    P: AsRef<Path>, 
[src]

Try to send a datagram to the peer without waiting.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;

    loop {
        // Wait for the socket to be writable
        socket.writable().await?;

        // Try to send data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_send_to(b"hello world", &server_path) {
            Ok(n) => {
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub async fn recv(&self, buf: &mut [u8]) -> Result<usize>[src]

Receives data from the socket.

Examples

use tokio::net::UnixDatagram;

// Create the pair of sockets
let (sock1, sock2) = UnixDatagram::pair()?;

// Since the sockets are paired, the paired send/recv
// functions can be used
let bytes = b"hello world";
sock1.send(bytes).await?;

let mut buff = vec![0u8; 24];
let size = sock2.recv(&mut buff).await?;

let dgram = &buff[..size];
assert_eq!(dgram, bytes);

pub fn try_recv(&self, buf: &mut [u8]) -> Result<usize>[src]

Try to receive a datagram from the peer without waiting.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    // Connect to a peer
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;
    socket.connect(&server_path)?;

    loop {
        // Wait for the socket to be readable
        socket.readable().await?;

        // The buffer is **not** included in the async task and will
        // only exist on the stack.
        let mut buf = [0; 1024];

        // Try to recv data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_recv(&mut buf) {
            Ok(n) => {
                println!("GOT {:?}", &buf[..n]);
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub fn try_recv_buf_from<B: BufMut>(
    &self,
    buf: &mut B
) -> Result<(usize, SocketAddr)>
[src]

This is supported on crate feature io-util only.

Try to receive data from the socket without waiting.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    // Connect to a peer
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;

    loop {
        // Wait for the socket to be readable
        socket.readable().await?;

        let mut buf = Vec::with_capacity(1024);

        // Try to recv data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_recv_buf_from(&mut buf) {
            Ok((n, _addr)) => {
                println!("GOT {:?}", &buf[..n]);
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub fn try_recv_buf<B: BufMut>(&self, buf: &mut B) -> Result<usize>[src]

This is supported on crate feature io-util only.

Try to read data from the stream into the provided buffer, advancing the buffer's internal cursor, returning how many bytes were read.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    // Connect to a peer
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;
    socket.connect(&server_path)?;

    loop {
        // Wait for the socket to be readable
        socket.readable().await?;

        let mut buf = Vec::with_capacity(1024);

        // Try to recv data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_recv_buf(&mut buf) {
            Ok(n) => {
                println!("GOT {:?}", &buf[..n]);
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub async fn send_to<P>(&self, buf: &[u8], target: P) -> Result<usize> where
    P: AsRef<Path>, 
[src]

Sends data on the socket to the specified address.

Examples

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// We use a temporary directory so that the socket
// files left by the bound sockets will get cleaned up.
let tmp = tempdir()?;

// Bind each socket to a filesystem path
let tx_path = tmp.path().join("tx");
let tx = UnixDatagram::bind(&tx_path)?;
let rx_path = tmp.path().join("rx");
let rx = UnixDatagram::bind(&rx_path)?;

let bytes = b"hello world";
tx.send_to(bytes, &rx_path).await?;

let mut buf = vec![0u8; 24];
let (size, addr) = rx.recv_from(&mut buf).await?;

let dgram = &buf[..size];
assert_eq!(dgram, bytes);
assert_eq!(addr.as_pathname().unwrap(), &tx_path);

pub async fn recv_from(&self, buf: &mut [u8]) -> Result<(usize, SocketAddr)>[src]

Receives data from the socket.

Examples

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// We use a temporary directory so that the socket
// files left by the bound sockets will get cleaned up.
let tmp = tempdir()?;

// Bind each socket to a filesystem path
let tx_path = tmp.path().join("tx");
let tx = UnixDatagram::bind(&tx_path)?;
let rx_path = tmp.path().join("rx");
let rx = UnixDatagram::bind(&rx_path)?;

let bytes = b"hello world";
tx.send_to(bytes, &rx_path).await?;

let mut buf = vec![0u8; 24];
let (size, addr) = rx.recv_from(&mut buf).await?;

let dgram = &buf[..size];
assert_eq!(dgram, bytes);
assert_eq!(addr.as_pathname().unwrap(), &tx_path);

pub fn poll_recv_from(
    &self,
    cx: &mut Context<'_>,
    buf: &mut ReadBuf<'_>
) -> Poll<Result<SocketAddr>>
[src]

Attempts to receive a single datagram on the specified address.

