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693 lines
22 KiB
Rust
693 lines
22 KiB
Rust
// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
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use super::TestEvent;
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use deno_core::futures::future::poll_fn;
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use deno_core::parking_lot;
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use deno_core::parking_lot::lock_api::RawMutex;
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use deno_core::parking_lot::lock_api::RawMutexTimed;
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use deno_runtime::deno_io::pipe;
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use deno_runtime::deno_io::AsyncPipeRead;
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use deno_runtime::deno_io::PipeRead;
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use deno_runtime::deno_io::PipeWrite;
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use memmem::Searcher;
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use std::fmt::Display;
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use std::future::Future;
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use std::io::Write;
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use std::pin::Pin;
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use std::sync::atomic::AtomicUsize;
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use std::sync::atomic::Ordering;
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use std::task::ready;
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use std::task::Poll;
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use std::time::Duration;
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use tokio::io::AsyncRead;
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use tokio::io::AsyncReadExt;
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use tokio::io::ReadBuf;
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use tokio::sync::mpsc::error::SendError;
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use tokio::sync::mpsc::UnboundedReceiver;
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use tokio::sync::mpsc::UnboundedSender;
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use tokio::sync::mpsc::WeakUnboundedSender;
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/// 8-byte sync marker that is unlikely to appear in normal output. Equivalent
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/// to the string `"\u{200B}\0\u{200B}\0"`.
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const SYNC_MARKER: &[u8; 8] = &[226, 128, 139, 0, 226, 128, 139, 0];
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const HALF_SYNC_MARKER: &[u8; 4] = &[226, 128, 139, 0];
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const BUFFER_SIZE: usize = 4096;
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/// The test channel has been closed and cannot be used to send further messages.
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#[derive(Debug, Copy, Clone, Eq, PartialEq)]
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pub struct ChannelClosedError;
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impl std::error::Error for ChannelClosedError {}
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impl Display for ChannelClosedError {
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fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
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f.write_str("Test channel closed")
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}
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}
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impl<T> From<SendError<T>> for ChannelClosedError {
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fn from(_: SendError<T>) -> Self {
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Self
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}
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}
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#[repr(transparent)]
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struct SendMutex(*const parking_lot::RawMutex);
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impl Drop for SendMutex {
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fn drop(&mut self) {
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// SAFETY: We know this was locked by the sender
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unsafe {
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(*self.0).unlock();
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}
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}
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}
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// SAFETY: This is a mutex, so it's safe to send a pointer to it
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unsafe impl Send for SendMutex {}
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/// Create a [`TestEventSenderFactory`] and [`TestEventReceiver`] pair. The [`TestEventSenderFactory`] may be
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/// used to create [`TestEventSender`]s and stdio streams for multiple workers in the system. The [`TestEventReceiver`]
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/// will be kept alive until the final [`TestEventSender`] is dropped.
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pub fn create_test_event_channel() -> (TestEventSenderFactory, TestEventReceiver)
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{
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let (sender, receiver) = tokio::sync::mpsc::unbounded_channel();
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(
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TestEventSenderFactory {
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sender,
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worker_id: Default::default(),
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},
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TestEventReceiver { receiver },
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)
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}
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/// Create a [`TestEventWorkerSender`] and [`TestEventReceiver`] pair.The [`TestEventReceiver`]
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/// will be kept alive until the [`TestEventSender`] is dropped.
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pub fn create_single_test_event_channel(
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) -> (TestEventWorkerSender, TestEventReceiver) {
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let (factory, receiver) = create_test_event_channel();
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(factory.worker(), receiver)
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}
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/// Polls for the next [`TestEvent`] from any worker. Events from multiple worker
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/// streams may be interleaved.
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pub struct TestEventReceiver {
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receiver: UnboundedReceiver<(usize, TestEvent)>,
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}
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impl TestEventReceiver {
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/// Receive a single test event, or `None` if no workers are alive.
