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use std::cmp;
use std::fmt;
#[cfg(all(feature = "server", feature = "runtime"))]
use std::future::Future;
use std::io::{self, IoSlice};
use std::marker::Unpin;
use std::mem::MaybeUninit;
#[cfg(all(feature = "server", feature = "runtime"))]
use std::time::Duration;
use bytes::{Buf, BufMut, Bytes, BytesMut};
use tokio::io::{AsyncRead, AsyncWrite, ReadBuf};
#[cfg(all(feature = "server", feature = "runtime"))]
use tokio::time::Instant;
use tracing::{debug, trace};
use super::{Http1Transaction, ParseContext, ParsedMessage};
use crate::common::buf::BufList;
use crate::common::{task, Pin, Poll};
/// The initial buffer size allocated before trying to read from IO.
pub(crate) const INIT_BUFFER_SIZE: usize = 8192;
/// The minimum value that can be set to max buffer size.
pub(crate) const MINIMUM_MAX_BUFFER_SIZE: usize = INIT_BUFFER_SIZE;
/// The default maximum read buffer size. If the buffer gets this big and
/// a message is still not complete, a `TooLarge` error is triggered.
// Note: if this changes, update server::conn::Http::max_buf_size docs.
pub(crate) const DEFAULT_MAX_BUFFER_SIZE: usize = 8192 + 4096 * 100;
/// The maximum number of distinct `Buf`s to hold in a list before requiring
/// a flush. Only affects when the buffer strategy is to queue buffers.
///
/// Note that a flush can happen before reaching the maximum. This simply
/// forces a flush if the queue gets this big.
const MAX_BUF_LIST_BUFFERS: usize = 16;
pub(crate) struct Buffered<T, B> {
flush_pipeline: bool,
io: T,
read_blocked: bool,
read_buf: BytesMut,
read_buf_strategy: ReadStrategy,
write_buf: WriteBuf<B>,
}
impl<T, B> fmt::Debug for Buffered<T, B>
where
B: Buf,
{
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("Buffered")
.field("read_buf", &self.read_buf)
.field("write_buf", &self.write_buf)
.finish()
}
}
impl<T, B> Buffered<T, B>
where
T: AsyncRead + AsyncWrite + Unpin,
B: Buf,
{
pub(crate) fn new(io: T) -> Buffered<T, B> {
let strategy = if io.is_write_vectored() {
WriteStrategy::Queue
} else {
WriteStrategy::Flatten
};
let write_buf = WriteBuf::new(strategy);
Buffered {
flush_pipeline: false,
io,
read_blocked: false,
read_buf: BytesMut::with_capacity(0),
read_buf_strategy: ReadStrategy::default(),
write_buf,
}
}
#[cfg(feature = "server")]
pub(crate) fn set_flush_pipeline(&mut self, enabled: bool) {
debug_assert!(!self.write_buf.has_remaining());
self.flush_pipeline = enabled;
if enabled {
self.set_write_strategy_flatten();
}
}
pub(crate) fn set_max_buf_size(&mut self, max: usize) {
assert!(
max >= MINIMUM_MAX_BUFFER_SIZE,
"The max_buf_size cannot be smaller than {}.",
MINIMUM_MAX_BUFFER_SIZE,
);
self.read_buf_strategy = ReadStrategy::with_max(max);
self.write_buf.max_buf_size = max;
}
#[cfg(feature = "client")]
pub(crate) fn set_read_buf_exact_size(&mut self, sz: usize) {
self.read_buf_strategy = ReadStrategy::Exact(sz);
}
pub(crate) fn set_write_strategy_flatten(&mut self) {
// this should always be called only at construction time,
// so this assert is here to catch myself
debug_assert!(self.write_buf.queue.bufs_cnt() == 0);
self.write_buf.set_strategy(WriteStrategy::Flatten);
}
pub(crate) fn set_write_strategy_queue(&mut self) {
// this should always be called only at construction time,
// so this assert is here to catch myself
debug_assert!(self.write_buf.queue.bufs_cnt() == 0);
self.write_buf.set_strategy(WriteStrategy::Queue);
}
pub(crate) fn read_buf(&self) -> &[u8] {
self.read_buf.as_ref()
}
#[cfg(test)]
#[cfg(feature = "nightly")]
pub(super) fn read_buf_mut(&mut self) -> &mut BytesMut {
&mut self.read_buf
}
/// Return the "allocated" available space, not the potential space
/// that could be allocated in the future.