Note that on multiple calls to a poll_* method in the recv direction, only the Waker from the Context passed to the most recent call will be scheduled to receive a wakeup.

Return value

The function returns:

  • Poll::Pending if the socket is not ready to read
  • Poll::Ready(Ok(addr)) reads data from addr into ReadBuf if the socket is ready
  • Poll::Ready(Err(e)) if an error is encountered.

Errors

This function may encounter any standard I/O error except WouldBlock.

pub fn poll_send_to<P>(
    &self,
    cx: &mut Context<'_>,
    buf: &[u8],
    target: P
) -> Poll<Result<usize>> where
    P: AsRef<Path>, 
[src]

Attempts to send data to the specified address.

Note that on multiple calls to a poll_* method in the send direction, only the Waker from the Context passed to the most recent call will be scheduled to receive a wakeup.

Return value

The function returns:

  • Poll::Pending if the socket is not ready to write
  • Poll::Ready(Ok(n)) n is the number of bytes sent.
  • Poll::Ready(Err(e)) if an error is encountered.

Errors

This function may encounter any standard I/O error except WouldBlock.

pub fn poll_send(&self, cx: &mut Context<'_>, buf: &[u8]) -> Poll<Result<usize>>[src]

Attempts to send data on the socket to the remote address to which it was previously connected.

The connect method will connect this socket to a remote address. This method will fail if the socket is not connected.

Note that on multiple calls to a poll_* method in the send direction, only the Waker from the Context passed to the most recent call will be scheduled to receive a wakeup.

Return value

The function returns:

  • Poll::Pending if the socket is not available to write
  • Poll::Ready(Ok(n)) n is the number of bytes sent
  • Poll::Ready(Err(e)) if an error is encountered.

Errors

This function may encounter any standard I/O error except WouldBlock.

pub fn poll_recv(
    &self,
    cx: &mut Context<'_>,
    buf: &mut ReadBuf<'_>
) -> Poll<Result<()>>
[src]

Attempts to receive a single datagram message on the socket from the remote address to which it is connected.

The connect method will connect this socket to a remote address. This method resolves to an error if the socket is not connected.

Note that on multiple calls to a poll_* method in the recv direction, only the Waker from the Context passed to the most recent call will be scheduled to receive a wakeup.

Return value

The function returns:

  • Poll::Pending if the socket is not ready to read
  • Poll::Ready(Ok(())) reads data ReadBuf if the socket is ready
  • Poll::Ready(Err(e)) if an error is encountered.

Errors

This function may encounter any standard I/O error except WouldBlock.

pub fn try_recv_from(&self, buf: &mut [u8]) -> Result<(usize, SocketAddr)>[src]

Try to receive data from the socket without waiting.

Examples

use tokio::net::UnixDatagram;
use std::io;

#[tokio::main]
async fn main() -> io::Result<()> {
    // Connect to a peer
    let dir = tempfile::tempdir().unwrap();
    let client_path = dir.path().join("client.sock");
    let server_path = dir.path().join("server.sock");
    let socket = UnixDatagram::bind(&client_path)?;

    loop {
        // Wait for the socket to be readable
        socket.readable().await?;

        // The buffer is **not** included in the async task and will
        // only exist on the stack.
        let mut buf = [0; 1024];

        // Try to recv data, this may still fail with `WouldBlock`
        // if the readiness event is a false positive.
        match socket.try_recv_from(&mut buf) {
            Ok((n, _addr)) => {
                println!("GOT {:?}", &buf[..n]);
                break;
            }
            Err(ref e) if e.kind() == io::ErrorKind::WouldBlock => {
                continue;
            }
            Err(e) => {
                return Err(e);
            }
        }
    }

    Ok(())
}

pub fn local_addr(&self) -> Result<SocketAddr>[src]

Returns the local address that this socket is bound to.

