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#![warn(missing_docs, missing_debug_implementations, rust_2018_idioms)]
#![doc(test(
no_crate_inject,
attr(deny(warnings, rust_2018_idioms), allow(dead_code, unused_variables))
))]
#![no_std]
#![cfg_attr(docsrs, feature(doc_cfg))]
//! Provides abstractions for working with bytes.
//!
//! The `bytes` crate provides an efficient byte buffer structure
//! ([`Bytes`]) and traits for working with buffer
//! implementations ([`Buf`], [`BufMut`]).
//!
//! # `Bytes`
//!
//! `Bytes` is an efficient container for storing and operating on contiguous
//! 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};
//!
//! let mut buf = BytesMut::with_capacity(1024);
//! buf.put(&b"hello world"[..]);
//! buf.put_u16(1234);
//!
//! let a = buf.split();
//! assert_eq!(a, b"hello world\x04\xD2"[..]);
//!
//! buf.put(&b"goodbye world"[..]);
//!
//! let b = buf.split();
//! 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](`Bytes`) for more details.
//!
//! # `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.
extern crate alloc;
#[cfg(feature = "std")]
extern crate std;
pub mod buf;
pub use crate::buf::{Buf, BufMut};
mod bytes;
mod bytes_mut;
mod fmt;
mod loom;
pub use crate::bytes::Bytes;
pub use crate::bytes_mut::BytesMut;
// Optional Serde support
#[cfg(feature = "serde")]
mod serde;
#[inline(never)]
#[cold]
fn abort() -> ! {
#[cfg(feature = "std")]
{
std::process::abort();
}
#[cfg(not(feature = "std"))]
{
struct Abort;
impl Drop for Abort {
fn drop(&mut self) {
panic!();
}
}
let _a = Abort;
panic!("abort");
}
}
#[inline(always)]
#[cfg(feature = "std")]
fn saturating_sub_usize_u64(a: usize, b: u64) -> usize {
use core::convert::TryFrom;
match usize::try_from(b) {
Ok(b) => a.saturating_sub(b),
Err(_) => 0,
}
}
#[inline(always)]
#[cfg(feature = "std")]
fn min_u64_usize(a: u64, b: usize) -> usize {
use core::convert::TryFrom;
match usize::try_from(a) {
Ok(a) => usize::min(a, b),
Err(_) => b,
}
}
/// Panic with a nice error message.
#[cold]
fn panic_advance(idx: usize, len: usize) -> ! {
panic!(
"advance out of bounds: the len is {} but advancing by {}",
len, idx
);
}
#[cold]
fn panic_does_not_fit(size: usize, nbytes: usize) -> ! {
panic!(
"size too large: the integer type can fit {} bytes, but nbytes is {}",
size, nbytes
);
}