fn read_buf_remaining_mut(&self) -> usize {
self.read_buf.capacity() - self.read_buf.len()
}
/// Return whether we can append to the headers buffer.
///
/// Reasons we can't:
/// - The write buf is in queue mode, and some of the past body is still
/// needing to be flushed.
pub(crate) fn can_headers_buf(&self) -> bool {
!self.write_buf.queue.has_remaining()
}
pub(crate) fn headers_buf(&mut self) -> &mut Vec<u8> {
let buf = self.write_buf.headers_mut();
&mut buf.bytes
}
pub(super) fn write_buf(&mut self) -> &mut WriteBuf<B> {
&mut self.write_buf
}
pub(crate) fn buffer<BB: Buf + Into<B>>(&mut self, buf: BB) {
self.write_buf.buffer(buf)
}
pub(crate) fn can_buffer(&self) -> bool {
self.flush_pipeline || self.write_buf.can_buffer()
}
pub(crate) fn consume_leading_lines(&mut self) {
if !self.read_buf.is_empty() {
let mut i = 0;
while i < self.read_buf.len() {
match self.read_buf[i] {
b'\r' | b'\n' => i += 1,
_ => break,
}
}
self.read_buf.advance(i);
}
}
pub(super) fn parse<S>(
&mut self,
cx: &mut task::Context<'_>,
parse_ctx: ParseContext<'_>,
) -> Poll<crate::Result<ParsedMessage<S::Incoming>>>
where
S: Http1Transaction,
{
loop {
match super::role::parse_headers::<S>(
&mut self.read_buf,
ParseContext {
cached_headers: parse_ctx.cached_headers,
req_method: parse_ctx.req_method,
h1_parser_config: parse_ctx.h1_parser_config.clone(),
#[cfg(all(feature = "server", feature = "runtime"))]
h1_header_read_timeout: parse_ctx.h1_header_read_timeout,
#[cfg(all(feature = "server", feature = "runtime"))]
h1_header_read_timeout_fut: parse_ctx.h1_header_read_timeout_fut,
#[cfg(all(feature = "server", feature = "runtime"))]
h1_header_read_timeout_running: parse_ctx.h1_header_read_timeout_running,
preserve_header_case: parse_ctx.preserve_header_case,
#[cfg(feature = "ffi")]
preserve_header_order: parse_ctx.preserve_header_order,
h09_responses: parse_ctx.h09_responses,
#[cfg(feature = "ffi")]
on_informational: parse_ctx.on_informational,
#[cfg(feature = "ffi")]
raw_headers: parse_ctx.raw_headers,
},
)? {
Some(msg) => {
debug!("parsed {} headers", msg.head.headers.len());
#[cfg(all(feature = "server", feature = "runtime"))]
{
*parse_ctx.h1_header_read_timeout_running = false;
if let Some(h1_header_read_timeout_fut) =
parse_ctx.h1_header_read_timeout_fut
{
// Reset the timer in order to avoid woken up when the timeout finishes
h1_header_read_timeout_fut
.as_mut()
.reset(Instant::now() + Duration::from_secs(30 * 24 * 60 * 60));
}
}
return Poll::Ready(Ok(msg));
}
None => {
let max = self.read_buf_strategy.max();
if self.read_buf.len() >= max {
debug!("max_buf_size ({}) reached, closing", max);
return Poll::Ready(Err(crate::Error::new_too_large()));
}
#[cfg(all(feature = "server", feature = "runtime"))]
