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use bytes::Buf;
use futures::{Async, Poll};
use std::io as std_io;
use AsyncRead;
/// Writes bytes asynchronously.
///
/// The trait inherits from `std::io::Write` and indicates that an I/O object is
/// **nonblocking**. All non-blocking I/O objects must return an error when
/// bytes cannot be written instead of blocking the current thread.
///
/// Specifically, this means that the `poll_write` function will return one of
/// the following:
///
/// * `Ok(Async::Ready(n))` means that `n` bytes of data was immediately
/// written.
///
/// * `Ok(Async::NotReady)` means that no data was written from the buffer
/// provided. The I/O object is not currently writable but may become writable
/// in the future. Most importantly, **the current future's task is scheduled
/// to get unparked when the object is writable**. This means that like
/// `Future::poll` you'll receive a notification when the I/O object is
/// writable again.
///
/// * `Err(e)` for other errors are standard I/O errors coming from the
/// underlying object.
///
/// This trait importantly means that the `write` method only works in the
/// context of a future's task. The object may panic if used outside of a task.
///
/// Note that this trait also represents that the `Write::flush` method works
/// very similarly to the `write` method, notably that `Ok(())` means that the
/// writer has successfully been flushed, a "would block" error means that the
/// current task is ready to receive a notification when flushing can make more
/// progress, and otherwise normal errors can happen as well.
pub trait AsyncWrite: std_io::Write {
/// Attempt to write bytes from `buf` into the object.
///
/// On success, returns `Ok(Async::Ready(num_bytes_written))`.
///
/// If the object is not ready for writing, the method returns
/// `Ok(Async::NotReady)` and arranges for the current task (via
/// `cx.waker()`) to receive a notification when the object becomes
/// readable or is closed.
fn poll_write(&mut self, buf: &[u8]) -> Poll<usize, std_io::Error> {
match self.write(buf) {
Ok(t) => Ok(Async::Ready(t)),
Err(ref e) if e.kind() == std_io::ErrorKind::WouldBlock => return Ok(Async::NotReady),
Err(e) => return Err(e.into()),
}
}
/// Attempt to flush the object, ensuring that any buffered data reach
/// their destination.
///
/// On success, returns `Ok(Async::Ready(()))`.
///
/// If flushing cannot immediately complete, this method returns
/// `Ok(Async::NotReady)` and arranges for the current task (via
/// `cx.waker()`) to receive a notification when the object can make
/// progress towards flushing.
fn poll_flush(&mut self) -> Poll<(), std_io::Error> {
match self.flush() {
Ok(t) => Ok(Async::Ready(t)),
Err(ref e) if e.kind() == std_io::ErrorKind::WouldBlock => return Ok(Async::NotReady),
Err(e) => return Err(e.into()),
}
}
/// Initiates or attempts to shut down this writer, returning success when
/// the I/O connection has completely shut down.
///
/// This method is intended to be used for asynchronous shutdown of I/O
/// connections. For example this is suitable for implementing shutdown of a
/// TLS connection or calling `TcpStream::shutdown` on a proxied connection.
/// Protocols sometimes need to flush out final pieces of data or otherwise
/// perform a graceful shutdown handshake, reading/writing more data as
/// appropriate. This method is the hook for such protocols to implement the
/// graceful shutdown logic.
///
/// This `shutdown` method is required by implementers of the
/// `AsyncWrite` trait. Wrappers typically just want to proxy this call
/// through to the wrapped type, and base types will typically implement
/// shutdown logic here or just return `Ok(().into())`. Note that if you're
/// wrapping an underlying `AsyncWrite` a call to `shutdown` implies that
/// transitively the entire stream has been shut down. After your wrapper's
/// shutdown logic has been executed you should shut down the underlying
/// stream.
///
/// Invocation of a `shutdown` implies an invocation of `flush`. Once this
/// method returns `Ready` it implies that a flush successfully happened
/// before the shutdown happened. That is, callers don't need to call
/// `flush` before calling `shutdown`. They can rely that by calling
/// `shutdown` any pending buffered data will be written out.
///
/// # Return value
///
/// This function returns a `Poll<(), io::Error>` classified as such:
///
/// * `Ok(Async::Ready(()))` - indicates that the connection was
/// successfully shut down and is now safe to deallocate/drop/close
/// resources associated with it. This method means that the current task
/// will no longer receive any notifications due to this method and the
/// I/O object itself is likely no longer usable.
///
/// * `Ok(Async::NotReady)` - indicates that shutdown is initiated but could
/// not complete just yet. This may mean that more I/O needs to happen to
/// continue this shutdown operation. The current task is scheduled to
/// receive a notification when it's otherwise ready to continue the
/// shutdown operation. When woken up this method should be called again.
///
/// * `Err(e)` - indicates a fatal error has happened with shutdown,
/// indicating that the shutdown operation did not complete successfully.
/// This typically means that the I/O object is no longer usable.
///
/// # Errors
///
/// This function can return normal I/O errors through `Err`, described
/// above. Additionally this method may also render the underlying
/// `Write::write` method no longer usable (e.g. will return errors in the
/// future). It's recommended that once `shutdown` is called the
/// `write` method is no longer called.
///
/// # Panics
///
/// This function will panic if not called within the context of a future's
/// task.
fn shutdown(&mut self) -> Poll<(), std_io::Error>;
/// Write a `Buf` into this value, returning how many bytes were written.
///
/// Note that this method will advance the `buf` provided automatically by
/// the number of bytes written.
fn write_buf<B: Buf>(&mut self, buf: &mut B) -> Poll<usize, std_io::Error>
where
Self: Sized,
{
if !buf.has_remaining() {
return Ok(Async::Ready(0));
}
let n = try_ready!(self.poll_write(buf.bytes()));
buf.advance(n);
Ok(Async::Ready(n))
}
}
impl<T: ?Sized + AsyncWrite> AsyncWrite for Box<T> {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
(**self).shutdown()
}
}
impl<'a, T: ?Sized + AsyncWrite> AsyncWrite for &'a mut T {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
(**self).shutdown()
}
}
impl AsyncRead for std_io::Repeat {
unsafe fn prepare_uninitialized_buffer(&self, _: &mut [u8]) -> bool {
false
}
}
impl AsyncWrite for std_io::Sink {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
Ok(().into())
}
}
impl<T: AsyncRead> AsyncRead for std_io::Take<T> {
unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool {
self.get_ref().prepare_uninitialized_buffer(buf)
}
}
impl<T, U> AsyncRead for std_io::Chain<T, U>
where
T: AsyncRead,
U: AsyncRead,
{
unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool {
let (t, u) = self.get_ref();
// We don't need to execute the second initializer if the first one
// already zeroed the buffer out.
t.prepare_uninitialized_buffer(buf) || u.prepare_uninitialized_buffer(buf)
}
}
impl<T: AsyncWrite> AsyncWrite for std_io::BufWriter<T> {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
try_ready!(self.poll_flush());
self.get_mut().shutdown()
}
}
impl<T: AsyncRead> AsyncRead for std_io::BufReader<T> {
unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool {
self.get_ref().prepare_uninitialized_buffer(buf)
}
}
impl<T: AsRef<[u8]>> AsyncRead for std_io::Cursor<T> {}
impl<'a> AsyncWrite for std_io::Cursor<&'a mut [u8]> {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
Ok(().into())
}
}
impl AsyncWrite for std_io::Cursor<Vec<u8>> {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
Ok(().into())
}
}
impl AsyncWrite for std_io::Cursor<Box<[u8]>> {
fn shutdown(&mut self) -> Poll<(), std_io::Error> {
Ok(().into())
}
}