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denoland-deno/ext/http/response_body.rs
Laurence Rowe e5819777c3
refactor(ext/http): Use HttpRecord as response body to track until body completion (#20822)
Use HttpRecord as response body so requests can be tracked all the way
to response body completion.

This allows Request properties to be accessed while the response body is
streaming.

Graceful shutdown now awaits a future instead of async spinning waiting
for requests to finish.

On the minimal benchmark this refactor improves performance an
additional 2% over pooling alone for a net 3% increase over the previous
deno main branch.

Builds upon https://github.com/denoland/deno/pull/20809 and
https://github.com/denoland/deno/pull/20770.

---------

Co-authored-by: Matt Mastracci <matthew@mastracci.com>
2023-11-13 19:17:31 +00:00

862 lines
24 KiB
Rust

// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
use std::io::Write;
use std::pin::Pin;
use std::rc::Rc;
use brotli::enc::encode::BrotliEncoderParameter;
use brotli::ffi::compressor::BrotliEncoderState;
use bytes::Bytes;
use bytes::BytesMut;
use deno_core::error::AnyError;
use deno_core::futures::ready;
use deno_core::futures::FutureExt;
use deno_core::AsyncResult;
use deno_core::BufView;
use deno_core::Resource;
use flate2::write::GzEncoder;
use http::HeaderMap;
use hyper1::body::Frame;
use hyper1::body::SizeHint;
use pin_project::pin_project;
/// Simplification for nested types we use for our streams. We provide a way to convert from
/// this type into Hyper's body [`Frame`].
pub enum ResponseStreamResult {
/// Stream is over.
EndOfStream,
/// Stream provided non-empty data.
NonEmptyBuf(BufView),
/// Stream is ready, but provided no data. Retry. This is a result that is like Pending, but does
/// not register a waker and should be called again at the lowest level of this code. Generally this
/// will only be returned from compression streams that require additional buffering.
NoData,
/// Stream provided trailers.
// TODO(mmastrac): We are threading trailers through the response system to eventually support Grpc.
#[allow(unused)]
Trailers(HeaderMap),
/// Stream failed.
Error(AnyError),
}
impl From<ResponseStreamResult> for Option<Result<Frame<BufView>, AnyError>> {
fn from(value: ResponseStreamResult) -> Self {
match value {
ResponseStreamResult::EndOfStream => None,
ResponseStreamResult::NonEmptyBuf(buf) => Some(Ok(Frame::data(buf))),
ResponseStreamResult::Error(err) => Some(Err(err)),
ResponseStreamResult::Trailers(map) => Some(Ok(Frame::trailers(map))),
// This result should be handled by retrying
ResponseStreamResult::NoData => unimplemented!(),
}
}
}
pub trait PollFrame: Unpin {
fn poll_frame(
self: Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<ResponseStreamResult>;
fn size_hint(&self) -> SizeHint;
}
#[derive(PartialEq, Eq)]
pub enum Compression {
None,
GZip,
Brotli,
}
pub enum ResponseStream {
/// A resource stream, piped in fast mode.
Resource(ResourceBodyAdapter),
#[cfg(test)]
TestChannel(tokio::sync::mpsc::Receiver<BufView>),
}
impl ResponseStream {
pub fn abort(self) {
match self {
ResponseStream::Resource(resource) => resource.stm.close(),
#[cfg(test)]
ResponseStream::TestChannel(..) => {}
}
}
}
#[derive(Default)]
pub enum ResponseBytesInner {
/// An empty stream.
#[default]
Empty,
/// A completed stream.
Done,
/// A static buffer of bytes, sent in one fell swoop.
Bytes(BufView),
/// An uncompressed stream.
UncompressedStream(ResponseStream),
/// A GZip stream.
GZipStream(GZipResponseStream),
/// A Brotli stream.
