x86_64/usr/lib/rustlib/src/rust/library/std/src/sync/mpmc/array.rs - manifest_repos/toolchain - Git at Google

 //! Bounded channel based on a preallocated array.
 //!
 //! This flavor has a fixed, positive capacity.
 //!
 //! The implementation is based on Dmitry Vyukov's bounded MPMC queue.
 //!
 //! Source:
 //!   - <http://www.1024cores.net/home/lock-free-algorithms/queues/bounded-mpmc-queue>
 //!   - <https://docs.google.com/document/d/1yIAYmbvL3JxOKOjuCyon7JhW4cSv1wy5hC0ApeGMV9s/pub>

 use super::context::Context;
 use super::error::*;
 use super::select::{Operation, Selected, Token};
 use super::utils::{Backoff, CachePadded};
 use super::waker::SyncWaker;

 use crate::cell::UnsafeCell;
 use crate::mem::MaybeUninit;
 use crate::ptr;
 use crate::sync::atomic::{self, AtomicUsize, Ordering};
 use crate::time::Instant;

 /// A slot in a channel.
 struct Slot<T> {
     /// The current stamp.
     stamp: AtomicUsize,

     /// The message in this slot.
     msg: UnsafeCell<MaybeUninit<T>>,
 }

 /// The token type for the array flavor.
 #[derive(Debug)]
 pub(crate) struct ArrayToken {
     /// Slot to read from or write to.
     slot: *const u8,

     /// Stamp to store into the slot after reading or writing.
     stamp: usize,
 }

 impl Default for ArrayToken {
     #[inline]
     fn default() -> Self {
         ArrayToken { slot: ptr::null(), stamp: 0 }
     }
 }

 /// Bounded channel based on a preallocated array.
 pub(crate) struct Channel<T> {
     /// The head of the channel.
     ///
     /// This value is a "stamp" consisting of an index into the buffer, a mark bit, and a lap, but
     /// packed into a single `usize`. The lower bits represent the index, while the upper bits
     /// represent the lap. The mark bit in the head is always zero.
     ///
     /// Messages are popped from the head of the channel.
     head: CachePadded<AtomicUsize>,

     /// The tail of the channel.
     ///
     /// This value is a "stamp" consisting of an index into the buffer, a mark bit, and a lap, but
     /// packed into a single `usize`. The lower bits represent the index, while the upper bits
     /// represent the lap. The mark bit indicates that the channel is disconnected.
     ///
     /// Messages are pushed into the tail of the channel.
     tail: CachePadded<AtomicUsize>,

     /// The buffer holding slots.
     buffer: Box<[Slot<T>]>,

     /// The channel capacity.
     cap: usize,

     /// A stamp with the value of `{ lap: 1, mark: 0, index: 0 }`.
     one_lap: usize,

     /// If this bit is set in the tail, that means the channel is disconnected.
     mark_bit: usize,

     /// Senders waiting while the channel is full.
     senders: SyncWaker,

     /// Receivers waiting while the channel is empty and not disconnected.
     receivers: SyncWaker,
 }

 impl<T> Channel<T> {
     /// Creates a bounded channel of capacity `cap`.
     pub(crate) fn with_capacity(cap: usize) -> Self {
         assert!(cap > 0, "capacity must be positive");

         // Compute constants `mark_bit` and `one_lap`.
         let mark_bit = (cap + 1).next_power_of_two();
         let one_lap = mark_bit * 2;

         // Head is initialized to `{ lap: 0, mark: 0, index: 0 }`.
         let head = 0;
         // Tail is initialized to `{ lap: 0, mark: 0, index: 0 }`.
         let tail = 0;

         // Allocate a buffer of `cap` slots initialized
         // with stamps.
         let buffer: Box<[Slot<T>]> = (0..cap)
             .map(|i| {
                 // Set the stamp to `{ lap: 0, mark: 0, index: i }`.
                 Slot { stamp: AtomicUsize::new(i), msg: UnsafeCell::new(MaybeUninit::uninit()) }
             })
             .collect();