Examples

For a socket bound to a local path

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// We use a temporary directory so that the socket
// files left by the bound sockets will get cleaned up.
let tmp = tempdir()?;

// Bind socket to a filesystem path
let socket_path = tmp.path().join("socket");
let socket = UnixDatagram::bind(&socket_path)?;

assert_eq!(socket.local_addr()?.as_pathname().unwrap(), &socket_path);

For an unbound socket

use tokio::net::UnixDatagram;

// Create an unbound socket
let socket = UnixDatagram::unbound()?;

assert!(socket.local_addr()?.is_unnamed());

pub fn peer_addr(&self) -> Result<SocketAddr>[src]

Returns the address of this socket's peer.

The connect method will connect the socket to a peer.

Examples

For a peer with a local path

use tokio::net::UnixDatagram;
use tempfile::tempdir;

// Create an unbound socket
let tx = UnixDatagram::unbound()?;

// Create another, bound socket
let tmp = tempdir()?;
let rx_path = tmp.path().join("rx");
let rx = UnixDatagram::bind(&rx_path)?;

// Connect to the bound socket
tx.connect(&rx_path)?;

assert_eq!(tx.peer_addr()?.as_pathname().unwrap(), &rx_path);

For an unbound peer

use tokio::net::UnixDatagram;

// Create the pair of sockets
let (sock1, sock2) = UnixDatagram::pair()?;

assert!(sock1.peer_addr()?.is_unnamed());

pub fn take_error(&self) -> Result<Option<Error>>[src]

Returns the value of the SO_ERROR option.

Examples

use tokio::net::UnixDatagram;

// Create an unbound socket
let socket = UnixDatagram::unbound()?;

if let Ok(Some(err)) = socket.take_error() {
    println!("Got error: {:?}", err);
}

pub fn shutdown(&self, how: Shutdown) -> Result<()>[src]

Shuts down the read, write, or both halves of this connection.

This function will cause all pending and future I/O calls on the specified portions to immediately return with an appropriate value (see the documentation of Shutdown).

Examples

use tokio::net::UnixDatagram;
use std::net::Shutdown;

// Create an unbound socket
let (socket, other) = UnixDatagram::pair()?;

socket.shutdown(Shutdown::Both)?;

// NOTE: the following commented out code does NOT work as expected.
// Due to an underlying issue, the recv call will block indefinitely.
// See: https://github.com/tokio-rs/tokio/issues/1679
//let mut buff = vec![0u8; 24];
//let size = socket.recv(&mut buff).await?;
//assert_eq!(size, 0);

let send_result = socket.send(b"hello world").await;
assert!(send_result.is_err());

Trait Implementations

impl AsRawFd for UnixDatagram[src]

impl Debug for UnixDatagram[src]

impl TryFrom<UnixDatagram> for UnixDatagram[src]

type Error = Error

The type returned in the event of a conversion error.

pub fn try_from(stream: UnixDatagram) -> Result<Self, Self::Error>[src]

Consumes stream, returning the Tokio I/O object.

This is equivalent to UnixDatagram::from_std(stream).

Auto Trait Implementations

Blanket Implementations

impl<T> Any for T where
    T: 'static + ?Sized
[src]

impl<T> Borrow<T> for T where
    T: ?Sized
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impl<T> BorrowMut<T> for T where
    T: ?Sized
[src]

impl<T> From<T> for T[src]

impl<T, U> Into<U> for T where
    U: From<T>, 
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impl<T, U> TryFrom<U> for T where
    U: Into<T>, 
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type Error = Infallible

The type returned in the event of a conversion error.

impl<T, U> TryInto<U> for T where
    U: TryFrom<T>, 
[src]

type Error = <U as TryFrom<T>>::Error

The type returned in the event of a conversion error.