deno/ext/http/response_body.rs

// Copyright 2018-2024 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 hyper::body::Frame;
use hyper::body::SizeHint;
use hyper::header::HeaderMap;
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);
}