         Channel {
             buffer,
             cap,
             one_lap,
             mark_bit,
             head: CachePadded::new(AtomicUsize::new(head)),
             tail: CachePadded::new(AtomicUsize::new(tail)),
             senders: SyncWaker::new(),
             receivers: SyncWaker::new(),
         }
     }

     /// Attempts to reserve a slot for sending a message.
     fn start_send(&self, token: &mut Token) -> bool {
         let backoff = Backoff::new();
         let mut tail = self.tail.load(Ordering::Relaxed);

         loop {
             // Check if the channel is disconnected.
             if tail & self.mark_bit != 0 {
                 token.array.slot = ptr::null();
                 token.array.stamp = 0;
                 return true;
             }

             // Deconstruct the tail.
             let index = tail & (self.mark_bit - 1);
             let lap = tail & !(self.one_lap - 1);

             // Inspect the corresponding slot.
             debug_assert!(index < self.buffer.len());
             let slot = unsafe { self.buffer.get_unchecked(index) };
             let stamp = slot.stamp.load(Ordering::Acquire);

             // If the tail and the stamp match, we may attempt to push.
             if tail == stamp {
                 let new_tail = if index + 1 < self.cap {
                     // Same lap, incremented index.
                     // Set to `{ lap: lap, mark: 0, index: index + 1 }`.
                     tail + 1
                 } else {
                     // One lap forward, index wraps around to zero.
                     // Set to `{ lap: lap.wrapping_add(1), mark: 0, index: 0 }`.
                     lap.wrapping_add(self.one_lap)
                 };

                 // Try moving the tail.
                 match self.tail.compare_exchange_weak(
                     tail,
                     new_tail,
                     Ordering::SeqCst,
                     Ordering::Relaxed,
                 ) {
                     Ok(_) => {
                         // Prepare the token for the follow-up call to `write`.
                         token.array.slot = slot as *const Slot<T> as *const u8;
                         token.array.stamp = tail + 1;
                         return true;
                     }
                     Err(_) => {
                         backoff.spin_light();
                         tail = self.tail.load(Ordering::Relaxed);
                     }
                 }
             } else if stamp.wrapping_add(self.one_lap) == tail + 1 {
                 atomic::fence(Ordering::SeqCst);
                 let head = self.head.load(Ordering::Relaxed);

                 // If the head lags one lap behind the tail as well...
                 if head.wrapping_add(self.one_lap) == tail {
                     // ...then the channel is full.
                     return false;
                 }

                 backoff.spin_light();
                 tail = self.tail.load(Ordering::Relaxed);
             } else {
                 // Snooze because we need to wait for the stamp to get updated.
                 backoff.spin_heavy();
                 tail = self.tail.load(Ordering::Relaxed);
             }
         }
     }

     /// Writes a message into the channel.
     pub(crate) unsafe fn write(&self, token: &mut Token, msg: T) -> Result<(), T> {
         // If there is no slot, the channel is disconnected.
         if token.array.slot.is_null() {
             return Err(msg);
         }

         let slot: &Slot<T> = &*(token.array.slot as *const Slot<T>);

         // Write the message into the slot and update the stamp.
         slot.msg.get().write(MaybeUninit::new(msg));
         slot.stamp.store(token.array.stamp, Ordering::Release);

         // Wake a sleeping receiver.
         self.receivers.notify();
         Ok(())
     }

     /// Attempts to reserve a slot for receiving a message.
     fn start_recv(&self, token: &mut Token) -> bool {
         let backoff = Backoff::new();
         let mut head = self.head.load(Ordering::Relaxed);

         loop {
             // Deconstruct the head.
             let index = head & (self.mark_bit - 1);
             let lap = head & !(self.one_lap - 1);

             // Inspect the corresponding slot.
             debug_assert!(index < self.buffer.len());
             let slot = unsafe { self.buffer.get_unchecked(index) };
             let stamp = slot.stamp.load(Ordering::Acquire);