BrotliStream(BrotliResponseStream),
}
impl std::fmt::Debug for ResponseBytesInner {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
Self::Done => f.write_str("Done"),
Self::Empty => f.write_str("Empty"),
Self::Bytes(..) => f.write_str("Bytes"),
Self::UncompressedStream(..) => f.write_str("Uncompressed"),
Self::GZipStream(..) => f.write_str("GZip"),
Self::BrotliStream(..) => f.write_str("Brotli"),
}
}
}
impl ResponseBytesInner {
pub fn abort(self) {
match self {
Self::Done | Self::Empty | Self::Bytes(..) => {}
Self::BrotliStream(stm) => stm.abort(),
Self::GZipStream(stm) => stm.abort(),
Self::UncompressedStream(stm) => stm.abort(),
}
}
pub fn size_hint(&self) -> SizeHint {
match self {
Self::Done => SizeHint::with_exact(0),
Self::Empty => SizeHint::with_exact(0),
Self::Bytes(bytes) => SizeHint::with_exact(bytes.len() as u64),
Self::UncompressedStream(res) => res.size_hint(),
Self::GZipStream(..) => SizeHint::default(),
Self::BrotliStream(..) => SizeHint::default(),
}
}
fn from_stream(compression: Compression, stream: ResponseStream) -> Self {
match compression {
Compression::GZip => Self::GZipStream(GZipResponseStream::new(stream)),
Compression::Brotli => {
Self::BrotliStream(BrotliResponseStream::new(stream))
}
_ => Self::UncompressedStream(stream),
}
}
pub fn from_resource(
compression: Compression,
stm: Rc<dyn Resource>,
auto_close: bool,
) -> Self {
Self::from_stream(
compression,
ResponseStream::Resource(ResourceBodyAdapter::new(stm, auto_close)),
)
}
pub fn from_bufview(compression: Compression, buf: BufView) -> Self {
match compression {
Compression::GZip => {
let mut writer =
GzEncoder::new(Vec::new(), flate2::Compression::fast());
writer.write_all(&buf).unwrap();
Self::Bytes(BufView::from(writer.finish().unwrap()))
}
Compression::Brotli => {
// quality level 6 is based on google's nginx default value for
// on-the-fly compression
// https://github.com/google/ngx_brotli#brotli_comp_level
// lgwin 22 is equivalent to brotli window size of (2**22)-16 bytes
// (~4MB)
let mut writer =
brotli::CompressorWriter::new(Vec::new(), 65 * 1024, 6, 22);
writer.write_all(&buf).unwrap();
writer.flush().unwrap();
Self::Bytes(BufView::from(writer.into_inner()))
}
_ => Self::Bytes(buf),
}
}
pub fn from_vec(compression: Compression, vec: Vec<u8>) -> Self {
match compression {
Compression::GZip => {
let mut writer =
GzEncoder::new(Vec::new(), flate2::Compression::fast());
writer.write_all(&vec).unwrap();
Self::Bytes(BufView::from(writer.finish().unwrap()))
}
Compression::Brotli => {
let mut writer =
brotli::CompressorWriter::new(Vec::new(), 65 * 1024, 6, 22);
writer.write_all(&vec).unwrap();
writer.flush().unwrap();
Self::Bytes(BufView::from(writer.into_inner()))
}
_ => Self::Bytes(BufView::from(vec)),
}
}
}
pub struct ResourceBodyAdapter {
auto_close: bool,
stm: Rc<dyn Resource>,
future: AsyncResult<BufView>,
}
impl ResourceBodyAdapter {
pub fn new(stm: Rc<dyn Resource>, auto_close: bool) -> Self {
let future = stm.clone().read(64 * 1024);
ResourceBodyAdapter {
auto_close,
stm,
future,
}
}
}
impl PollFrame for ResponseStream {
fn poll_frame(
mut self: Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<ResponseStreamResult> {
match &mut *self {
ResponseStream::Resource(res) => Pin::new(res).poll_frame(cx),
#[cfg(test)]
ResponseStream::TestChannel(rx) => Pin::new(rx).poll_frame(cx),
}
}
fn size_hint(&self) -> SizeHint {
match self {
ResponseStream::Resource(res) => res.size_hint(),
#[cfg(test)]
ResponseStream::TestChannel(_) => SizeHint::default(),
}
}
}
impl PollFrame for ResourceBodyAdapter {
fn poll_frame(
mut self: Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<ResponseStreamResult> {