if *parse_ctx.h1_header_read_timeout_running {
if let Some(h1_header_read_timeout_fut) =
parse_ctx.h1_header_read_timeout_fut
{
if Pin::new(h1_header_read_timeout_fut).poll(cx).is_ready() {
*parse_ctx.h1_header_read_timeout_running = false;
tracing::warn!("read header from client timeout");
return Poll::Ready(Err(crate::Error::new_header_timeout()));
}
}
}
}
}
if ready!(self.poll_read_from_io(cx)).map_err(crate::Error::new_io)? == 0 {
trace!("parse eof");
return Poll::Ready(Err(crate::Error::new_incomplete()));
}
}
}
pub(crate) fn poll_read_from_io(
&mut self,
cx: &mut task::Context<'_>,
) -> Poll<io::Result<usize>> {
self.read_blocked = false;
let next = self.read_buf_strategy.next();
if self.read_buf_remaining_mut() < next {
self.read_buf.reserve(next);
}
let dst = self.read_buf.chunk_mut();
let dst = unsafe { &mut *(dst as *mut _ as *mut [MaybeUninit<u8>]) };
let mut buf = ReadBuf::uninit(dst);
match Pin::new(&mut self.io).poll_read(cx, &mut buf) {
Poll::Ready(Ok(_)) => {
let n = buf.filled().len();
trace!("received {} bytes", n);
unsafe {
// Safety: we just read that many bytes into the
// uninitialized part of the buffer, so this is okay.
// @tokio pls give me back `poll_read_buf` thanks
self.read_buf.advance_mut(n);
}
self.read_buf_strategy.record(n);
Poll::Ready(Ok(n))
}
Poll::Pending => {
self.read_blocked = true;
Poll::Pending
}
Poll::Ready(Err(e)) => Poll::Ready(Err(e)),
}
}
pub(crate) fn into_inner(self) -> (T, Bytes) {
(self.io, self.read_buf.freeze())
}
pub(crate) fn io_mut(&mut self) -> &mut T {
&mut self.io
}
pub(crate) fn is_read_blocked(&self) -> bool {
self.read_blocked
}
pub(crate) fn poll_flush(&mut self, cx: &mut task::Context<'_>) -> Poll<io::Result<()>> {
if self.flush_pipeline && !self.read_buf.is_empty() {
Poll::Ready(Ok(()))
} else if self.write_buf.remaining() == 0 {
Pin::new(&mut self.io).poll_flush(cx)
} else {
if let WriteStrategy::Flatten = self.write_buf.strategy {
return self.poll_flush_flattened(cx);
}
const MAX_WRITEV_BUFS: usize = 64;
loop {
let n = {
let mut iovs = [IoSlice::new(&[]); MAX_WRITEV_BUFS];
let len = self.write_buf.chunks_vectored(&mut iovs);
ready!(Pin::new(&mut self.io).poll_write_vectored(cx, &iovs[..len]))?
};
// TODO(eliza): we have to do this manually because
// `poll_write_buf` doesn't exist in Tokio 0.3 yet...when
// `poll_write_buf` comes back, the manual advance will need to leave!
self.write_buf.advance(n);
debug!("flushed {} bytes", n);
if self.write_buf.remaining() == 0 {
break;
} else if n == 0 {
trace!(
"write returned zero, but {} bytes remaining",
self.write_buf.remaining()
);
return Poll::Ready(Err(io::ErrorKind::WriteZero.into()));
}
}
Pin::new(&mut self.io).poll_flush(cx)
}
}
/// Specialized version of `flush` when strategy is Flatten.