             // If the stamp is ahead of the head by 1, we may attempt to pop.
             if head + 1 == stamp {
                 let new = if index + 1 < self.cap {
                     // Same lap, incremented index.
                     // Set to `{ lap: lap, mark: 0, index: index + 1 }`.
                     head + 1
                 } else {
                     // One lap forward, index wraps around to zero.
                     // Set to `{ lap: lap.wrapping_add(1), mark: 0, index: 0 }`.
                     lap.wrapping_add(self.one_lap)
                 };

                 // Try moving the head.
                 match self.head.compare_exchange_weak(
                     head,
                     new,
                     Ordering::SeqCst,
                     Ordering::Relaxed,
                 ) {
                     Ok(_) => {
                         // Prepare the token for the follow-up call to `read`.
                         token.array.slot = slot as *const Slot<T> as *const u8;
                         token.array.stamp = head.wrapping_add(self.one_lap);
                         return true;
                     }
                     Err(_) => {
                         backoff.spin_light();
                         head = self.head.load(Ordering::Relaxed);
                     }
                 }
             } else if stamp == head {
                 atomic::fence(Ordering::SeqCst);
                 let tail = self.tail.load(Ordering::Relaxed);

                 // If the tail equals the head, that means the channel is empty.
                 if (tail & !self.mark_bit) == head {
                     // If the channel is disconnected...
                     if tail & self.mark_bit != 0 {
                         // ...then receive an error.
                         token.array.slot = ptr::null();
                         token.array.stamp = 0;
                         return true;
                     } else {
                         // Otherwise, the receive operation is not ready.
                         return false;
                     }
                 }

                 backoff.spin_light();
                 head = self.head.load(Ordering::Relaxed);
             } else {
                 // Snooze because we need to wait for the stamp to get updated.
                 backoff.spin_heavy();
                 head = self.head.load(Ordering::Relaxed);
             }
         }
     }

     /// Reads a message from the channel.
     pub(crate) unsafe fn read(&self, token: &mut Token) -> Result<T, ()> {
         if token.array.slot.is_null() {
             // The channel is disconnected.
             return Err(());
         }

         let slot: &Slot<T> = &*(token.array.slot as *const Slot<T>);

         // Read the message from the slot and update the stamp.
         let msg = slot.msg.get().read().assume_init();
         slot.stamp.store(token.array.stamp, Ordering::Release);

         // Wake a sleeping sender.
         self.senders.notify();
         Ok(msg)
     }

     /// Attempts to send a message into the channel.
     pub(crate) fn try_send(&self, msg: T) -> Result<(), TrySendError<T>> {
         let token = &mut Token::default();
         if self.start_send(token) {
             unsafe { self.write(token, msg).map_err(TrySendError::Disconnected) }
         } else {
             Err(TrySendError::Full(msg))
         }
     }

     /// Sends a message into the channel.
     pub(crate) fn send(
         &self,
         msg: T,
         deadline: Option<Instant>,
     ) -> Result<(), SendTimeoutError<T>> {
         let token = &mut Token::default();
         loop {
             // Try sending a message several times.
             let backoff = Backoff::new();
             loop {
                 if self.start_send(token) {
                     let res = unsafe { self.write(token, msg) };
                     return res.map_err(SendTimeoutError::Disconnected);
                 }

                 if backoff.is_completed() {
                     break;
                 } else {
                     backoff.spin_light();
                 }
             }

             if let Some(d) = deadline {
                 if Instant::now() >= d {
                     return Err(SendTimeoutError::Timeout(msg));
                 }
             }

             Context::with(|cx| {
                 // Prepare for blocking until a receiver wakes us up.
                 let oper = Operation::hook(token);
                 self.senders.register(oper, cx);

                 // Has the channel become ready just now?
                 if !self.is_full() || self.is_disconnected() {
                     let _ = cx.try_select(Selected::Aborted);
                 }

