third_party/rust_crates/vendor/tokio-io/src/framed.rs - fuchsia - Git at Google

 #![allow(deprecated)]

 use std::io::{self, Read, Write};
 use std::fmt;

 use {AsyncRead, AsyncWrite};
 use codec::{Decoder, Encoder};
 use framed_read::{framed_read2, framed_read2_with_buffer, FramedRead2};
 use framed_write::{framed_write2, framed_write2_with_buffer, FramedWrite2};

 use futures::{Stream, Sink, StartSend, Poll};
 use bytes::{BytesMut};

 /// A unified `Stream` and `Sink` interface to an underlying I/O object, using
 /// the `Encoder` and `Decoder` traits to encode and decode frames.
 ///
 /// You can create a `Framed` instance by using the `AsyncRead::framed` adapter.
 #[deprecated(since = "0.1.7", note = "Moved to tokio-codec")]
 #[doc(hidden)]
 pub struct Framed<T, U> {
     inner: FramedRead2<FramedWrite2<Fuse<T, U>>>,
 }

 #[deprecated(since = "0.1.7", note = "Moved to tokio-codec")]
 #[doc(hidden)]
 pub struct Fuse<T, U>(pub T, pub U);

 pub fn framed<T, U>(inner: T, codec: U) -> Framed<T, U>
     where T: AsyncRead + AsyncWrite,
           U: Decoder + Encoder,
 {
     Framed {
         inner: framed_read2(framed_write2(Fuse(inner, codec))),
     }
 }

 impl<T, U> Framed<T, U> {
     /// Provides a `Stream` and `Sink` interface for reading and writing to this
     /// `Io` object, using `Decode` and `Encode` to read and write the raw data.
     ///
     /// Raw I/O objects work with byte sequences, but higher-level code usually
     /// wants to batch these into meaningful chunks, called "frames". This
     /// method layers framing on top of an I/O object, by using the `Codec`
     /// traits to handle encoding and decoding of messages frames. Note that
     /// the incoming and outgoing frame types may be distinct.
     ///
     /// This function returns a *single* object that is both `Stream` and
     /// `Sink`; grouping this into a single object is often useful for layering
     /// things like gzip or TLS, which require both read and write access to the
     /// underlying object.
     ///
     /// This objects takes a stream and a readbuffer and a writebuffer. These field
     /// can be obtained from an existing `Framed` with the `into_parts` method.
     ///
     /// If you want to work more directly with the streams and sink, consider
     /// calling `split` on the `Framed` returned by this method, which will
     /// break them into separate objects, allowing them to interact more easily.
     pub fn from_parts(parts: FramedParts<T>, codec: U) -> Framed<T, U>
     {
         Framed {
             inner: framed_read2_with_buffer(framed_write2_with_buffer(Fuse(parts.inner, codec), parts.writebuf), parts.readbuf),
         }
     }

     /// Returns a reference to the underlying I/O stream wrapped by
     /// `Frame`.
     ///
     /// Note that care should be taken to not tamper with the underlying stream
     /// of data coming in as it may corrupt the stream of frames otherwise
     /// being worked with.
     pub fn get_ref(&self) -> &T {
         &self.inner.get_ref().get_ref().0
     }

     /// Returns a mutable reference to the underlying I/O stream wrapped by
     /// `Frame`.
     ///
     /// Note that care should be taken to not tamper with the underlying stream
     /// of data coming in as it may corrupt the stream of frames otherwise
     /// being worked with.
     pub fn get_mut(&mut self) -> &mut T {
         &mut self.inner.get_mut().get_mut().0
     }

     /// Consumes the `Frame`, returning its underlying I/O stream.
     ///
     /// Note that care should be taken to not tamper with the underlying stream
     /// of data coming in as it may corrupt the stream of frames otherwise
     /// being worked with.
     pub fn into_inner(self) -> T {
         self.inner.into_inner().into_inner().0
     }

     /// Consumes the `Frame`, returning its underlying I/O stream and the buffer
     /// with unprocessed data.
     ///
     /// Note that care should be taken to not tamper with the underlying stream
     /// of data coming in as it may corrupt the stream of frames otherwise
     /// being worked with.
     pub fn into_parts(self) -> FramedParts<T> {
         let (inner, readbuf) = self.inner.into_parts();
         let (inner, writebuf) = inner.into_parts();
         FramedParts { inner: inner.0, readbuf: readbuf, writebuf: writebuf }
     }