let res = match ready!(self.future.poll_unpin(cx)) {
Err(err) => ResponseStreamResult::Error(err),
Ok(buf) => {
if buf.is_empty() {
if self.auto_close {
self.stm.clone().close();
}
ResponseStreamResult::EndOfStream
} else {
// Re-arm the future
self.future = self.stm.clone().read(64 * 1024);
ResponseStreamResult::NonEmptyBuf(buf)
}
}
};
std::task::Poll::Ready(res)
}
fn size_hint(&self) -> SizeHint {
let hint = self.stm.size_hint();
let mut size_hint = SizeHint::new();
size_hint.set_lower(hint.0);
if let Some(upper) = hint.1 {
size_hint.set_upper(upper)
}
size_hint
}
}
#[cfg(test)]
impl PollFrame for tokio::sync::mpsc::Receiver<BufView> {
fn poll_frame(
mut self: Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<ResponseStreamResult> {
let res = match ready!(self.poll_recv(cx)) {
Some(buf) => ResponseStreamResult::NonEmptyBuf(buf),
None => ResponseStreamResult::EndOfStream,
};
std::task::Poll::Ready(res)
}
fn size_hint(&self) -> SizeHint {
SizeHint::default()
}
}
#[derive(Copy, Clone, Debug)]
enum GZipState {
Header,
Streaming,
Flushing,
Trailer,
EndOfStream,
}
#[pin_project]
pub struct GZipResponseStream {
stm: flate2::Compress,
crc: flate2::Crc,
next_buf: Option<BytesMut>,
partial: Option<BufView>,
#[pin]
underlying: ResponseStream,
state: GZipState,
}
impl GZipResponseStream {
pub fn new(underlying: ResponseStream) -> Self {
Self {
stm: flate2::Compress::new(flate2::Compression::fast(), false),
crc: flate2::Crc::new(),
next_buf: None,
partial: None,
state: GZipState::Header,
underlying,
}
}
pub fn abort(self) {
self.underlying.abort()
}
}
/// This is a minimal GZip header suitable for serving data from a webserver. We don't need to provide
/// most of the information. We're skipping header name, CRC, etc, and providing a null timestamp.
///
/// We're using compression level 1, as higher levels don't produce significant size differences. This
/// is probably the reason why nginx's default gzip compression level is also 1:
///
/// https://nginx.org/en/docs/http/ngx_http_gzip_module.html#gzip_comp_level
static GZIP_HEADER: Bytes =
Bytes::from_static(&[0x1f, 0x8b, 0x08, 0, 0, 0, 0, 0, 0x01, 0xff]);
impl PollFrame for GZipResponseStream {
fn poll_frame(
self: Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<ResponseStreamResult> {
let this = self.get_mut();
let state = &mut this.state;
let orig_state = *state;
let frame = match *state {
GZipState::EndOfStream => {
return std::task::Poll::Ready(ResponseStreamResult::EndOfStream)
}
GZipState::Header => {
*state = GZipState::Streaming;
return std::task::Poll::Ready(ResponseStreamResult::NonEmptyBuf(
BufView::from(GZIP_HEADER.clone()),
));
}
GZipState::Trailer => {
*state = GZipState::EndOfStream;
let mut v = Vec::with_capacity(8);
v.extend(&this.crc.sum().to_le_bytes());
v.extend(&this.crc.amount().to_le_bytes());
return std::task::Poll::Ready(ResponseStreamResult::NonEmptyBuf(
BufView::from(v),
));
}
GZipState::Streaming => {
if let Some(partial) = this.partial.take() {
ResponseStreamResult::NonEmptyBuf(partial)
} else {
ready!(Pin::new(&mut this.underlying).poll_frame(cx))
}
}
GZipState::Flushing => ResponseStreamResult::EndOfStream,
};
let stm = &mut this.stm;
// Ideally we could use MaybeUninit here, but flate2 requires &[u8]. We should also try
// to dynamically adjust this buffer.
let mut buf = this
.next_buf
.take()
.unwrap_or_else(|| BytesMut::zeroed(64 * 1024));
let start_in = stm.total_in();
let start_out = stm.total_out();
let res = match frame {
// Short-circuit these and just return
x @ (ResponseStreamResult::NoData
| ResponseStreamResult::Error(..)