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pub async fn recv(&mut self) -> Option<(usize, TestEvent)> {
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self.receiver.recv().await
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}
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}
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struct TestStream {
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id: usize,
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read_opt: Option<AsyncPipeRead>,
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sender: UnboundedSender<(usize, TestEvent)>,
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}
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impl TestStream {
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fn new(
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id: usize,
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pipe_reader: PipeRead,
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sender: UnboundedSender<(usize, TestEvent)>,
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) -> std::io::Result<Self> {
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// This may fail if the tokio runtime is shutting down
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let read_opt = Some(pipe_reader.into_async()?);
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Ok(Self {
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id,
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read_opt,
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sender,
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})
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}
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/// Send a buffer to the test event channel. If the channel no longer exists, shut down the stream
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/// because we can't do anything.
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#[must_use = "If this returns false, don't keep reading because we cannot send"]
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fn send(&mut self, buffer: Vec<u8>) -> bool {
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if buffer.is_empty() {
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true
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} else if self
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.sender
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.send((self.id, TestEvent::Output(buffer)))
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.is_err()
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{
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self.read_opt.take();
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false
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} else {
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true
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}
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}
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fn is_alive(&self) -> bool {
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self.read_opt.is_some()
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}
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/// Cancellation-safe.
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#[inline]
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fn pipe(&mut self) -> impl Future<Output = ()> + '_ {
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poll_fn(|cx| self.poll_pipe(cx))
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}
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/// Attempt to read from a given stream, pushing all of the data in it into the given
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/// [`UnboundedSender`] before returning.
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fn poll_pipe(&mut self, cx: &mut std::task::Context) -> Poll<()> {
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let mut buffer = [0_u8; BUFFER_SIZE];
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let mut buf = ReadBuf::new(&mut buffer);
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let res = {
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// No more stream, we shouldn't hit this case.
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let Some(stream) = &mut self.read_opt else {
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unreachable!();
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};
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ready!(Pin::new(&mut *stream).poll_read(cx, &mut buf))
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};
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match res {
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Ok(_) => {
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let buf = buf.filled().to_vec();
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if buf.is_empty() {
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// The buffer may return empty in EOF conditions and never return an error,
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// so we need to treat this as EOF
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self.read_opt.take();
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} else {
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// Attempt to send the buffer, marking as not alive if the channel is closed
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_ = self.send(buf);
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}
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}
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Err(_) => {
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// Stream errored, so just return and mark this stream as not alive.
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_ = self.send(buf.filled().to_vec());
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self.read_opt.take();
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}
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}
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Poll::Ready(())
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}
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/// Read and "block" until the sync markers have been read.
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async fn read_until_sync_marker(&mut self) {
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let Some(file) = &mut self.read_opt else {
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return;
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};
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let mut flush = Vec::with_capacity(BUFFER_SIZE);
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loop {
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let mut buffer = [0_u8; BUFFER_SIZE];
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match file.read(&mut buffer).await {
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Err(_) | Ok(0) => {
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// EOF or error, just return. We make no guarantees about unflushed data at shutdown.
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self.read_opt.take();
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return;
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}
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Ok(read) => {
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flush.extend(&buffer[0..read]);
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// "ends_with" is cheaper, so check that first
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if flush.ends_with(HALF_SYNC_MARKER) {
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// We might have read the full sync marker.
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if flush.ends_with(SYNC_MARKER) {
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flush.truncate(flush.len() - SYNC_MARKER.len());
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} else {
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flush.truncate(flush.len() - HALF_SYNC_MARKER.len());
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}
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// Try to send our flushed buffer. If the channel is closed, this stream will
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// be marked as not alive.
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_ = self.send(flush);
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return;
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}
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// If we don't end with the marker, then we need to search the bytes we read plus four bytes
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// from before. There's still a possibility that the marker could be split because of a pipe
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// buffer that fills up, forcing the flush to be written across two writes and interleaving
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// data between, but that's a risk we take with this sync marker approach.
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let searcher = memmem::TwoWaySearcher::new(HALF_SYNC_MARKER);
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let start =
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(flush.len() - read).saturating_sub(HALF_SYNC_MARKER.len());
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if let Some(offset) = searcher.search_in(&flush[start..]) {
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flush.truncate(offset);
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// Try to send our flushed buffer. If the channel is closed, this stream will
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// be marked as not alive.
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_ = self.send(flush);
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return;
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}
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}
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}
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}
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}
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}
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/// A factory for creating [`TestEventSender`]s. This factory must be dropped
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/// before the [`TestEventReceiver`] will complete.
