1 use crate::io::util::vec_with_initialized::{into_read_buf_parts, VecU8, VecWithInitialized};
2 use crate::io::{AsyncRead, ReadBuf};
3
4 use pin_project_lite::pin_project;
5 use std::future::Future;
6 use std::io;
7 use std::marker::PhantomPinned;
8 use std::mem::{self, MaybeUninit};
9 use std::pin::Pin;
10 use std::task::{ready, Context, Poll};
11
12 pin_project! {
13 #[derive(Debug)]
14 #[must_use = "futures do nothing unless you `.await` or poll them"]
15 pub struct ReadToEnd<'a, R: ?Sized> {
16 reader: &'a mut R,
17 buf: VecWithInitialized<&'a mut Vec<u8>>,
18 // The number of bytes appended to buf. This can be less than buf.len() if
19 // the buffer was not empty when the operation was started.
20 read: usize,
21 // Make this future `!Unpin` for compatibility with async trait methods.
22 #[pin]
23 _pin: PhantomPinned,
24 }
25 }
26
read_to_end<'a, R>(reader: &'a mut R, buffer: &'a mut Vec<u8>) -> ReadToEnd<'a, R> where R: AsyncRead + Unpin + ?Sized,27 pub(crate) fn read_to_end<'a, R>(reader: &'a mut R, buffer: &'a mut Vec<u8>) -> ReadToEnd<'a, R>
28 where
29 R: AsyncRead + Unpin + ?Sized,
30 {
31 ReadToEnd {
32 reader,
33 buf: VecWithInitialized::new(buffer),
34 read: 0,
35 _pin: PhantomPinned,
36 }
37 }
38
read_to_end_internal<V: VecU8, R: AsyncRead + ?Sized>( buf: &mut VecWithInitialized<V>, mut reader: Pin<&mut R>, num_read: &mut usize, cx: &mut Context<'_>, ) -> Poll<io::Result<usize>>39 pub(super) fn read_to_end_internal<V: VecU8, R: AsyncRead + ?Sized>(
40 buf: &mut VecWithInitialized<V>,
41 mut reader: Pin<&mut R>,
42 num_read: &mut usize,
43 cx: &mut Context<'_>,
44 ) -> Poll<io::Result<usize>> {
45 loop {
46 let ret = ready!(poll_read_to_end(buf, reader.as_mut(), cx));
47 match ret {
48 Err(err) => return Poll::Ready(Err(err)),
49 Ok(0) => return Poll::Ready(Ok(mem::replace(num_read, 0))),
50 Ok(num) => {
51 *num_read += num;
52 }
53 }
54 }
55 }
56
57 /// Tries to read from the provided [`AsyncRead`].
58 ///
59 /// The length of the buffer is increased by the number of bytes read.
poll_read_to_end<V: VecU8, R: AsyncRead + ?Sized>( buf: &mut VecWithInitialized<V>, read: Pin<&mut R>, cx: &mut Context<'_>, ) -> Poll<io::Result<usize>>60 fn poll_read_to_end<V: VecU8, R: AsyncRead + ?Sized>(
61 buf: &mut VecWithInitialized<V>,
62 read: Pin<&mut R>,
63 cx: &mut Context<'_>,
64 ) -> Poll<io::Result<usize>> {
65 // This uses an adaptive system to extend the vector when it fills. We want to
66 // avoid paying to allocate and zero a huge chunk of memory if the reader only
67 // has 4 bytes while still making large reads if the reader does have a ton
68 // of data to return. Simply tacking on an extra DEFAULT_BUF_SIZE space every
69 // time is 4,500 times (!) slower than this if the reader has a very small
70 // amount of data to return. When the vector is full with its starting
71 // capacity, we first try to read into a small buffer to see if we reached
72 // an EOF. This only happens when the starting capacity is >= NUM_BYTES, since
73 // we allocate at least NUM_BYTES each time. This avoids the unnecessary
74 // allocation that we attempt before reading into the vector.
75
76 const NUM_BYTES: usize = 32;
77 let try_small_read = buf.try_small_read_first(NUM_BYTES);
78
79 // Get a ReadBuf into the vector.
80 let mut read_buf;
81 let poll_result;
82
83 let n = if try_small_read {
84 // Read some bytes using a small read.
85 let mut small_buf: [MaybeUninit<u8>; NUM_BYTES] = [MaybeUninit::uninit(); NUM_BYTES];
86 let mut small_read_buf = ReadBuf::uninit(&mut small_buf);
87 poll_result = read.poll_read(cx, &mut small_read_buf);
88 let to_write = small_read_buf.filled();
89
90 // Ensure we have enough space to fill our vector with what we read.
91 read_buf = buf.get_read_buf();
92 if to_write.len() > read_buf.remaining() {
93 buf.reserve(NUM_BYTES);
94 read_buf = buf.get_read_buf();
95 }
96 read_buf.put_slice(to_write);
97
98 to_write.len()
99 } else {
100 // Ensure we have enough space for reading.
101 buf.reserve(NUM_BYTES);
102 read_buf = buf.get_read_buf();
103
104 // Read data directly into vector.
105 let filled_before = read_buf.filled().len();
106 poll_result = read.poll_read(cx, &mut read_buf);
107
108 // Compute the number of bytes read.
109 read_buf.filled().len() - filled_before
110 };
111
112 // Update the length of the vector using the result of poll_read.
113 let read_buf_parts = into_read_buf_parts(read_buf);
114 buf.apply_read_buf(read_buf_parts);
115
116 match poll_result {
117 Poll::Pending => {
118 // In this case, nothing should have been read. However we still
119 // update the vector in case the poll_read call initialized parts of
120 // the vector's unused capacity.
121 debug_assert_eq!(n, 0);
122 Poll::Pending
123 }
124 Poll::Ready(Err(err)) => {
125 debug_assert_eq!(n, 0);
126 Poll::Ready(Err(err))
127 }
128 Poll::Ready(Ok(())) => Poll::Ready(Ok(n)),
129 }
130 }
131
132 impl<A> Future for ReadToEnd<'_, A>
133 where
134 A: AsyncRead + ?Sized + Unpin,
135 {
136 type Output = io::Result<usize>;
137
poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output>138 fn poll(self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<Self::Output> {
139 let me = self.project();
140
141 read_to_end_internal(me.buf, Pin::new(*me.reader), me.read, cx)
142 }
143 }
144