///
/// Since all buffered bytes are flattened into the single headers buffer,
/// that skips some bookkeeping around using multiple buffers.
fn poll_flush_flattened(&mut self, cx: &mut task::Context<'_>) -> Poll<io::Result<()>> {
loop {
let n = ready!(Pin::new(&mut self.io).poll_write(cx, self.write_buf.headers.chunk()))?;
debug!("flushed {} bytes", n);
self.write_buf.headers.advance(n);
if self.write_buf.headers.remaining() == 0 {
self.write_buf.headers.reset();
break;
} else if n == 0 {
trace!(
"write returned zero, but {} bytes remaining",
self.write_buf.remaining()
);
return Poll::Ready(Err(io::ErrorKind::WriteZero.into()));
}
}
Pin::new(&mut self.io).poll_flush(cx)
}
#[cfg(test)]
fn flush<'a>(&'a mut self) -> impl std::future::Future<Output = io::Result<()>> + 'a {
futures_util::future::poll_fn(move |cx| self.poll_flush(cx))
}
}
// The `B` is a `Buf`, we never project a pin to it
impl<T: Unpin, B> Unpin for Buffered<T, B> {}
// TODO: This trait is old... at least rename to PollBytes or something...
pub(crate) trait MemRead {
fn read_mem(&mut self, cx: &mut task::Context<'_>, len: usize) -> Poll<io::Result<Bytes>>;
}
impl<T, B> MemRead for Buffered<T, B>
where
T: AsyncRead + AsyncWrite + Unpin,
B: Buf,
{
fn read_mem(&mut self, cx: &mut task::Context<'_>, len: usize) -> Poll<io::Result<Bytes>> {
if !self.read_buf.is_empty() {
let n = std::cmp::min(len, self.read_buf.len());
Poll::Ready(Ok(self.read_buf.split_to(n).freeze()))
} else {
let n = ready!(self.poll_read_from_io(cx))?;
Poll::Ready(Ok(self.read_buf.split_to(::std::cmp::min(len, n)).freeze()))
}
}
}
#[derive(Clone, Copy, Debug)]
enum ReadStrategy {
Adaptive {
decrease_now: bool,
next: usize,
max: usize,
},
#[cfg(feature = "client")]
Exact(usize),
}
impl ReadStrategy {
fn with_max(max: usize) -> ReadStrategy {
ReadStrategy::Adaptive {
decrease_now: false,
next: INIT_BUFFER_SIZE,
max,
}
}
fn next(&self) -> usize {
match *self {
ReadStrategy::Adaptive { next, .. } => next,
#[cfg(feature = "client")]
ReadStrategy::Exact(exact) => exact,
}
}
fn max(&self) -> usize {
match *self {
ReadStrategy::Adaptive { max, .. } => max,
#[cfg(feature = "client")]
ReadStrategy::Exact(exact) => exact,
}
}
fn record(&mut self, bytes_read: usize) {
match *self {
ReadStrategy::Adaptive {
ref mut decrease_now,
ref mut next,
max,
..
} => {
if bytes_read >= *next {
*next = cmp::min(incr_power_of_two(*next), max);
*decrease_now = false;
} else {
let decr_to = prev_power_of_two(*next);
if bytes_read < decr_to {
if *decrease_now {
*next = cmp::max(decr_to, INIT_BUFFER_SIZE);
*decrease_now = false;
} else {
// Decreasing is a two "record" process.
*decrease_now = true;
}
} else {
// A read within the current range should cancel
// a potential decrease, since we just saw proof
// that we still need this size.
*decrease_now = false;
}
}
}
#[cfg(feature = "client")]
ReadStrategy::Exact(_) => (),
}
}
}
fn incr_power_of_two(n: usize) -> usize {
n.saturating_mul(2)
}
fn prev_power_of_two(n: usize) -> usize {
// Only way this shift can underflow is if n is less than 4.