     /// Consumes the `Frame`, returning its underlying I/O stream and the buffer
     /// with unprocessed data, and also the current codec state.
     ///
     /// Note that care should be taken to not tamper with the underlying stream
     /// of data coming in as it may corrupt the stream of frames otherwise
     /// being worked with.
     ///
     /// Note that this function will be removed once the codec has been
     /// integrated into `FramedParts` in a new version (see
     /// [#53](https://github.com/tokio-rs/tokio-io/pull/53)).
     pub fn into_parts_and_codec(self) -> (FramedParts<T>, U) {
         let (inner, readbuf) = self.inner.into_parts();
         let (inner, writebuf) = inner.into_parts();
         (FramedParts { inner: inner.0, readbuf: readbuf, writebuf: writebuf }, inner.1)
     }
 }

 impl<T, U> Stream for Framed<T, U>
     where T: AsyncRead,
           U: Decoder,
 {
     type Item = U::Item;
     type Error = U::Error;

     fn poll(&mut self) -> Poll<Option<Self::Item>, Self::Error> {
         self.inner.poll()
     }
 }

 impl<T, U> Sink for Framed<T, U>
     where T: AsyncWrite,
           U: Encoder,
           U::Error: From<io::Error>,
 {
     type SinkItem = U::Item;
     type SinkError = U::Error;

     fn start_send(&mut self,
                   item: Self::SinkItem)
                   -> StartSend<Self::SinkItem, Self::SinkError>
     {
         self.inner.get_mut().start_send(item)
     }

     fn poll_complete(&mut self) -> Poll<(), Self::SinkError> {
         self.inner.get_mut().poll_complete()
     }

     fn close(&mut self) -> Poll<(), Self::SinkError> {
         self.inner.get_mut().close()
     }
 }

 impl<T, U> fmt::Debug for Framed<T, U>
     where T: fmt::Debug,
           U: fmt::Debug,
 {
     fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
         f.debug_struct("Framed")
          .field("io", &self.inner.get_ref().get_ref().0)
          .field("codec", &self.inner.get_ref().get_ref().1)
          .finish()
     }
 }

 // ===== impl Fuse =====

 impl<T: Read, U> Read for Fuse<T, U> {
     fn read(&mut self, dst: &mut [u8]) -> io::Result<usize> {
         self.0.read(dst)
     }
 }

 impl<T: AsyncRead, U> AsyncRead for Fuse<T, U> {
     unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool {
         self.0.prepare_uninitialized_buffer(buf)
     }
 }

 impl<T: Write, U> Write for Fuse<T, U> {
     fn write(&mut self, src: &[u8]) -> io::Result<usize> {
         self.0.write(src)
     }

     fn flush(&mut self) -> io::Result<()> {
         self.0.flush()
     }
 }

 impl<T: AsyncWrite, U> AsyncWrite for Fuse<T, U> {
     fn shutdown(&mut self) -> Poll<(), io::Error> {
         self.0.shutdown()
     }
 }

 impl<T, U: Decoder> Decoder for Fuse<T, U> {
     type Item = U::Item;
     type Error = U::Error;

     fn decode(&mut self, buffer: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error> {
         self.1.decode(buffer)
     }

     fn decode_eof(&mut self, buffer: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error> {
         self.1.decode_eof(buffer)
     }
 }

 impl<T, U: Encoder> Encoder for Fuse<T, U> {
     type Item = U::Item;
     type Error = U::Error;

     fn encode(&mut self, item: Self::Item, dst: &mut BytesMut) -> Result<(), Self::Error> {
         self.1.encode(item, dst)
     }
 }

