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

 use std::io;
 use bytes::BytesMut;

 use {AsyncWrite, AsyncRead};
 use super::encoder::Encoder;

 use ::_tokio_codec::Framed;

 /// Decoding of frames via buffers.
 ///
 /// This trait is used when constructing an instance of `Framed` or
 /// `FramedRead`. An implementation of `Decoder` takes a byte stream that has
 /// already been buffered in `src` and decodes the data into a stream of
 /// `Self::Item` frames.
 ///
 /// Implementations are able to track state on `self`, which enables
 /// implementing stateful streaming parsers. In many cases, though, this type
 /// will simply be a unit struct (e.g. `struct HttpDecoder`).

 // Note: We can't deprecate this trait, because the deprecation carries through to tokio-codec, and
 // there doesn't seem to be a way to un-deprecate the re-export.
 pub trait Decoder {
     /// The type of decoded frames.
     type Item;

     /// The type of unrecoverable frame decoding errors.
     ///
     /// If an individual message is ill-formed but can be ignored without
     /// interfering with the processing of future messages, it may be more
     /// useful to report the failure as an `Item`.
     ///
     /// `From<io::Error>` is required in the interest of making `Error` suitable
     /// for returning directly from a `FramedRead`, and to enable the default
     /// implementation of `decode_eof` to yield an `io::Error` when the decoder
     /// fails to consume all available data.
     ///
     /// Note that implementors of this trait can simply indicate `type Error =
     /// io::Error` to use I/O errors as this type.
     type Error: From<io::Error>;

     /// Attempts to decode a frame from the provided buffer of bytes.
     ///
     /// This method is called by `FramedRead` whenever bytes are ready to be
     /// parsed.  The provided buffer of bytes is what's been read so far, and
     /// this instance of `Decode` can determine whether an entire frame is in
     /// the buffer and is ready to be returned.
     ///
     /// If an entire frame is available, then this instance will remove those
     /// bytes from the buffer provided and return them as a decoded
     /// frame. Note that removing bytes from the provided buffer doesn't always
     /// necessarily copy the bytes, so this should be an efficient operation in
     /// most circumstances.
     ///
     /// If the bytes look valid, but a frame isn't fully available yet, then
     /// `Ok(None)` is returned. This indicates to the `Framed` instance that
     /// it needs to read some more bytes before calling this method again.
     ///
     /// Note that the bytes provided may be empty. If a previous call to
     /// `decode` consumed all the bytes in the buffer then `decode` will be
     /// called again until it returns `Ok(None)`, indicating that more bytes need to
     /// be read.
     ///
     /// Finally, if the bytes in the buffer are malformed then an error is
     /// returned indicating why. This informs `Framed` that the stream is now
     /// corrupt and should be terminated.
     fn decode(&mut self, src: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error>;

     /// A default method available to be called when there are no more bytes
     /// available to be read from the underlying I/O.
     ///
     /// This method defaults to calling `decode` and returns an error if
     /// `Ok(None)` is returned while there is unconsumed data in `buf`.
     /// Typically this doesn't need to be implemented unless the framing
     /// protocol differs near the end of the stream.
     ///
     /// Note that the `buf` argument may be empty. If a previous call to
     /// `decode_eof` consumed all the bytes in the buffer, `decode_eof` will be
     /// called again until it returns `None`, indicating that there are no more
     /// frames to yield. This behavior enables returning finalization frames
     /// that may not be based on inbound data.
     fn decode_eof(&mut self, buf: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error> {
         match try!(self.decode(buf)) {
             Some(frame) => Ok(Some(frame)),
             None => {
                 if buf.is_empty() {
                     Ok(None)
                 } else {
                     Err(io::Error::new(io::ErrorKind::Other,
                                        "bytes remaining on stream").into())
                 }
             }
         }
     }

     /// 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.
     ///
     /// 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.
     fn framed<T: AsyncRead + AsyncWrite + Sized>(self, io: T) -> Framed<T, Self>
         where Self: Encoder + Sized,
     {
         Framed::new(io, self)
     }
 }
	use std::io;
	use bytes::BytesMut;

	use {AsyncWrite, AsyncRead};
	use super::encoder::Encoder;

	use ::_tokio_codec::Framed;

