// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use bytes::BytesMut; use deno_core::error::type_error; use deno_core::error::AnyError; use deno_core::external; use deno_core::op2; use deno_core::serde_v8::V8Slice; use deno_core::unsync::TaskQueue; use deno_core::AsyncResult; use deno_core::BufView; use deno_core::CancelFuture; use deno_core::CancelHandle; use deno_core::ExternalPointer; use deno_core::JsBuffer; use deno_core::OpState; use deno_core::RcLike; use deno_core::RcRef; use deno_core::Resource; use deno_core::ResourceId; use futures::future::poll_fn; use std::borrow::Cow; use std::cell::RefCell; use std::cell::RefMut; use std::ffi::c_void; use std::future::Future; use std::marker::PhantomData; use std::mem::MaybeUninit; use std::pin::Pin; use std::rc::Rc; use std::task::Context; use std::task::Poll; use std::task::Waker; // How many buffers we'll allow in the channel before we stop allowing writes. const BUFFER_CHANNEL_SIZE: u16 = 1024; // How much data is in the channel before we stop allowing writes. const BUFFER_BACKPRESSURE_LIMIT: usize = 64 * 1024; // Optimization: prevent multiple small writes from adding overhead. // // If the total size of the channel is less than this value and there is more than one buffer available // to read, we will allocate a buffer to store the entire contents of the channel and copy each value from // the channel rather than yielding them one at a time. const BUFFER_AGGREGATION_LIMIT: usize = 1024; struct BoundedBufferChannelInner { buffers: [MaybeUninit>; BUFFER_CHANNEL_SIZE as _], ring_producer: u16, ring_consumer: u16, error: Option, current_size: usize, // TODO(mmastrac): we can math this field instead of accounting for it len: usize, closed: bool, read_waker: Option, write_waker: Option, _unsend: PhantomData>, } impl Default for BoundedBufferChannelInner { fn default() -> Self { Self::new() } } impl std::fmt::Debug for BoundedBufferChannelInner { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { f.write_fmt(format_args!( "[BoundedBufferChannel closed={} error={:?} ring={}->{} len={} size={}]", self.closed, self.error, self.ring_producer, self.ring_consumer, self.len, self.current_size )) } } impl BoundedBufferChannelInner { pub fn new() -> Self { const UNINIT: MaybeUninit> = MaybeUninit::uninit(); Self { buffers: [UNINIT; BUFFER_CHANNEL_SIZE as _], ring_producer: 0, ring_consumer: 0, len: 0, closed: false, error: None, current_size: 0, read_waker: None, write_waker: None, _unsend: PhantomData, } } /// # Safety /// /// This doesn't check whether `ring_consumer` is valid, so you'd better make sure it is before /// calling this. #[inline(always)] unsafe fn next_unsafe(&mut self) -> &mut V8Slice { self .buffers .get_unchecked_mut(self.ring_consumer as usize) .assume_init_mut() } /// # Safety /// /// This doesn't check whether `ring_consumer` is valid, so you'd better make sure it is before /// calling this. #[inline(always)] unsafe fn take_next_unsafe(&mut self) -> V8Slice { let res = std::ptr::read(self.next_unsafe()); self.ring_consumer = (self.ring_consumer + 1) % BUFFER_CHANNEL_SIZE; res } fn drain(&mut self, mut f: impl FnMut(V8Slice)) { while self.ring_producer != self.ring_consumer { // SAFETY: We know the ring indexes are valid let res = unsafe { std::ptr::read(self.next_unsafe()) }; self.ring_consumer = (self.ring_consumer + 1) % BUFFER_CHANNEL_SIZE; f(res); } self.current_size = 0; self.ring_producer = 0; self.ring_consumer = 0; self.len = 0; } pub fn read(&mut self, limit: usize) -> Result, AnyError> { // Empty buffers will return the error, if one exists, or None if self.len == 0 { if let Some(error) = self.error.take() { return Err(error); } else { return Ok(None); } } // If we have less than the aggregation limit AND we have more than one buffer in the channel, // aggregate and return everything in a single buffer. if limit >= BUFFER_AGGREGATION_LIMIT && self.current_size <= BUFFER_AGGREGATION_LIMIT && self.len > 1 { let mut bytes = BytesMut::with_capacity(BUFFER_AGGREGATION_LIMIT); self.drain(|slice| { bytes.extend_from_slice(slice.as_ref()); }); // We can always write again if let Some(waker) = self.write_waker.take() { waker.wake(); } return Ok(Some(BufView::from(bytes.freeze()))); } // SAFETY: We know this exists let buf = unsafe { self.next_unsafe() }; let buf = if buf.len() <= limit { self.current_size -= buf.len(); self.len -= 1; // SAFETY: We know this exists unsafe { self.take_next_unsafe() } } else { let buf = buf.split_to(limit); self.current_size -= limit; buf }; // If current_size is zero, len must be zero (and if not, len must not be) debug_assert!