| ResponseStreamResult::Trailers(..)) => {
return std::task::Poll::Ready(x)
}
ResponseStreamResult::EndOfStream => {
*state = GZipState::Flushing;
stm.compress(&[], &mut buf, flate2::FlushCompress::Finish)
}
ResponseStreamResult::NonEmptyBuf(mut input) => {
let res = stm.compress(&input, &mut buf, flate2::FlushCompress::None);
let len_in = (stm.total_in() - start_in) as usize;
debug_assert!(len_in <= input.len());
this.crc.update(&input[..len_in]);
if len_in < input.len() {
input.advance_cursor(len_in);
this.partial = Some(input);
}
res
}
};
let len = stm.total_out() - start_out;
let res = match res {
Err(err) => ResponseStreamResult::Error(err.into()),
Ok(flate2::Status::BufError) => {
// This should not happen
unreachable!("old={orig_state:?} new={state:?} buf_len={}", buf.len());
}
Ok(flate2::Status::Ok) => {
if len == 0 {
this.next_buf = Some(buf);
ResponseStreamResult::NoData
} else {
buf.truncate(len as usize);
ResponseStreamResult::NonEmptyBuf(BufView::from(buf.freeze()))
}
}
Ok(flate2::Status::StreamEnd) => {
*state = GZipState::Trailer;
if len == 0 {
this.next_buf = Some(buf);
ResponseStreamResult::NoData
} else {
buf.truncate(len as usize);
ResponseStreamResult::NonEmptyBuf(BufView::from(buf.freeze()))
}
}
};
std::task::Poll::Ready(res)
}
fn size_hint(&self) -> SizeHint {
SizeHint::default()
}
}
#[derive(Copy, Clone, Debug)]
enum BrotliState {
Streaming,
Flushing,
EndOfStream,
}
struct BrotliEncoderStateWrapper {
stm: *mut BrotliEncoderState,
}
#[pin_project]
pub struct BrotliResponseStream {
state: BrotliState,
stm: BrotliEncoderStateWrapper,
current_cursor: usize,
output_written_so_far: usize,
#[pin]
underlying: ResponseStream,
}
impl Drop for BrotliEncoderStateWrapper {
fn drop(&mut self) {
// SAFETY: since we are dropping, we can be sure that this instance will not
// be used again.
unsafe {
brotli::ffi::compressor::BrotliEncoderDestroyInstance(self.stm);
}
}
}
impl BrotliResponseStream {
pub fn new(underlying: ResponseStream) -> Self {
// SAFETY: creating an FFI instance should be OK with these args.
let stm = unsafe {
let stm = brotli::ffi::compressor::BrotliEncoderCreateInstance(
None,
None,
std::ptr::null_mut(),
);
// Quality level 6 is based on google's nginx default value for on-the-fly compression
// https://github.com/google/ngx_brotli#brotli_comp_level
// lgwin 22 is equivalent to brotli window size of (2**22)-16 bytes (~4MB)
brotli::ffi::compressor::BrotliEncoderSetParameter(
stm,
BrotliEncoderParameter::BROTLI_PARAM_QUALITY,
6,
);
brotli::ffi::compressor::BrotliEncoderSetParameter(
stm,
BrotliEncoderParameter::BROTLI_PARAM_LGWIN,
22,
);
BrotliEncoderStateWrapper { stm }
};
Self {
stm,
output_written_so_far: 0,
current_cursor: 0,
state: BrotliState::Streaming,
underlying,
}
}
pub fn abort(self) {
self.underlying.abort()
}
}
fn max_compressed_size(input_size: usize) -> usize {
if input_size == 0 {
return 2;
}
// [window bits / empty metadata] + N * [uncompressed] + [last empty]
let num_large_blocks = input_size >> 14;
let overhead = 2 + (4 * num_large_blocks) + 3 + 1;
let result = input_size + overhead;
if result < input_size {
0
} else {
result
}
}
impl PollFrame for BrotliResponseStream {
fn poll_frame(
self: Pin<&mut Self>,
cx: &mut std::task::Context<'_>,
) -> std::task::Poll<ResponseStreamResult> {
let this = self.get_mut();
let state = &mut this.state;
let frame = match *state {
BrotliState::Streaming => {
ready!(Pin::new(&mut this.underlying).poll_frame(cx))
}
BrotliState::Flushing => ResponseStreamResult::EndOfStream,
BrotliState::EndOfStream => {
return std::task::Poll::Ready(ResponseStreamResult::EndOfStream);
}
};
let res = match frame {
ResponseStreamResult::NonEmptyBuf(buf) => {
let mut output_written = 0;
let mut total_output_written = 0;
let mut input_size = buf.len();
let input_buffer = buf.as_ref();
let mut len = max_compressed_size(input_size);
let mut output_buffer = vec![0u8; len];
let mut ob_ptr = output_buffer.as_mut_ptr();
// SAFETY: these are okay arguments to these FFI calls.