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pub struct TestEventSenderFactory {
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sender: UnboundedSender<(usize, TestEvent)>,
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worker_id: AtomicUsize,
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}
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impl TestEventSenderFactory {
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/// Create a [`TestEventWorkerSender`], along with a stdout/stderr stream.
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pub fn worker(&self) -> TestEventWorkerSender {
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let id = self.worker_id.fetch_add(1, Ordering::AcqRel);
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let (stdout_reader, stdout_writer) = pipe().unwrap();
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let (stderr_reader, stderr_writer) = pipe().unwrap();
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let (sync_sender, mut sync_receiver) =
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tokio::sync::mpsc::unbounded_channel::<(SendMutex, SendMutex)>();
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let stdout = stdout_writer.try_clone().unwrap();
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let stderr = stderr_writer.try_clone().unwrap();
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let sender = self.sender.clone();
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// Each worker spawns its own output monitoring and serialization task. This task will
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// poll the stdout/stderr streams and interleave that data with `TestEvents` generated
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// by the test runner worker.
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//
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// Note that this _must_ be a separate thread! Flushing requires locking coördination
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// on two threads and if we're blocking-locked on the mutex we've sent down the sync_receiver,
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// there's no way for us to process the actual flush operation here.
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//
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// Creating a mini-runtime to flush the stdout/stderr is the easiest way to do this, but
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// there's no reason we couldn't do it with non-blocking I/O, other than the difficulty
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// of setting up an I/O reactor in Windows.
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std::thread::spawn(move || {
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let runtime = tokio::runtime::Builder::new_current_thread()
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.enable_io()
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.build()
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.unwrap();
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runtime.block_on(tokio::task::unconstrained(async move {
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let mut test_stdout =
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TestStream::new(id, stdout_reader, sender.clone())?;
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let mut test_stderr = TestStream::new(id, stderr_reader, sender)?;
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// This ensures that the stdout and stderr streams in the select! loop below cannot starve each
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// other.
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let mut alternate_stream_priority = false;
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// This function will be woken whenever a stream or the receiver is ready
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loop {
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alternate_stream_priority = !alternate_stream_priority;
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let (a, b) = if alternate_stream_priority {
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(&mut test_stdout, &mut test_stderr)
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} else {
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(&mut test_stderr, &mut test_stdout)
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};
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tokio::select! {
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biased; // We actually want to poll the channel first
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recv = sync_receiver.recv() => {
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match recv {
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// If the channel closed, we assume that all important data from the streams was synced,
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// so we just end this task immediately.
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None => { break },
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Some((mutex1, mutex2)) => {
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// Two phase lock: mutex1 indicates that we are done our general read phase and are ready for
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// the sync phase. mutex2 indicates that we have completed the sync phase. This prevents deadlock
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// when the pipe is too full to accept the sync marker.
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drop(mutex1);
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for stream in [&mut test_stdout, &mut test_stderr] {
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if stream.is_alive() {
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stream.read_until_sync_marker().await;
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}
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}
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drop(mutex2);
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}
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}
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}
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// Poll stdout first if `alternate_stream_priority` is true, otherwise poll stderr first.
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// This is necessary because of the `biased` flag above to avoid starvation.
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_ = a.pipe(), if a.is_alive() => {},
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_ = b.pipe(), if b.is_alive() => {},
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}
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}
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Ok::<_, std::io::Error>(())
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}))?;
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Ok::<_, std::io::Error>(())
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});
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let sender = TestEventSender {
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id,
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sender: self.sender.clone(),
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sync_sender,
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stdout_writer,
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stderr_writer,
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};
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TestEventWorkerSender {
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sender,
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stdout,
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stderr,
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}
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}
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/// A [`TestEventWeakSender`] has a unique ID, but will not keep the [`TestEventReceiver`] alive.
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/// This may be useful to add a `SIGINT` or other break handler to tests that isn't part of a
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/// specific test, but handles the overall orchestration of running tests:
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///
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/// ```nocompile
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/// let mut cancel_sender = test_event_sender_factory.weak_sender();
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/// let sigint_handler_handle = spawn(async move {
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/// signal::ctrl_c().await.unwrap();
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/// cancel_sender.send(TestEvent::Sigint).ok();
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/// });
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/// ```
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pub fn weak_sender(&self) -> TestEventWeakSender {
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TestEventWeakSender {
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id: self.worker_id.fetch_add(1, Ordering::AcqRel),
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sender: self.sender.downgrade(),
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}
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}
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}
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pub struct TestEventWeakSender {
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pub id: usize,
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sender: WeakUnboundedSender<(usize, TestEvent)>,
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}
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impl TestEventWeakSender {
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pub fn send(&mut self, message: TestEvent) -> Result<(), ChannelClosedError> {
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Ok(
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self
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.sender
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.upgrade()
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.ok_or(ChannelClosedError)?