( !((self.current_size == 0) ^ (self.len == 0)), "Length accounting mismatch: {self:?}" ); if self.write_waker.is_some() { // We may be able to write again if we have buffer and byte room in the channel if self.can_write() { if let Some(waker) = self.write_waker.take() { waker.wake(); } } } Ok(Some(BufView::from(JsBuffer::from_parts(buf)))) } pub fn write(&mut self, buffer: V8Slice) -> Result<(), V8Slice> { let next_producer_index = (self.ring_producer + 1) % BUFFER_CHANNEL_SIZE; if next_producer_index == self.ring_consumer { // Note that we may have been allowed to write because of a close/error condition, but the // underlying channel is actually closed. If this is the case, we return `Ok(())`` and just // drop the bytes on the floor. return if self.closed || self.error.is_some() { Ok(()) } else { Err(buffer) }; } self.current_size += buffer.len(); // SAFETY: we know the ringbuffer bounds are correct unsafe { *self.buffers.get_unchecked_mut(self.ring_producer as usize) = MaybeUninit::new(buffer) }; self.ring_producer = next_producer_index; self.len += 1; debug_assert!(self.ring_producer != self.ring_consumer); if let Some(waker) = self.read_waker.take() { waker.wake(); } Ok(()) } pub fn write_error(&mut self, error: AnyError) { self.error = Some(error); if let Some(waker) = self.read_waker.take() { waker.wake(); } } #[inline(always)] pub fn can_read(&self) -> bool { // Read will return if: // - the stream is closed // - there is an error // - the stream is not empty self.closed || self.error.is_some() || self.ring_consumer != self.ring_producer } #[inline(always)] pub fn can_write(&self) -> bool { // Write will return if: // - the stream is closed // - there is an error // - the stream is not full (either buffer or byte count) let next_producer_index = (self.ring_producer + 1) % BUFFER_CHANNEL_SIZE; self.closed || self.error.is_some() || (next_producer_index != self.ring_consumer && self.current_size < BUFFER_BACKPRESSURE_LIMIT) } pub fn poll_read_ready(&mut self, cx: &mut Context) -> Poll<()> { if !self.can_read() { self.read_waker = Some(cx.waker().clone()); Poll::Pending } else { self.read_waker.take(); Poll::Ready(()) } } pub fn poll_write_ready(&mut self, cx: &mut Context) -> Poll<()> { if !self.can_write() { self.write_waker = Some(cx.waker().clone()); Poll::Pending } else { self.write_waker.take(); Poll::Ready(()) } } pub fn close(&mut self) { self.closed = true; // Wake up reads and writes, since they'll both be able to proceed forever now if let Some(waker) = self.write_waker.take() { waker.wake(); } if let Some(waker) = self.read_waker.take() { waker.wake(); } } } #[repr(transparent)] #[derive(Clone, Default)] struct BoundedBufferChannel { inner: Rc>, } impl BoundedBufferChannel { // TODO(mmastrac): in release mode we should be able to make this an UnsafeCell #[inline(always)] fn inner(&self) -> RefMut { self.inner.borrow_mut() } pub fn read(&self, limit: usize) -> Result, AnyError> { self.inner().read(limit) } pub fn write(&self, buffer: V8Slice) -> Result<(), V8Slice> { self.inner().write(buffer) } pub fn write_error(&self, error: AnyError) { self.inner().write_error(error) } pub fn can_write(&self) -> bool { self.inner().can_write() } pub fn poll_read_ready(&self, cx: &mut Context) -> Poll<()> { self.inner().poll_read_ready(cx) } pub fn poll_write_ready(&self, cx: &mut Context) -> Poll<()> { self.inner().poll_write_ready(cx) } pub fn closed(&self) -> bool { self.inner().closed } #[cfg(test)] pub fn byte_size(&self) -> usize { self.inner().current_size } pub fn close(&self) { self.inner().close() } } #[allow(clippy::type_complexity)] struct ReadableStreamResource { read_queue: Rc, channel: BoundedBufferChannel, cancel_handle: CancelHandle, data: ReadableStreamResourceData, size_hint: (u64, Option), } impl ReadableStreamResource { pub fn cancel_handle(self: &Rc) -> impl RcLike { RcRef::map(self, |s| &s.cancel_handle).clone() } async fn read(self: Rc, limit: usize) -> Result { let cancel_handle = self.cancel_handle(); // Serialize all the reads using a task queue. let _read_permit = self.read_queue.acquire().await; poll_fn(|cx| self.channel.poll_read_ready(cx)) .or_cancel(cancel_handle) .await?; self .channel .read(limit) .map(|buf| buf.unwrap_or_else(BufView::empty)) } fn close_channel(&self) { // Trigger the promise in JS to cancel the stream if necessarily self.data.completion.complete(true); // Cancel any outstanding read requests self.cancel_handle.cancel(); // Close the channel to wake up anyone waiting self.channel.close(); } } impl Resource for ReadableStreamResource { fn name(&self) -> Cow { Cow::Borrowed("readableStream") } fn read(self: Rc, limit: usize) -> AsyncResult { Box::pin(ReadableStreamResource::read(self, limit)) } fn close(self: Rc) { self.close_channel(); } fn size_hint(&self) -> (u64, Option) { self.size_hint } } impl Drop for ReadableStreamResource { fn drop(&mut self) { self.close_channel(); } } // TODO(mmastrac): Move this to deno_core #[derive(Clone, Debug, Default)] pub struct CompletionHandle { inner: Rc>, } #[derive(Debug, Default)] struct CompletionHandleInner { complete: bool, success: bool, waker: Option, } impl CompletionHandle { pub fn complete(&self, success: bool) { let mut mut_self = self.inner.borrow_mut(); mut_self.complete = true; mut_self.success = success; if let Some(waker) = mut_self.waker.take() { drop(mut_self); waker.wake(); } } } impl Future for CompletionHandle { type Output = bool; fn poll( self: Pin<&mut Self>, cx: &mut std::task::Context<'_>, ) -> std::task::Poll { let mut mut_self = self.inner.borrow_mut(); if mut_self.complete { return std::task::Poll::Ready(mut_self.success); } mut_self.waker = Some(cx.waker().clone()); std::task::Poll::Pending } } /// Allocate a resource that wraps a ReadableStream. #[op2(fast)] #[smi] pub fn op_readable_stream_resource_allocate(state: &mut OpState) -> ResourceId { let completion = CompletionHandle::default(); let resource = ReadableStreamResource { read_queue: Default::default(), cancel_handle: Default::default(), channel: BoundedBufferChannel::default(), data: ReadableStreamResourceData { completion }, size_hint: (0, None), }; state.resource_table.add(resource) } /// Allocate a resource that wraps a ReadableStream, with a size hint. #[op2(fast)] #[smi] pub fn op_readable_stream_resource_allocate_sized( state: &mut OpState, #[number] length: u64, ) -> ResourceId { let completion = CompletionHandle::default(); let resource = ReadableStreamResource { read_queue: Default::default(), cancel_handle: Default::default(), channel: BoundedBufferChannel::default(), data: ReadableStreamResourceData { completion }, size_hint: (length, Some(length)), }; state.resource_table.add(resource) } #[op2(fast)] pub fn op_readable_stream_resource_get_sink( state: &mut OpState, #[smi] rid: ResourceId, ) -> *const c_void { let Ok(resource) = state.resource_table.get::(rid) else { return std::ptr::null(); }; ExternalPointer::new(resource.channel.clone()).into_raw() } external!(BoundedBufferChannel, "stream resource channel"); fn get_sender(sender: *const c_void) -> BoundedBufferChannel { // SAFETY: We know this is a valid v8::External unsafe { ExternalPointer::::from_raw(sender) .unsafely_deref() .clone() } } fn drop_sender(sender: *const c_void) { // SAFETY: We know this is a valid v8::External unsafe { ExternalPointer::::from_raw(sender).unsafely_take(); } } #[op2(async)] pub fn op_readable_stream_resource_write_buf( sender: *const c_void, #[buffer] buffer: JsBuffer, ) -> impl Future { let sender = get_sender(sender); async move { poll_fn(|cx| sender.poll_write_ready(cx)).await; sender.write(buffer.into_parts()).unwrap(); !sender.closed() } } /// Write to the channel synchronously, returning 0 if the channel was closed, 1 if we wrote /// successfully, 2 if the channel was full and we need to block. #[op2] pub fn op_readable_stream_resource_write_sync( sender: *const c_void, #[buffer] buffer: JsBuffer, ) -> u32 { let sender = get_sender(sender); if sender.can_write() { if sender.closed() { 0 } else { sender.write(buffer.into_parts()).unwrap(); 