// (Which would means `usize::MAX >> 64` and underflowed!)
debug_assert!(n >= 4);
(::std::usize::MAX >> (n.leading_zeros() + 2)) + 1
}
impl Default for ReadStrategy {
fn default() -> ReadStrategy {
ReadStrategy::with_max(DEFAULT_MAX_BUFFER_SIZE)
}
}
#[derive(Clone)]
pub(crate) struct Cursor<T> {
bytes: T,
pos: usize,
}
impl<T: AsRef<[u8]>> Cursor<T> {
#[inline]
pub(crate) fn new(bytes: T) -> Cursor<T> {
Cursor { bytes, pos: 0 }
}
}
impl Cursor<Vec<u8>> {
/// If we've advanced the position a bit in this cursor, and wish to
/// extend the underlying vector, we may wish to unshift the "read" bytes
/// off, and move everything else over.
fn maybe_unshift(&mut self, additional: usize) {
if self.pos == 0 {
// nothing to do
return;
}
if self.bytes.capacity() - self.bytes.len() >= additional {
// there's room!
return;
}
self.bytes.drain(0..self.pos);
self.pos = 0;
}
fn reset(&mut self) {
self.pos = 0;
self.bytes.clear();
}
}
impl<T: AsRef<[u8]>> fmt::Debug for Cursor<T> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("Cursor")
.field("pos", &self.pos)
.field("len", &self.bytes.as_ref().len())
.finish()
}
}
impl<T: AsRef<[u8]>> Buf for Cursor<T> {
#[inline]
fn remaining(&self) -> usize {
self.bytes.as_ref().len() - self.pos
}
#[inline]
fn chunk(&self) -> &[u8] {
&self.bytes.as_ref()[self.pos..]
}
#[inline]
fn advance(&mut self, cnt: usize) {
debug_assert!(self.pos + cnt <= self.bytes.as_ref().len());
self.pos += cnt;
}
}
// an internal buffer to collect writes before flushes
pub(super) struct WriteBuf<B> {
/// Re-usable buffer that holds message headers
headers: Cursor<Vec<u8>>,
max_buf_size: usize,
/// Deque of user buffers if strategy is Queue
queue: BufList<B>,
strategy: WriteStrategy,
}
impl<B: Buf> WriteBuf<B> {
fn new(strategy: WriteStrategy) -> WriteBuf<B> {
WriteBuf {
headers: Cursor::new(Vec::with_capacity(INIT_BUFFER_SIZE)),
max_buf_size: DEFAULT_MAX_BUFFER_SIZE,
queue: BufList::new(),
strategy,
}
}
}
impl<B> WriteBuf<B>
where
B: Buf,
{
fn set_strategy(&mut self, strategy: WriteStrategy) {
self.strategy = strategy;
}
pub(super) fn buffer<BB: Buf + Into<B>>(&mut self, mut buf: BB) {
debug_assert!(buf.has_remaining());
match self.strategy {
WriteStrategy::Flatten => {
let head = self.headers_mut();
head.maybe_unshift(buf.remaining());
trace!(
self.len = head.remaining(),
buf.len = buf.remaining(),
"buffer.flatten"
);
//perf: This is a little faster than <Vec as BufMut>>::put,
//but accomplishes the same result.