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.send((self.id, message))?,
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)
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}
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}
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pub struct TestEventWorkerSender {
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pub sender: TestEventSender,
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pub stdout: PipeWrite,
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pub stderr: PipeWrite,
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}
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/// Sends messages from a given worker into the test stream. If multiple clones of
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/// this sender are kept alive, the worker is kept alive.
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///
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/// Any unflushed bytes in the stdout or stderr stream associated with this sender
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/// are not guaranteed to be sent on drop unless flush is explicitly called.
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pub struct TestEventSender {
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pub id: usize,
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sender: UnboundedSender<(usize, TestEvent)>,
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sync_sender: UnboundedSender<(SendMutex, SendMutex)>,
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stdout_writer: PipeWrite,
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stderr_writer: PipeWrite,
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}
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impl TestEventSender {
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pub fn send(&mut self, message: TestEvent) -> Result<(), ChannelClosedError> {
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// Certain messages require us to ensure that all output has been drained to ensure proper
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// interleaving of messages.
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if message.requires_stdio_sync() {
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self.flush()?;
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}
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Ok(self.sender.send((self.id, message))?)
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}
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/// Ensure that all output has been fully flushed by writing a sync marker into the
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/// stdout and stderr streams and waiting for it on the other side.
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pub fn flush(&mut self) -> Result<(), ChannelClosedError> {
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// Two phase lock: mutex1 indicates that we are done our general read phase and are ready for
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// the sync phase. mutex2 indicates that we have completed the sync phase. This prevents deadlock
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// when the pipe is too full to accept the sync marker.
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let mutex1 = parking_lot::RawMutex::INIT;
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mutex1.lock();
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let mutex2 = parking_lot::RawMutex::INIT;
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mutex2.lock();
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self
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.sync_sender
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.send((SendMutex(&mutex1 as _), SendMutex(&mutex2 as _)))?;
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if !mutex1.try_lock_for(Duration::from_secs(30)) {
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panic!(
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"Test flush deadlock 1, sender closed = {}",
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self.sync_sender.is_closed()
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);
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}
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_ = self.stdout_writer.write_all(SYNC_MARKER);
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_ = self.stderr_writer.write_all(SYNC_MARKER);
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if !mutex2.try_lock_for(Duration::from_secs(30)) {
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panic!(
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"Test flush deadlock 2, sender closed = {}",
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self.sync_sender.is_closed()
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);
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}
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Ok(())
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}
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}
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#[allow(clippy::print_stdout)]
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#[allow(clippy::print_stderr)]
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#[cfg(test)]
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mod tests {
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use super::*;
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use crate::tools::test::TestResult;
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use deno_core::unsync::spawn;
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use deno_core::unsync::spawn_blocking;
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|
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/// Test that output is correctly interleaved with messages.
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#[tokio::test]
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async fn spawn_worker() {
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test_util::timeout!(60);
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let (mut worker, mut receiver) = create_single_test_event_channel();
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let recv_handle = spawn(async move {
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let mut queue = vec![];
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while let Some((_, message)) = receiver.recv().await {
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let msg_str = format!("{message:?}");
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if msg_str.len() > 50 {
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eprintln!("message = {}...", &msg_str[..50]);
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} else {
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eprintln!("message = {}", msg_str);
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}
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queue.push(message);
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}
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eprintln!("done");
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queue
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});
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let send_handle = spawn_blocking(move || {
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worker.stdout.write_all(&[1; 100_000]).unwrap();
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eprintln!("Wrote bytes");
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worker.sender.send(TestEvent::StepWait(1)).unwrap();
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eprintln!("Sent");
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worker.stdout.write_all(&[2; 100_000]).unwrap();
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eprintln!("Wrote bytes 2");
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worker.sender.flush().unwrap();
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eprintln!("Done");
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});
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send_handle.await.unwrap();
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let messages = recv_handle.await.unwrap();
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let mut expected = 1;
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let mut count = 0;
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for message in messages {
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match message {
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TestEvent::Output(vec) => {
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assert_eq!(vec[0], expected);
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count += vec.len();
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}
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TestEvent::StepWait(_) => {
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assert_eq!(count, 100_000);
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count = 0;
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expected = 2;
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}
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_ => unreachable!(),
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}
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}
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assert_eq!(expected, 2);
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assert_eq!(count, 100_000);
|
|
}
|
|
|
|
/// Test that flushing a large number of times doesn't hang.