	/// Decoding of frames via buffers.
	///
	/// This trait is used when constructing an instance of `Framed` or
	/// `FramedRead`. An implementation of `Decoder` takes a byte stream that has
	/// already been buffered in `src` and decodes the data into a stream of
	/// `Self::Item` frames.
	///
	/// Implementations are able to track state on `self`, which enables
	/// implementing stateful streaming parsers. In many cases, though, this type
	/// will simply be a unit struct (e.g. `struct HttpDecoder`).

	// Note: We can't deprecate this trait, because the deprecation carries through to tokio-codec, and
	// there doesn't seem to be a way to un-deprecate the re-export.
	pub trait Decoder {
	/// The type of decoded frames.
	type Item;

	/// The type of unrecoverable frame decoding errors.
	///
	/// If an individual message is ill-formed but can be ignored without
	/// interfering with the processing of future messages, it may be more
	/// useful to report the failure as an `Item`.
	///
	/// `From<io::Error>` is required in the interest of making `Error` suitable
	/// for returning directly from a `FramedRead`, and to enable the default
	/// implementation of `decode_eof` to yield an `io::Error` when the decoder
	/// fails to consume all available data.
	///
	/// Note that implementors of this trait can simply indicate `type Error =
	/// io::Error` to use I/O errors as this type.
	type Error: From<io::Error>;

	/// Attempts to decode a frame from the provided buffer of bytes.
	///
	/// This method is called by `FramedRead` whenever bytes are ready to be
	/// parsed. The provided buffer of bytes is what's been read so far, and
	/// this instance of `Decode` can determine whether an entire frame is in
	/// the buffer and is ready to be returned.
	///
	/// If an entire frame is available, then this instance will remove those
	/// bytes from the buffer provided and return them as a decoded
	/// frame. Note that removing bytes from the provided buffer doesn't always
	/// necessarily copy the bytes, so this should be an efficient operation in
	/// most circumstances.
	///
	/// If the bytes look valid, but a frame isn't fully available yet, then
	/// `Ok(None)` is returned. This indicates to the `Framed` instance that
	/// it needs to read some more bytes before calling this method again.
	///
	/// Note that the bytes provided may be empty. If a previous call to
	/// `decode` consumed all the bytes in the buffer then `decode` will be
	/// called again until it returns `Ok(None)`, indicating that more bytes need to
	/// be read.
	///
	/// Finally, if the bytes in the buffer are malformed then an error is
	/// returned indicating why. This informs `Framed` that the stream is now
	/// corrupt and should be terminated.
	fn decode(&mut self, src: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error>;

	/// A default method available to be called when there are no more bytes
	/// available to be read from the underlying I/O.
	///
	/// This method defaults to calling `decode` and returns an error if
	/// `Ok(None)` is returned while there is unconsumed data in `buf`.
	/// Typically this doesn't need to be implemented unless the framing
	/// protocol differs near the end of the stream.
	///
	/// Note that the `buf` argument may be empty. If a previous call to
	/// `decode_eof` consumed all the bytes in the buffer, `decode_eof` will be
	/// called again until it returns `None`, indicating that there are no more
	/// frames to yield. This behavior enables returning finalization frames
	/// that may not be based on inbound data.
	fn decode_eof(&mut self, buf: &mut BytesMut) -> Result<Option<Self::Item>, Self::Error> {
	match try!(self.decode(buf)) {
	Some(frame) => Ok(Some(frame)),
	None => {
	if buf.is_empty() {
	Ok(None)
	} else {
	Err(io::Error::new(io::ErrorKind::Other,
	"bytes remaining on stream").into())
	}
	}
	}
	}

	/// 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.
	///
	/// 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.
	fn framed<T: AsyncRead + AsyncWrite + Sized>(self, io: T) -> Framed<T, Self>
	where Self: Encoder + Sized,
	{
	Framed::new(io, self)
	}
	}