loop {
let adv = {
let slice = buf.chunk();
if slice.is_empty() {
return;
}
head.bytes.extend_from_slice(slice);
slice.len()
};
buf.advance(adv);
}
}
WriteStrategy::Queue => {
trace!(
self.len = self.remaining(),
buf.len = buf.remaining(),
"buffer.queue"
);
self.queue.push(buf.into());
}
}
}
fn can_buffer(&self) -> bool {
match self.strategy {
WriteStrategy::Flatten => self.remaining() < self.max_buf_size,
WriteStrategy::Queue => {
self.queue.bufs_cnt() < MAX_BUF_LIST_BUFFERS && self.remaining() < self.max_buf_size
}
}
}
fn headers_mut(&mut self) -> &mut Cursor<Vec<u8>> {
debug_assert!(!self.queue.has_remaining());
&mut self.headers
}
}
impl<B: Buf> fmt::Debug for WriteBuf<B> {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
f.debug_struct("WriteBuf")
.field("remaining", &self.remaining())
.field("strategy", &self.strategy)
.finish()
}
}
impl<B: Buf> Buf for WriteBuf<B> {
#[inline]
fn remaining(&self) -> usize {
self.headers.remaining() + self.queue.remaining()
}
#[inline]
fn chunk(&self) -> &[u8] {
let headers = self.headers.chunk();
if !headers.is_empty() {
headers
} else {
self.queue.chunk()
}
}
#[inline]
fn advance(&mut self, cnt: usize) {
let hrem = self.headers.remaining();
match hrem.cmp(&cnt) {
cmp::Ordering::Equal => self.headers.reset(),
cmp::Ordering::Greater => self.headers.advance(cnt),
cmp::Ordering::Less => {
let qcnt = cnt - hrem;
self.headers.reset();
self.queue.advance(qcnt);
}
}
}
#[inline]
fn chunks_vectored<'t>(&'t self, dst: &mut [IoSlice<'t>]) -> usize {
let n = self.headers.chunks_vectored(dst);
self.queue.chunks_vectored(&mut dst[n..]) + n
}
}
#[derive(Debug)]
enum WriteStrategy {
Flatten,
Queue,
}
#[cfg(test)]
mod tests {
use super::*;
use std::time::Duration;
use tokio_test::io::Builder as Mock;
// #[cfg(feature = "nightly")]
// use test::Bencher;
/*
impl<T: Read> MemRead for AsyncIo<T> {
fn read_mem(&mut self, len: usize) -> Poll<Bytes, io::Error> {
let mut v = vec![0; len];
let n = try_nb!(self.read(v.as_mut_slice()));
Ok(Async::Ready(BytesMut::from(&v[..n]).freeze()))
}
}
*/
#[tokio::test]
#[ignore]
async fn iobuf_write_empty_slice() {
// TODO(eliza): can i have writev back pls T_T
// // First, let's just check that the Mock would normally return an
// // error on an unexpected write, even if the buffer is empty...
// let mut mock = Mock::new().build();
// futures_util::future::poll_fn(|cx| {
// Pin::new(&mut mock).poll_write_buf(cx, &mut Cursor::new(&[]))
// })
// .await
// .expect_err("should be a broken pipe");
// // underlying io will return the logic error upon write,
// // so we are testing that the io_buf does not trigger a write
// // when there is nothing to flush
// let mock = Mock::new().build();
// let mut io_buf = Buffered::<_, Cursor<Vec<u8>>>::new(mock);
// io_buf.flush().await.expect("should short-circuit flush");
}
#[tokio::test]
async fn parse_reads_until_blocked() {
use crate::proto::h1::ClientTransaction;
let _ = pretty_env_logger::try_init();
let mock = Mock::new()
// Split over multiple reads will read all of it
.read(b"HTTP/1.1 200 OK\r\n")
.read(b"Server: hyper\r\n")
// missing last line ending
.wait(Duration::from_secs(1))
.build();
let mut buffered = Buffered::<_, Cursor<Vec<u8>>>::new(mock);
// We expect a `parse` to be not ready, and so can't await it directly.
// Rather, this `poll_fn` will wrap the `Poll` result.
futures_util::future::poll_fn(|cx| {
let parse_ctx = ParseContext {
cached_headers: &mut None,
req_method: &mut None,
h1_parser_config: Default::default(),
#[cfg(feature = "runtime")]
h1_header_read_timeout: None,
#[cfg(feature = "runtime")]
h1_header_read_timeout_fut: &mut None,
#[cfg(feature = "runtime")]
h1_header_read_timeout_running: &mut false,
preserve_header_case: false,
#[cfg(feature = "ffi")]
preserve_header_order: false,
h09_responses: false,
#[cfg(feature = "ffi")]
on_informational: &mut None,
#[cfg(feature = "ffi")]
raw_headers: false,
};
assert!(buffered
.parse::<ClientTransaction>(cx, parse_ctx)
.is_pending());
Poll::Ready(())
})
.await;
assert_eq!(
buffered.read_buf,
b"HTTP/1.1 200 OK\r\nServer: hyper\r\n"[..]