|
|
#[tokio::test]
|
|
async fn test_flush_lots() {
|
|
test_util::timeout!(240);
|
|
let (mut worker, mut receiver) = create_single_test_event_channel();
|
|
let recv_handle = spawn(async move {
|
|
let mut queue = vec![];
|
|
while let Some((_, message)) = receiver.recv().await {
|
|
assert!(!matches!(message, TestEvent::Output(..)));
|
|
queue.push(message);
|
|
}
|
|
eprintln!("Receiver closed");
|
|
queue
|
|
});
|
|
let send_handle = spawn_blocking(move || {
|
|
for _ in 0..100000 {
|
|
worker.sender.send(TestEvent::StepWait(1)).unwrap();
|
|
}
|
|
eprintln!("Sent all messages");
|
|
});
|
|
send_handle.await.unwrap();
|
|
let messages = recv_handle.await.unwrap();
|
|
assert_eq!(messages.len(), 100000);
|
|
}
|
|
|
|
/// Test that flushing a large number of times doesn't hang.
|
|
#[tokio::test]
|
|
async fn test_flush_large() {
|
|
test_util::timeout!(240);
|
|
let (mut worker, mut receiver) = create_single_test_event_channel();
|
|
let recv_handle = spawn(async move {
|
|
let mut queue = vec![];
|
|
while let Some((_, message)) = receiver.recv().await {
|
|
if let TestEvent::StepWait(..) = message {
|
|
queue.push(());
|
|
}
|
|
}
|
|
eprintln!("Receiver closed");
|
|
queue
|
|
});
|
|
let send_handle = spawn_blocking(move || {
|
|
for _ in 0..25000 {
|
|
// Write one pipe buffer's worth of message here. We try a few different sizes of potentially
|
|
// blocking writes.
|
|
worker.stderr.write_all(&[0; 4 * 1024]).unwrap();
|
|
worker.sender.send(TestEvent::StepWait(1)).unwrap();
|
|
worker.stderr.write_all(&[0; 16 * 1024]).unwrap();
|
|
worker.sender.send(TestEvent::StepWait(1)).unwrap();
|
|
worker.stderr.write_all(&[0; 64 * 1024]).unwrap();
|
|
worker.sender.send(TestEvent::StepWait(1)).unwrap();
|
|
worker.stderr.write_all(&[0; 128 * 1024]).unwrap();
|
|
worker.sender.send(TestEvent::StepWait(1)).unwrap();
|
|
}
|
|
eprintln!("Sent all messages");
|
|
});
|
|
send_handle.await.unwrap();
|
|
let messages = recv_handle.await.unwrap();
|
|
assert_eq!(messages.len(), 100000);
|
|
}
|
|
|
|
/// Test that flushing a large number of times doesn't hang.
|
|
#[tokio::test]
|
|
async fn test_flush_with_close() {
|
|
test_util::timeout!(240);
|
|
let (worker, mut receiver) = create_single_test_event_channel();
|
|
let TestEventWorkerSender {
|
|
mut sender,
|
|
stderr,
|
|
stdout,
|
|
} = worker;
|
|
let recv_handle = spawn(async move {
|
|
let mut queue = vec![];
|
|
while let Some((_, _)) = receiver.recv().await {
|
|
queue.push(());
|
|
}
|
|
eprintln!("Receiver closed");
|
|
queue
|
|
});
|
|
let send_handle = spawn_blocking(move || {
|
|
let mut stdout = Some(stdout);
|
|
let mut stderr = Some(stderr);
|
|
for i in 0..100000 {
|
|
if i == 20000 {
|
|
stdout.take();
|
|
}
|
|
if i == 40000 {
|
|
stderr.take();
|
|
}
|
|
if i % 2 == 0 {
|
|
if let Some(stdout) = &mut stdout {
|
|
stdout.write_all(b"message").unwrap();
|
|
}
|
|
} else if let Some(stderr) = &mut stderr {
|
|
stderr.write_all(b"message").unwrap();
|
|
}
|
|
sender.send(TestEvent::StepWait(1)).unwrap();
|
|
}
|
|
eprintln!("Sent all messages");
|
|
});
|
|
send_handle.await.unwrap();
|
|
let messages = recv_handle.await.unwrap();
|
|
assert_eq!(messages.len(), 130000);
|
|
}
|
|
|
|
/// Test that large numbers of interleaved steps are routed properly.