 /// `FramedParts` contains an export of the data of a Framed transport.
 /// It can be used to construct a new `Framed` with a different codec.
 /// It contains all current buffers and the inner transport.
 #[derive(Debug)]
 pub struct FramedParts<T>
 {
     /// The inner transport used to read bytes to and write bytes to
     pub inner: T,
     /// The buffer with read but unprocessed data.
     pub readbuf: BytesMut,
     /// A buffer with unprocessed data which are not written yet.
     pub writebuf: BytesMut
 }
	#![allow(deprecated)]

	use std::io::{self, Read, Write};
	use std::fmt;

	use {AsyncRead, AsyncWrite};
	use codec::{Decoder, Encoder};
	use framed_read::{framed_read2, framed_read2_with_buffer, FramedRead2};
	use framed_write::{framed_write2, framed_write2_with_buffer, FramedWrite2};

	use futures::{Stream, Sink, StartSend, Poll};
	use bytes::{BytesMut};

	/// A unified `Stream` and `Sink` interface to an underlying I/O object, using
	/// the `Encoder` and `Decoder` traits to encode and decode frames.
	///
	/// You can create a `Framed` instance by using the `AsyncRead::framed` adapter.
	#[deprecated(since = "0.1.7", note = "Moved to tokio-codec")]
	#[doc(hidden)]
	pub struct Framed<T, U> {
	inner: FramedRead2<FramedWrite2<Fuse<T, U>>>,
	}

	#[deprecated(since = "0.1.7", note = "Moved to tokio-codec")]
	#[doc(hidden)]
	pub struct Fuse<T, U>(pub T, pub U);

	pub fn framed<T, U>(inner: T, codec: U) -> Framed<T, U>
	where T: AsyncRead + AsyncWrite,
	U: Decoder + Encoder,
	{
	Framed {
	inner: framed_read2(framed_write2(Fuse(inner, codec))),
	}
	}

	impl<T, U> Framed<T, U> {
	/// Provides a `Stream` and `Sink` interface for reading and writing to this
	/// `Io` object, using `Decode` and `Encode` to read and write the raw data.
	///
	/// Raw I/O objects work with byte sequences, but higher-level code usually
	/// wants to batch these into meaningful chunks, called "frames". This
	/// method layers framing on top of an I/O object, by using the `Codec`
	/// traits to handle encoding and decoding of messages frames. Note that
	/// the incoming and outgoing frame types may be distinct.
	///
	/// This function returns a single object that is both `Stream` and
	/// `Sink`; grouping this into a single object is often useful for layering
	/// things like gzip or TLS, which require both read and write access to the
	/// underlying object.
	///
	/// This objects takes a stream and a readbuffer and a writebuffer. These field
	/// can be obtained from an existing `Framed` with the `into_parts` method.
	///
	/// If you want to work more directly with the streams and sink, consider
	/// calling `split` on the `Framed` returned by this method, which will
	/// break them into separate objects, allowing them to interact more easily.
	pub fn from_parts(parts: FramedParts<T>, codec: U) -> Framed<T, U>
	{
	Framed {
	inner: framed_read2_with_buffer(framed_write2_with_buffer(Fuse(parts.inner, codec), parts.writebuf), parts.readbuf),
	}
	}

	/// Returns a reference to the underlying I/O stream wrapped by
	/// `Frame`.
	///
	/// Note that care should be taken to not tamper with the underlying stream
	/// of data coming in as it may corrupt the stream of frames otherwise
	/// being worked with.
	pub fn get_ref(&self) -> &T {
	&self.inner.get_ref().get_ref().0
	}

	/// Returns a mutable reference to the underlying I/O stream wrapped by
	/// `Frame`.
	///
	/// Note that care should be taken to not tamper with the underlying stream
	/// of data coming in as it may corrupt the stream of frames otherwise
	/// being worked with.
	pub fn get_mut(&mut self) -> &mut T {
	&mut self.inner.get_mut().get_mut().0
	}

	/// Consumes the `Frame`, returning its underlying I/O stream.
	///
	/// Note that care should be taken to not tamper with the underlying stream
	/// of data coming in as it may corrupt the stream of frames otherwise
	/// being worked with.
	pub fn into_inner(self) -> T {
	self.inner.into_inner().into_inner().0
	}

	/// Consumes the `Frame`, returning its underlying I/O stream and the buffer
	/// with unprocessed data.
	///
	/// Note that care should be taken to not tamper with the underlying stream
	/// of data coming in as it may corrupt the stream of frames otherwise
	/// being worked with.
	pub fn into_parts(self) -> FramedParts<T> {
	let (inner, readbuf) = self.inner.into_parts();
	let (inner, writebuf) = inner.into_parts();
	FramedParts { inner: inner.0, readbuf: readbuf, writebuf: writebuf }
	}

