third_party/bytes/src/lib.rs - incubator-teaclave-sgx-sdk - Git at Google

 //! Provides abstractions for working with bytes.
 //!
 //! The `bytes` crate provides an efficient byte buffer structure
 //! ([`Bytes`](struct.Bytes.html)) and traits for working with buffer
 //! implementations ([`Buf`], [`BufMut`]).
 //!
 //! [`Buf`]: trait.Buf.html
 //! [`BufMut`]: trait.BufMut.html
 //!
 //! # `Bytes`
 //!
 //! `Bytes` is an efficient container for storing and operating on continguous
 //! slices of memory. It is intended for use primarily in networking code, but
 //! could have applications elsewhere as well.
 //!
 //! `Bytes` values facilitate zero-copy network programming by allowing multiple
 //! `Bytes` objects to point to the same underlying memory. This is managed by
 //! using a reference count to track when the memory is no longer needed and can
 //! be freed.
 //!
 //! A `Bytes` handle can be created directly from an existing byte store (such as &[u8]
 //! or Vec<u8>), but usually a `BytesMut` is used first and written to. For
 //! example:
 //!
 //! ```rust
 //! use bytes::{BytesMut, BufMut, BigEndian};
 //!
 //! let mut buf = BytesMut::with_capacity(1024);
 //! buf.put(&b"hello world"[..]);
 //! buf.put_u16::<BigEndian>(1234);
 //!
 //! let a = buf.take();
 //! assert_eq!(a, b"hello world\x04\xD2"[..]);
 //!
 //! buf.put(&b"goodbye world"[..]);
 //!
 //! let b = buf.take();
 //! assert_eq!(b, b"goodbye world"[..]);
 //!
 //! assert_eq!(buf.capacity(), 998);
 //! ```
 //!
 //! In the above example, only a single buffer of 1024 is allocated. The handles
 //! `a` and `b` will share the underlying buffer and maintain indices tracking
 //! the view into the buffer represented by the handle.
 //!
 //! See the [struct docs] for more details.
 //!
 //! [struct docs]: struct.Bytes.html
 //!
 //! # `Buf`, `BufMut`
 //!
 //! These two traits provide read and write access to buffers. The underlying
 //! storage may or may not be in contiguous memory. For example, `Bytes` is a
 //! buffer that guarantees contiguous memory, but a [rope] stores the bytes in
 //! disjoint chunks. `Buf` and `BufMut` maintain cursors tracking the current
 //! position in the underlying byte storage. When bytes are read or written, the
 //! cursor is advanced.
 //!
 //! [rope]: https://en.wikipedia.org/wiki/Rope_(data_structure)
 //!
 //! ## Relation with `Read` and `Write`
 //!
 //! At first glance, it may seem that `Buf` and `BufMut` overlap in
 //! functionality with `std::io::Read` and `std::io::Write`. However, they
 //! serve different purposes. A buffer is the value that is provided as an
 //! argument to `Read::read` and `Write::write`. `Read` and `Write` may then
 //! perform a syscall, which has the potential of failing. Operations on `Buf`
 //! and `BufMut` are infallible.

 #![deny(warnings, missing_docs, missing_debug_implementations)]
 #![doc(html_root_url = "https://docs.rs/bytes/0.4.8")]

 #![cfg_attr(not(target_env = "sgx"), no_std)]
 #![cfg_attr(target_env = "sgx", feature(rustc_private))]

 #[cfg(not(target_env = "sgx"))]
 #[macro_use]
 extern crate sgx_tstd as std;

 extern crate byteorder;
 extern crate iovec;

 pub mod buf;
 pub use buf::{
     Buf,
     BufMut,
     IntoBuf,
 };
 #[deprecated(since = "0.4.1", note = "moved to `buf` module")]
 #[doc(hidden)]
 pub use buf::{
     Reader,
     Writer,
     Take,
 };

 mod bytes;
 mod debug;
 pub use bytes::{Bytes, BytesMut};

 #[deprecated]
 pub use byteorder::{ByteOrder, BigEndian, LittleEndian};