|
|
#[tokio::test]
|
|
async fn test_interleave() {
|
|
test_util::timeout!(60);
|
|
const MESSAGE_COUNT: usize = 10_000;
|
|
let (mut worker, mut receiver) = create_single_test_event_channel();
|
|
let recv_handle = spawn(async move {
|
|
let mut i = 0;
|
|
while let Some((_, message)) = receiver.recv().await {
|
|
if i % 2 == 0 {
|
|
let expected_text = format!("{:08x}", i / 2).into_bytes();
|
|
let TestEvent::Output(text) = message else {
|
|
panic!("Incorrect message: {message:?}");
|
|
};
|
|
assert_eq!(text, expected_text);
|
|
} else {
|
|
let TestEvent::Result(index, TestResult::Ok, 0) = message else {
|
|
panic!("Incorrect message: {message:?}");
|
|
};
|
|
assert_eq!(index, i / 2);
|
|
}
|
|
i += 1;
|
|
}
|
|
eprintln!("Receiver closed");
|
|
i
|
|
});
|
|
let send_handle: deno_core::unsync::JoinHandle<()> =
|
|
spawn_blocking(move || {
|
|
for i in 0..MESSAGE_COUNT {
|
|
worker
|
|
.stderr
|
|
.write_all(format!("{i:08x}").as_str().as_bytes())
|
|
.unwrap();
|
|
worker
|
|
.sender
|
|
.send(TestEvent::Result(i, TestResult::Ok, 0))
|
|
.unwrap();
|
|
}
|
|
eprintln!("Sent all messages");
|
|
});
|
|
send_handle.await.unwrap();
|
|
let messages = recv_handle.await.unwrap();
|
|
assert_eq!(messages, MESSAGE_COUNT * 2);
|
|
}
|
|
|
|
#[tokio::test]
|
|
async fn test_sender_shutdown_before_receive() {
|
|
test_util::timeout!(60);
|
|
for _ in 0..10 {
|
|
let (mut worker, mut receiver) = create_single_test_event_channel();
|
|
worker.stderr.write_all(b"hello").unwrap();
|
|
worker
|
|
.sender
|
|
.send(TestEvent::Result(0, TestResult::Ok, 0))
|
|
.unwrap();
|
|
drop(worker);
|
|
let (_, message) = receiver.recv().await.unwrap();
|
|
let TestEvent::Output(text) = message else {
|
|
panic!("Incorrect message: {message:?}");
|
|
};
|
|
assert_eq!(text.as_slice(), b"hello");
|
|
let (_, message) = receiver.recv().await.unwrap();
|
|
let TestEvent::Result(..) = message else {
|
|
panic!("Incorrect message: {message:?}");
|
|
};
|
|
assert!(receiver.recv().await.is_none());
|
|
}
|
|
}
|
|
|
|
/// Ensure nothing panics if we're racing the runtime shutdown.
|
|
#[test]
|
|
fn test_runtime_shutdown() {
|
|
test_util::timeout!(60);
|
|
let runtime = tokio::runtime::Builder::new_current_thread()
|
|
.enable_all()
|
|
.build()
|
|
.unwrap();
|
|
runtime.block_on(async {
|
|
let (mut worker, mut receiver) = create_single_test_event_channel();
|
|
tokio::task::spawn(async move {
|
|
loop {
|
|
if receiver.recv().await.is_none() {
|
|
break;
|
|
}
|
|
}
|
|
});
|
|
tokio::task::spawn(async move {
|
|
_ = worker.sender.send(TestEvent::Sigint);
|
|
});
|
|
});
|
|
}
|
|
}
|