unsafe {
brotli::ffi::compressor::BrotliEncoderCompressStream(
this.stm.stm,
brotli::ffi::compressor::BrotliEncoderOperation::BROTLI_OPERATION_PROCESS,
&mut input_size,
&input_buffer.as_ptr() as *const *const u8 as *mut *const u8,
&mut len,
&mut ob_ptr,
&mut output_written,
);
total_output_written += output_written;
output_written = 0;
brotli::ffi::compressor::BrotliEncoderCompressStream(
this.stm.stm,
brotli::ffi::compressor::BrotliEncoderOperation::BROTLI_OPERATION_FLUSH,
&mut input_size,
&input_buffer.as_ptr() as *const *const u8 as *mut *const u8,
&mut len,
&mut ob_ptr,
&mut output_written,
);
total_output_written += output_written;
};
output_buffer
.truncate(total_output_written - this.output_written_so_far);
this.output_written_so_far = total_output_written;
ResponseStreamResult::NonEmptyBuf(BufView::from(output_buffer))
}
ResponseStreamResult::EndOfStream => {
let mut len = 1024usize;
let mut output_buffer = vec![0u8; len];
let mut input_size = 0;
let mut output_written = 0;
let ob_ptr = output_buffer.as_mut_ptr();
// SAFETY: these are okay arguments to these FFI calls.
unsafe {
brotli::ffi::compressor::BrotliEncoderCompressStream(
this.stm.stm,
brotli::ffi::compressor::BrotliEncoderOperation::BROTLI_OPERATION_FINISH,
&mut input_size,
std::ptr::null_mut(),
&mut len,
&ob_ptr as *const *mut u8 as *mut *mut u8,
&mut output_written,
);
};
if output_written == 0 {
this.state = BrotliState::EndOfStream;
ResponseStreamResult::EndOfStream
} else {
this.state = BrotliState::Flushing;
output_buffer.truncate(output_written - this.output_written_so_far);
ResponseStreamResult::NonEmptyBuf(BufView::from(output_buffer))
}
}
_ => frame,
};
std::task::Poll::Ready(res)
}
fn size_hint(&self) -> SizeHint {
SizeHint::default()
}
}
#[cfg(test)]
mod tests {
use super::*;
use deno_core::futures::future::poll_fn;
use std::hash::Hasher;
use std::io::Read;
use std::io::Write;
fn zeros() -> Vec<u8> {
vec![0; 1024 * 1024]
}
fn hard_to_gzip_data() -> Vec<u8> {
const SIZE: usize = 1024 * 1024;
let mut v = Vec::with_capacity(SIZE);
let mut hasher = std::collections::hash_map::DefaultHasher::new();
for i in 0..SIZE {
hasher.write_usize(i);
v.push(hasher.finish() as u8);
}
v
}
fn already_gzipped_data() -> Vec<u8> {
let mut v = Vec::with_capacity(1024 * 1024);
let mut gz =
flate2::GzBuilder::new().write(&mut v, flate2::Compression::best());
gz.write_all(&hard_to_gzip_data()).unwrap();
_ = gz.finish().unwrap();
v
}
fn chunk(v: Vec<u8>) -> impl Iterator<Item = Vec<u8>> {
// Chunk the data into 10k
let mut out = vec![];
for v in v.chunks(10 * 1024) {
out.push(v.to_vec());
}
out.into_iter()
}
fn random(mut v: Vec<u8>) -> impl Iterator<Item = Vec<u8>> {
let mut out = vec![];
loop {
if v.is_empty() {
break;
}
let rand = (rand::random::<usize>() % v.len()) + 1;
let new = v.split_off(rand);
out.push(v);
v = new;
}
// Print the lengths of the vectors if we actually fail this test at some point
let lengths = out.iter().map(|v| v.len()).collect::<Vec<_>>();
eprintln!("Lengths = {:?}", lengths);
out.into_iter()
}
fn front_load(mut v: Vec<u8>) -> impl Iterator<Item = Vec<u8>> {
// Chunk the data at 90%
let offset = (v.len() * 90) / 100;
let v2 = v.split_off(offset);
vec![v, v2].into_iter()
}
fn front_load_but_one(mut v: Vec<u8>) -> impl Iterator<Item = Vec<u8>> {
let offset = v.len() - 1;
let v2 = v.split_off(offset);
vec![v, v2].into_iter()
}
fn back_load(mut v: Vec<u8>) -> impl Iterator<Item = Vec<u8>> {
// Chunk the data at 10%
let offset = (v.len() * 10) / 100;
let v2 = v.split_off(offset);
vec![v, v2].into_iter()
}
async fn test_gzip(i: impl Iterator<Item = Vec<u8>> + Send + 'static) {