 // Optional Serde support
 #[cfg(feature = "serde")]
 #[doc(hidden)]
 pub mod serde;
	//! Provides abstractions for working with bytes.
	//!
	//! The `bytes` crate provides an efficient byte buffer structure
	//! ([`Bytes`](struct.Bytes.html)) and traits for working with buffer
	//! implementations ([`Buf`], [`BufMut`]).
	//!
	//! [`Buf`]: trait.Buf.html
	//! [`BufMut`]: trait.BufMut.html
	//!
	//! # `Bytes`
	//!
	//! `Bytes` is an efficient container for storing and operating on continguous
	//! slices of memory. It is intended for use primarily in networking code, but
	//! could have applications elsewhere as well.
	//!
	//! `Bytes` values facilitate zero-copy network programming by allowing multiple
	//! `Bytes` objects to point to the same underlying memory. This is managed by
	//! using a reference count to track when the memory is no longer needed and can
	//! be freed.
	//!
	//! A `Bytes` handle can be created directly from an existing byte store (such as &[u8]
	//! or Vec<u8>), but usually a `BytesMut` is used first and written to. For
	//! example:
	//!
	//! ```rust
	//! use bytes::{BytesMut, BufMut, BigEndian};
	//!
	//! let mut buf = BytesMut::with_capacity(1024);
	//! buf.put(&b"hello world"[..]);
	//! buf.put_u16::<BigEndian>(1234);
	//!
	//! let a = buf.take();
	//! assert_eq!(a, b"hello world\x04\xD2"[..]);
	//!
	//! buf.put(&b"goodbye world"[..]);
	//!
	//! let b = buf.take();
	//! assert_eq!(b, b"goodbye world"[..]);
	//!
	//! assert_eq!(buf.capacity(), 998);
	//! ```
	//!
	//! In the above example, only a single buffer of 1024 is allocated. The handles
	//! `a` and `b` will share the underlying buffer and maintain indices tracking
	//! the view into the buffer represented by the handle.
	//!
	//! See the [struct docs] for more details.
	//!
	//! [struct docs]: struct.Bytes.html
	//!
	//! # `Buf`, `BufMut`
	//!
	//! These two traits provide read and write access to buffers. The underlying
	//! storage may or may not be in contiguous memory. For example, `Bytes` is a
	//! buffer that guarantees contiguous memory, but a [rope] stores the bytes in
	//! disjoint chunks. `Buf` and `BufMut` maintain cursors tracking the current
	//! position in the underlying byte storage. When bytes are read or written, the
	//! cursor is advanced.
	//!
	//! [rope]: https://en.wikipedia.org/wiki/Rope_(data_structure)
	//!
	//! ## Relation with `Read` and `Write`
	//!
	//! At first glance, it may seem that `Buf` and `BufMut` overlap in
	//! functionality with `std::io::Read` and `std::io::Write`. However, they
	//! serve different purposes. A buffer is the value that is provided as an
	//! argument to `Read::read` and `Write::write`. `Read` and `Write` may then
	//! perform a syscall, which has the potential of failing. Operations on `Buf`
	//! and `BufMut` are infallible.

	#![deny(warnings, missing_docs, missing_debug_implementations)]
	#![doc(html_root_url = "https://docs.rs/bytes/0.4.8")]

	#![cfg_attr(not(target_env = "sgx"), no_std)]
	#![cfg_attr(target_env = "sgx", feature(rustc_private))]

	#[cfg(not(target_env = "sgx"))]
	#[macro_use]
	extern crate sgx_tstd as std;

	extern crate byteorder;
	extern crate iovec;

	pub mod buf;
	pub use buf::{
	Buf,
	BufMut,
	IntoBuf,
	};
	#[deprecated(since = "0.4.1", note = "moved to `buf` module")]
	#[doc(hidden)]
	pub use buf::{
	Reader,
	Writer,
	Take,
	};

	mod bytes;
	mod debug;
	pub use bytes::{Bytes, BytesMut};

	#[deprecated]
	pub use byteorder::{ByteOrder, BigEndian, LittleEndian};

	// Optional Serde support
	#[cfg(feature = "serde")]
	#[doc(hidden)]
	pub mod serde;