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use std::io as std_io; use bytes::BufMut; use futures::{Async, Poll}; use {framed, split, AsyncWrite}; #[allow(deprecated)] use codec::{Decoder, Encoder, Framed}; use split::{ReadHalf, WriteHalf}; /// Read bytes asynchronously. /// /// This trait inherits from `std::io::Read` and indicates that an I/O object is /// **non-blocking**. All non-blocking I/O objects must return an error when /// bytes are unavailable instead of blocking the current thread. /// /// Specifically, this means that the `read` function will return one of the /// following: /// /// * `Ok(Async::Ready(n))` means that `n` bytes of data was immediately read /// and placed into the output buffer, where `n` == 0 implies that EOF has /// been reached. /// /// * `Ok(Async::NotReady)` means that no data was read into the buffer /// provided. The I/O object is not currently readable but may become readable /// in the future. Most importantly, **the current future's task is scheduled /// to get unparked when the object is readable**. This means that like /// `Future::poll` you'll receive a notification when the I/O object is /// readable again. /// /// * `Err(e)` for other errors are standard I/O errors coming from the /// underlying object. /// /// This trait importantly means that the `read` method only works in the /// context of a future's task. The object may panic if used outside of a task. pub trait AsyncRead: std_io::Read { /// Prepares an uninitialized buffer to be safe to pass to `read`. Returns /// `true` if the supplied buffer was zeroed out. /// /// While it would be highly unusual, implementations of [`io::Read`] are /// able to read data from the buffer passed as an argument. Because of /// this, the buffer passed to [`io::Read`] must be initialized memory. In /// situations where large numbers of buffers are used, constantly having to /// zero out buffers can be expensive. /// /// This function does any necessary work to prepare an uninitialized buffer /// to be safe to pass to `read`. If `read` guarantees to never attempt read /// data out of the supplied buffer, then `prepare_uninitialized_buffer` /// doesn't need to do any work. /// /// If this function returns `true`, then the memory has been zeroed out. /// This allows implementations of `AsyncRead` which are composed of /// multiple sub implementations to efficiently implement /// `prepare_uninitialized_buffer`. /// /// This function isn't actually `unsafe` to call but `unsafe` to implement. /// The implementer must ensure that either the whole `buf` has been zeroed /// or `read_buf()` overwrites the buffer without reading it and returns /// correct value. /// /// This function is called from [`read_buf`]. /// /// [`io::Read`]: https://doc.rust-lang.org/std/io/trait.Read.html /// [`read_buf`]: #method.read_buf unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool { for i in 0..buf.len() { buf[i] = 0; } true } /// Attempt to read from the `AsyncRead` into `buf`. /// /// On success, returns `Ok(Async::Ready(num_bytes_read))`. /// /// If no data is available for reading, the method returns /// `Ok(Async::Pending)` and arranges for the current task (via /// `cx.waker()`) to receive a notification when the object becomes /// readable or is closed. fn poll_read(&mut self, buf: &mut [u8]) -> Poll<usize, std_io::Error> { match self.read(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()), } } /// Pull some bytes from this source into the specified `Buf`, returning /// how many bytes were read. /// /// The `buf` provided will have bytes read into it and the internal cursor /// will be advanced if any bytes were read. Note that this method typically /// will not reallocate the buffer provided. fn read_buf<B: BufMut>(&mut self, buf: &mut B) -> Poll<usize, std_io::Error> where Self: Sized, { if !buf.has_remaining_mut() { return Ok(Async::Ready(0)); } unsafe { let n = { let b = buf.bytes_mut(); self.prepare_uninitialized_buffer(b); try_ready!(self.poll_read(b)) }; buf.advance_mut(n); Ok(Async::Ready(n)) } } /// 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. #[deprecated(since = "0.1.7", note = "Use tokio_codec::Decoder::framed instead")] #[allow(deprecated)] fn framed<T: Encoder + Decoder>(self, codec: T) -> Framed<Self, T> where Self: AsyncWrite + Sized, { framed::framed(self, codec) } /// Helper method for splitting this read/write object into two halves. /// /// The two halves returned implement the `Read` and `Write` traits, /// respectively. fn split(self) -> (ReadHalf<Self>, WriteHalf<Self>) where Self: AsyncWrite + Sized, { split::split(self) } } impl<T: ?Sized + AsyncRead> AsyncRead for Box<T> { unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool { (**self).prepare_uninitialized_buffer(buf) } } impl<'a, T: ?Sized + AsyncRead> AsyncRead for &'a mut T { unsafe fn prepare_uninitialized_buffer(&self, buf: &mut [u8]) -> bool { (**self).prepare_uninitialized_buffer(buf) } } impl<'a> AsyncRead for &'a [u8] { unsafe fn prepare_uninitialized_buffer(&self, _buf: &mut [u8]) -> bool { false } }