1 } } else { 2 } } #[op2(fast)] pub fn op_readable_stream_resource_write_error( sender: *const c_void, #[string] error: String, ) -> bool { let sender = get_sender(sender); // We can always write an error, no polling required sender.write_error(type_error(Cow::Owned(error))); !sender.closed() } #[op2(fast)] #[smi] pub fn op_readable_stream_resource_close(sender: *const c_void) { get_sender(sender).close(); drop_sender(sender); } #[op2(async)] pub fn op_readable_stream_resource_await_close( state: &mut OpState, #[smi] rid: ResourceId, ) -> impl Future { let completion = state .resource_table .get::(rid) .ok() .map(|r| r.data.completion.clone()); async move { if let Some(completion) = completion { completion.await; } } } struct ReadableStreamResourceData { completion: CompletionHandle, } impl Drop for ReadableStreamResourceData { fn drop(&mut self) { self.completion.complete(true); } } #[cfg(test)] mod tests { use super::*; use deno_core::v8; use std::cell::OnceCell; use std::sync::atomic::AtomicUsize; use std::sync::OnceLock; use std::time::Duration; static V8_GLOBAL: OnceLock<()> = OnceLock::new(); thread_local! { static ISOLATE: OnceCell> = const { OnceCell::new() }; } fn with_isolate(mut f: impl FnMut(&mut v8::Isolate) -> T) -> T { V8_GLOBAL.get_or_init(|| { let platform = v8::new_unprotected_default_platform(0, false).make_shared(); v8::V8::initialize_platform(platform); v8::V8::initialize(); }); ISOLATE.with(|cell| { let mut isolate = cell .get_or_init(|| { std::sync::Mutex::new(v8::Isolate::new(Default::default())) }) .try_lock() .unwrap(); f(&mut isolate) }) } fn create_buffer(byte_length: usize) -> V8Slice { with_isolate(|isolate| { let ptr = v8::ArrayBuffer::new_backing_store(isolate, byte_length); // SAFETY: we just made this unsafe { V8Slice::from_parts(ptr.into(), 0..byte_length) } }) } #[test] fn test_bounded_buffer_channel() { let channel = BoundedBufferChannel::default(); for _ in 0..BUFFER_CHANNEL_SIZE - 1 { channel.write(create_buffer(1024)).unwrap(); } } #[tokio::test(flavor = "current_thread")] async fn test_multi_task() { let channel = BoundedBufferChannel::default(); let channel_send = channel.clone(); // Fast writer let a = deno_core::unsync::spawn(async move { for _ in 0..BUFFER_CHANNEL_SIZE * 2 { poll_fn(|cx| channel_send.poll_write_ready(cx)).await; channel_send .write(create_buffer(BUFFER_AGGREGATION_LIMIT)) .unwrap(); } }); // Slightly slower reader let b = deno_core::unsync::spawn(async move { for _ in 0..BUFFER_CHANNEL_SIZE * 2 { if cfg!(windows) { // windows has ~15ms resolution on sleep, so just yield so // this test doesn't take 30 seconds to run tokio::task::yield_now().await; } else { tokio::time::sleep(Duration::from_millis(1)).await; } poll_fn(|cx| channel.poll_read_ready(cx)).await; channel.read(BUFFER_AGGREGATION_LIMIT).unwrap(); } }); a.await.unwrap(); b.await.unwrap(); } #[tokio::test(flavor = "current_thread")] async fn test_multi_task_small_reads() { let channel = BoundedBufferChannel::default(); let channel_send = channel.clone(); let total_send = Rc::new(AtomicUsize::new(0)); let total_send_task = total_send.clone(); let total_recv = Rc::new(AtomicUsize::new(0)); let total_recv_task = total_recv.clone(); // Fast writer let a = deno_core::unsync::spawn(async move { for _ in 0..BUFFER_CHANNEL_SIZE * 2 { poll_fn(|cx| channel_send.poll_write_ready(cx)).await; channel_send.write(create_buffer(16)).unwrap(); total_send_task.fetch_add(16, std::sync::atomic::Ordering::SeqCst); } // We need to close because we may get aggregated packets and we want a signal channel_send.close(); }); // Slightly slower reader let b = deno_core::unsync::spawn(async move { for _ in 0..BUFFER_CHANNEL_SIZE * 2 { poll_fn(|cx| channel.poll_read_ready(cx)).await; // We want to make sure we're aggregating at least some packets while channel.byte_size() <= 16 && !channel.closed() { tokio::time::sleep(Duration::from_millis(1)).await; } let len = channel .read(1024) .unwrap() .map(|b| b.len()) .unwrap_or_default(); total_recv_task.fetch_add(len, std::sync::atomic::Ordering::SeqCst); } }); a.await.unwrap(); b.await.unwrap(); assert_eq!( total_send.load(std::sync::atomic::Ordering::SeqCst), total_recv.load(std::sync::atomic::Ordering::SeqCst) ); } }