let v = i.collect::<Vec<_>>();
let mut expected: Vec<u8> = vec![];
for v in &v {
expected.extend(v);
}
let (tx, rx) = tokio::sync::mpsc::channel(1);
let underlying = ResponseStream::TestChannel(rx);
let mut resp = GZipResponseStream::new(underlying);
let handle = tokio::task::spawn(async move {
for chunk in v {
tx.send(chunk.into()).await.ok().unwrap();
}
});
// Limit how many times we'll loop
const LIMIT: usize = 1000;
let mut v: Vec<u8> = vec![];
for i in 0..=LIMIT {
assert_ne!(i, LIMIT);
let frame = poll_fn(|cx| Pin::new(&mut resp).poll_frame(cx)).await;
if matches!(frame, ResponseStreamResult::EndOfStream) {
break;
}
if matches!(frame, ResponseStreamResult::NoData) {
continue;
}
let ResponseStreamResult::NonEmptyBuf(buf) = frame else {
panic!("Unexpected stream type");
};
assert_ne!(buf.len(), 0);
v.extend(&*buf);
}
let mut gz = flate2::read::GzDecoder::new(&*v);
let mut v = vec![];
gz.read_to_end(&mut v).unwrap();
assert_eq!(v, expected);
handle.await.unwrap();
}
async fn test_brotli(i: impl Iterator<Item = Vec<u8>> + Send + 'static) {
let v = i.collect::<Vec<_>>();
let mut expected: Vec<u8> = vec![];
for v in &v {
expected.extend(v);
}
let (tx, rx) = tokio::sync::mpsc::channel(1);
let underlying = ResponseStream::TestChannel(rx);
let mut resp = BrotliResponseStream::new(underlying);
let handle = tokio::task::spawn(async move {
for chunk in v {
tx.send(chunk.into()).await.ok().unwrap();
}
});
// Limit how many times we'll loop
const LIMIT: usize = 1000;
let mut v: Vec<u8> = vec![];
for i in 0..=LIMIT {
assert_ne!(i, LIMIT);
let frame = poll_fn(|cx| Pin::new(&mut resp).poll_frame(cx)).await;
if matches!(frame, ResponseStreamResult::EndOfStream) {
break;
}
if matches!(frame, ResponseStreamResult::NoData) {
continue;
}
let ResponseStreamResult::NonEmptyBuf(buf) = frame else {
panic!("Unexpected stream type");
};
assert_ne!(buf.len(), 0);
v.extend(&*buf);
}
let mut gz = brotli::Decompressor::new(&*v, v.len());
let mut v = vec![];
if !expected.is_empty() {
gz.read_to_end(&mut v).unwrap();
}
assert_eq!(v, expected);
handle.await.unwrap();
}
#[tokio::test]
async fn test_simple() {
test_brotli(vec![b"hello world".to_vec()].into_iter()).await;
test_gzip(vec![b"hello world".to_vec()].into_iter()).await;
}
#[tokio::test]
async fn test_empty() {
test_brotli(vec![].into_iter()).await;
test_gzip(vec![].into_iter()).await;
}
#[tokio::test]
async fn test_simple_zeros() {
test_brotli(vec![vec![0; 0x10000]].into_iter()).await;
test_gzip(vec![vec![0; 0x10000]].into_iter()).await;
}
macro_rules! test {
($vec:ident) => {
mod $vec {
#[tokio::test]
async fn chunk() {
let iter = super::chunk(super::$vec());
super::test_gzip(iter).await;
let br_iter = super::chunk(super::$vec());
super::test_brotli(br_iter).await;
}
#[tokio::test]
async fn front_load() {
let iter = super::front_load(super::$vec());
super::test_gzip(iter).await;
let br_iter = super::front_load(super::$vec());
super::test_brotli(br_iter).await;
}
#[tokio::test]
async fn front_load_but_one() {
let iter = super::front_load_but_one(super::$vec());
super::test_gzip(iter).await;
let br_iter = super::front_load_but_one(super::$vec());
super::test_brotli(br_iter).await;
}
#[tokio::test]
async fn back_load() {
let iter = super::back_load(super::$vec());
super::test_gzip(iter).await;
let br_iter = super::back_load(super::$vec());
super::test_brotli(br_iter).await;
}
#[tokio::test]
async fn random() {
let iter = super::random(super::$vec());
super::test_gzip(iter).await;
let br_iter = super::random(super::$vec());
super::test_brotli(br_iter).await;
}
}
};
}
test!(zeros);
test!(hard_to_gzip_data);
test!(already_gzipped_data);
}