	/// Consumes the `Frame`, returning its underlying I/O stream and the buffer
	/// with unprocessed data, and also the current codec state.
	///
	/// Note that care should be taken to not tamper with the underlying stream
	/// of data coming in as it may corrupt the stream of frames otherwise
	/// being worked with.
	///
	/// Note that this function will be removed once the codec has been
	/// integrated into `FramedParts` in a new version (see
	/// [#53](https://github.com/tokio-rs/tokio-io/pull/53)).
	pub fn into_parts_and_codec(self) -> (FramedParts<T>, U) {
	let (inner, readbuf) = self.inner.into_parts();
	let (inner, writebuf) = inner.into_parts();
	(FramedParts { inner: inner.0, readbuf: readbuf, writebuf: writebuf }, inner.1)
	}
	}

	impl<T, U> Stream for Framed<T, U>
	where T: AsyncRead,
	U: Decoder,
	{
	type Item = U::Item;
	type Error = U::Error;

	fn poll(&mut self) -> Poll<Option<Self::Item>, Self::Error> {
	self.inner.poll()
	}
	}

	impl<T, U> Sink for Framed<T, U>
	where T: AsyncWrite,
	U: Encoder,
	U::Error: From<io::Error>,
	{
	type SinkItem = U::Item;
	type SinkError = U::Error;

	fn start_send(&mut self,
	item: Self::SinkItem)
	-> StartSend<Self::SinkItem, Self::SinkError>
	{
	self.inner.get_mut().start_send(item)
	}

	fn poll_complete(&mut self) -> Poll<(), Self::SinkError> {
	self.inner.get_mut().poll_complete()
	}

	fn close(&mut self) -> Poll<(), Self::SinkError> {
	self.inner.get_mut().close()
	}
	}

	impl<T, U> fmt::Debug for Framed<T, U>
	where T: fmt::Debug,
	U: fmt::Debug,
	{
	fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
	f.debug_struct("Framed")
	.field("io", &self.inner.get_ref().get_ref().0)
	.field("codec", &self.inner.get_ref().get_ref().1)
	.finish()
	}
	}

	// ===== impl Fuse =====

	impl<T: Read, U> Read for Fuse<T, U> {
	fn read(&mut self, dst: &mut [u8]) -> io::Result<usize> {
	self.0.read(dst)
	}
	}

	impl<T: AsyncRead, U> AsyncRead for Fuse<T, U> {
	unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool {
	self.0.prepare_uninitialized_buffer(buf)
	}
	}

	impl<T: Write, U> Write for Fuse<T, U> {
	fn write(&mut self, src: &[u8]) -> io::Result<usize> {
	self.0.write(src)
	}

	fn flush(&mut self) -> io::Result<()> {
	self.0.flush()
	}
	}

	impl<T: AsyncWrite, U> AsyncWrite for Fuse<T, U> {
	fn shutdown(&mut self) -> Poll<(), io::Error> {
	self.0.shutdown()
	}
	}

	impl<T, U: Decoder> Decoder for Fuse<T, U> {
	type Item = U::Item;
	type Error = U::Error;

	fn decode(&mut self, buffer: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error> {
	self.1.decode(buffer)
	}

	fn decode_eof(&mut self, buffer: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error> {
	self.1.decode_eof(buffer)
	}
	}

	impl<T, U: Encoder> Encoder for Fuse<T, U> {
	type Item = U::Item;
	type Error = U::Error;

	fn encode(&mut self, item: Self::Item, dst: &mut BytesMut) -> Result<(), Self::Error> {
	self.1.encode(item, dst)
	}
	}

	/// `FramedParts` contains an export of the data of a Framed transport.
	/// It can be used to construct a new `Framed` with a different codec.
	/// It contains all current buffers and the inner transport.
	#[derive(Debug)]
	pub struct FramedParts<T>
	{
	/// The inner transport used to read bytes to and write bytes to
	pub inner: T,
	/// The buffer with read but unprocessed data.
	pub readbuf: BytesMut,
	/// A buffer with unprocessed data which are not written yet.
	pub writebuf: BytesMut
	}