use crate::buf::{IntoIter, UninitSlice}; use crate::{Buf, BufMut}; #[cfg(feature = "std")] use std::io::IoSlice; /// A `Chain` sequences two buffers. /// /// `Chain` is an adapter that links two underlying buffers and provides a /// continuous view across both buffers. It is able to sequence either immutable /// buffers ([`Buf`] values) or mutable buffers ([`BufMut`] values). /// /// This struct is generally created by calling [`Buf::chain`]. Please see that /// function's documentation for more detail. /// /// # Examples /// /// ``` /// use bytes::{Bytes, Buf}; /// /// let mut buf = (&b"hello "[..]) /// .chain(&b"world"[..]); /// /// let full: Bytes = buf.copy_to_bytes(11); /// assert_eq!(full[..], b"hello world"[..]); /// ``` /// /// [`Buf::chain`]: trait.Buf.html#method.chain /// [`Buf`]: trait.Buf.html /// [`BufMut`]: trait.BufMut.html #[derive(Debug)] pub struct Chain { a: T, b: U, } impl Chain { /// Creates a new `Chain` sequencing the provided values. pub(crate) fn new(a: T, b: U) -> Chain { Chain { a, b } } /// Gets a reference to the first underlying `Buf`. /// /// # Examples /// /// ``` /// use bytes::Buf; /// /// let buf = (&b"hello"[..]) /// .chain(&b"world"[..]); /// /// assert_eq!(buf.first_ref()[..], b"hello"[..]); /// ``` pub fn first_ref(&self) -> &T { &self.a } /// Gets a mutable reference to the first underlying `Buf`. /// /// # Examples /// /// ``` /// use bytes::Buf; /// /// let mut buf = (&b"hello"[..]) /// .chain(&b"world"[..]); /// /// buf.first_mut().advance(1); /// /// let full = buf.copy_to_bytes(9); /// assert_eq!(full, b"elloworld"[..]); /// ``` pub fn first_mut(&mut self) -> &mut T { &mut self.a } /// Gets a reference to the last underlying `Buf`. /// /// # Examples /// /// ``` /// use bytes::Buf; /// /// let buf = (&b"hello"[..]) /// .chain(&b"world"[..]); /// /// assert_eq!(buf.last_ref()[..], b"world"[..]); /// ``` pub fn last_ref(&self) -> &U { &self.b } /// Gets a mutable reference to the last underlying `Buf`. /// /// # Examples /// /// ``` /// use bytes::Buf; /// /// let mut buf = (&b"hello "[..]) /// .chain(&b"world"[..]); /// /// buf.last_mut().advance(1); /// /// let full = buf.copy_to_bytes(10); /// assert_eq!(full, b"hello orld"[..]); /// ``` pub fn last_mut(&mut self) -> &mut U { &mut self.b } /// Consumes this `Chain`, returning the underlying values. /// /// # Examples /// /// ``` /// use bytes::Buf; /// /// let chain = (&b"hello"[..]) /// .chain(&b"world"[..]); /// /// let (first, last) = chain.into_inner(); /// assert_eq!(first[..], b"hello"[..]); /// assert_eq!(last[..], b"world"[..]); /// ``` pub fn into_inner(self) -> (T, U) { (self.a, self.b) } } impl Buf for Chain where T: Buf, U: Buf, { fn remaining(&self) -> usize { self.a.remaining() + self.b.remaining() } fn chunk(&self) -> &[u8] { if self.a.has_remaining() { self.a.chunk() } else { self.b.chunk() } } fn advance(&mut self, mut cnt: usize) { let a_rem = self.a.remaining(); if a_rem != 0 { if a_rem >= cnt { self.a.advance(cnt); return; } // Consume what is left of a self.a.advance(a_rem); cnt -= a_rem; } self.b.advance(cnt); } #[cfg(feature = "std")] fn chunks_vectored<'a>(&'a self, dst: &mut [IoSlice<'a>]) -> usize { let mut n = self.a.chunks_vectored(dst); n += self.b.chunks_vectored(&mut dst[n..]); n } } unsafe impl BufMut for Chain where T: BufMut, U: BufMut, { fn remaining_mut(&self) -> usize { self.a.remaining_mut() + self.b.remaining_mut() } fn chunk_mut(&mut self) -> &mut UninitSlice { if self.a.has_remaining_mut() { self.a.chunk_mut() } else { self.b.chunk_mut() } } unsafe fn advance_mut(&mut self, mut cnt: usize) { let a_rem = self.a.remaining_mut(); if a_rem != 0 { if a_rem >= cnt { self.a.advance_mut(cnt); return; } // Consume what is left of a self.a.advance_mut(a_rem); cnt -= a_rem; } self.b.advance_mut(cnt); } } impl IntoIterator for Chain where T: Buf, U: Buf, { type Item = u8; type IntoIter = IntoIter>; fn into_iter(self) -> Self::IntoIter { IntoIter::new(self) } }