);
}
#[test]
fn read_strategy_adaptive_increments() {
let mut strategy = ReadStrategy::default();
assert_eq!(strategy.next(), 8192);
// Grows if record == next
strategy.record(8192);
assert_eq!(strategy.next(), 16384);
strategy.record(16384);
assert_eq!(strategy.next(), 32768);
// Enormous records still increment at same rate
strategy.record(::std::usize::MAX);
assert_eq!(strategy.next(), 65536);
let max = strategy.max();
while strategy.next() < max {
strategy.record(max);
}
assert_eq!(strategy.next(), max, "never goes over max");
strategy.record(max + 1);
assert_eq!(strategy.next(), max, "never goes over max");
}
#[test]
fn read_strategy_adaptive_decrements() {
let mut strategy = ReadStrategy::default();
strategy.record(8192);
assert_eq!(strategy.next(), 16384);
strategy.record(1);
assert_eq!(
strategy.next(),
16384,
"first smaller record doesn't decrement yet"
);
strategy.record(8192);
assert_eq!(strategy.next(), 16384, "record was with range");
strategy.record(1);
assert_eq!(
strategy.next(),
16384,
"in-range record should make this the 'first' again"
);
strategy.record(1);
assert_eq!(strategy.next(), 8192, "second smaller record decrements");
strategy.record(1);
assert_eq!(strategy.next(), 8192, "first doesn't decrement");
strategy.record(1);
assert_eq!(strategy.next(), 8192, "doesn't decrement under minimum");
}
#[test]
fn read_strategy_adaptive_stays_the_same() {
let mut strategy = ReadStrategy::default();
strategy.record(8192);
assert_eq!(strategy.next(), 16384);
strategy.record(8193);
assert_eq!(
strategy.next(),
16384,
"first smaller record doesn't decrement yet"
);
strategy.record(8193);
assert_eq!(
strategy.next(),
16384,
"with current step does not decrement"
);
}
#[test]
fn read_strategy_adaptive_max_fuzz() {
fn fuzz(max: usize) {
let mut strategy = ReadStrategy::with_max(max);
while strategy.next() < max {
strategy.record(::std::usize::MAX);
}
let mut next = strategy.next();
while next > 8192 {
strategy.record(1);
strategy.record(1);
next = strategy.next();
assert!(
next.is_power_of_two(),
"decrement should be powers of two: {} (max = {})",
next,
max,
);
}
}
let mut max = 8192;
while max < std::usize::MAX {
fuzz(max);
max = (max / 2).saturating_mul(3);
}
fuzz(::std::usize::MAX);
}
#[test]
#[should_panic]
#[cfg(debug_assertions)] // needs to trigger a debug_assert
fn write_buf_requires_non_empty_bufs() {
let mock = Mock::new().build();
let mut buffered = Buffered::<_, Cursor<Vec<u8>>>::new(mock);
buffered.buffer(Cursor::new(Vec::new()));
}
/*
TODO: needs tokio_test::io to allow configure write_buf calls
#[test]
fn write_buf_queue() {
let _ = pretty_env_logger::try_init();
let mock = AsyncIo::new_buf(vec![], 1024);
let mut buffered = Buffered::<_, Cursor<Vec<u8>>>::new(mock);
buffered.headers_buf().extend(b"hello ");
buffered.buffer(Cursor::new(b"world, ".to_vec()));
buffered.buffer(Cursor::new(b"it's ".to_vec()));
buffered.buffer(Cursor::new(b"hyper!".to_vec()));
assert_eq!(buffered.write_buf.queue.bufs_cnt(), 3);
buffered.flush().unwrap();
assert_eq!(buffered.io, b"hello world, it's hyper!");
assert_eq!(buffered.io.num_writes(), 1);
assert_eq!(buffered.write_buf.queue.bufs_cnt(), 0);
}
*/
#[tokio::test]
async fn write_buf_flatten() {
let _ = pretty_env_logger::try_init();
let mock = Mock::new().write(b"hello world, it's hyper!").build();
let mut buffered = Buffered::<_, Cursor<Vec<u8>>>::new(mock);
buffered.write_buf.set_strategy(WriteStrategy::Flatten);
buffered.headers_buf().extend(b"hello ");
buffered.buffer(Cursor::new(b"world, ".to_vec()));
buffered.buffer(Cursor::new(b"it's ".to_vec()));
buffered.buffer(Cursor::new(b"hyper!".to_vec()));
assert_eq!(buffered.write_buf.queue.bufs_cnt(), 0);
buffered.flush().await.expect("flush");
}
#[test]
fn write_buf_flatten_partially_flushed() {
let _ = pretty_env_logger::try_init();
let b = |s: &str| Cursor::new(s.as_bytes().to_vec());
let mut write_buf = WriteBuf::<Cursor<Vec<u8>>>::new(WriteStrategy::Flatten);
write_buf.buffer(b("hello "));
write_buf.buffer(b("world, "));
assert_eq!(write_buf.chunk(), b"hello world, ");
// advance most of the way, but not all
write_buf.advance(11);
assert_eq!(write_buf.chunk(), b", ");
assert_eq!(write_buf.headers.pos, 11);
assert_eq!(write_buf.headers.bytes.capacity(), INIT_BUFFER_SIZE);
// there's still room in the headers buffer, so just push on the end
write_buf.buffer(b("it's hyper!"));
assert_eq!(write_buf.chunk(), b", it's hyper!");
assert_eq!(write_buf.headers.pos, 11);
let rem1 = write_buf.remaining();
let cap = write_buf.headers.bytes.capacity();
// but when this would go over capacity, don't copy the old bytes
write_buf.buffer(Cursor::new(vec![b'X'; cap]));
assert_eq!(write_buf.remaining(), cap + rem1);
assert_eq!(write_buf.headers.pos, 0);
}
#[tokio::test]
async fn write_buf_queue_disable_auto() {
let _ = pretty_env_logger::try_init();
let mock = Mock::new()
.write(b"hello ")
.write(b"world, ")
.write(b"it's ")
.write(b"hyper!")
.build();
let mut buffered = Buffered::<_, Cursor<Vec<u8>>>::new(mock);
buffered.write_buf.set_strategy(WriteStrategy::Queue);
// we have 4 buffers, and vec IO disabled, but explicitly said
// don't try to auto detect (via setting strategy above)
buffered.headers_buf().extend(b"hello ");
buffered.buffer(Cursor::new(b"world, ".to_vec()));
buffered.buffer(Cursor::new(b"it's ".to_vec()));
buffered.buffer(Cursor::new(b"hyper!".to_vec()));
assert_eq!(buffered.write_buf.queue.bufs_cnt(), 3);
buffered.flush().await.expect("flush");
assert_eq!(buffered.write_buf.queue.bufs_cnt(), 0);
}
// #[cfg(feature = "nightly")]
// #[bench]
// fn bench_write_buf_flatten_buffer_chunk(b: &mut Bencher) {
// let s = "Hello, World!";
// b.bytes = s.len() as u64;
// let mut write_buf = WriteBuf::<bytes::Bytes>::new();
// write_buf.set_strategy(WriteStrategy::Flatten);
// b.iter(|| {
// let chunk = bytes::Bytes::from(s);
// write_buf.buffer(chunk);
// ::test::black_box(&write_buf);
// write_buf.headers.bytes.clear();
// })
// }
}