                 // Block the current thread.
                 let sel = cx.wait_until(deadline);

                 match sel {
                     Selected::Waiting => unreachable!(),
                     Selected::Aborted | Selected::Disconnected => {
                         self.senders.unregister(oper).unwrap();
                     }
                     Selected::Operation(_) => {}
                 }
             });
         }
     }

     /// Attempts to receive a message without blocking.
     pub(crate) fn try_recv(&self) -> Result<T, TryRecvError> {
         let token = &mut Token::default();

         if self.start_recv(token) {
             unsafe { self.read(token).map_err(|_| TryRecvError::Disconnected) }
         } else {
             Err(TryRecvError::Empty)
         }
     }

     /// Receives a message from the channel.
     pub(crate) fn recv(&self, deadline: Option<Instant>) -> Result<T, RecvTimeoutError> {
         let token = &mut Token::default();
         loop {
             if self.start_recv(token) {
                 let res = unsafe { self.read(token) };
                 return res.map_err(|_| RecvTimeoutError::Disconnected);
             }

             if let Some(d) = deadline {
                 if Instant::now() >= d {
                     return Err(RecvTimeoutError::Timeout);
                 }
             }

             Context::with(|cx| {
                 // Prepare for blocking until a sender wakes us up.
                 let oper = Operation::hook(token);
                 self.receivers.register(oper, cx);

                 // Has the channel become ready just now?
                 if !self.is_empty() || self.is_disconnected() {
                     let _ = cx.try_select(Selected::Aborted);
                 }

                 // Block the current thread.
                 let sel = cx.wait_until(deadline);

                 match sel {
                     Selected::Waiting => unreachable!(),
                     Selected::Aborted | Selected::Disconnected => {
                         self.receivers.unregister(oper).unwrap();
                         // If the channel was disconnected, we still have to check for remaining
                         // messages.
                     }
                     Selected::Operation(_) => {}
                 }
             });
         }
     }

     /// Returns the current number of messages inside the channel.
     pub(crate) fn len(&self) -> usize {
         loop {
             // Load the tail, then load the head.
             let tail = self.tail.load(Ordering::SeqCst);
             let head = self.head.load(Ordering::SeqCst);

             // If the tail didn't change, we've got consistent values to work with.
             if self.tail.load(Ordering::SeqCst) == tail {
                 let hix = head & (self.mark_bit - 1);
                 let tix = tail & (self.mark_bit - 1);

                 return if hix < tix {
                     tix - hix
                 } else if hix > tix {
                     self.cap - hix + tix
                 } else if (tail & !self.mark_bit) == head {
                     0
                 } else {
                     self.cap
                 };
             }
         }
     }

     /// Returns the capacity of the channel.
     #[allow(clippy::unnecessary_wraps)] // This is intentional.
     pub(crate) fn capacity(&self) -> Option<usize> {
         Some(self.cap)
     }

     /// Disconnects the channel and wakes up all blocked senders and receivers.
     ///
     /// Returns `true` if this call disconnected the channel.
     pub(crate) fn disconnect(&self) -> bool {
         let tail = self.tail.fetch_or(self.mark_bit, Ordering::SeqCst);

         if tail & self.mark_bit == 0 {
             self.senders.disconnect();
             self.receivers.disconnect();
             true
         } else {
             false
         }
     }

     /// Returns `true` if the channel is disconnected.
     pub(crate) fn is_disconnected(&self) -> bool {
         self.tail.load(Ordering::SeqCst) & self.mark_bit != 0
     }

     /// Returns `true` if the channel is empty.
     pub(crate) fn is_empty(&self) -> bool {
         let head = self.head.load(Ordering::SeqCst);
         let tail = self.tail.load(Ordering::SeqCst);

         // Is the tail equal to the head?
         //
         // Note: If the head changes just before we load the tail, that means there was a moment
         // when the channel was not empty, so it is safe to just return `false`.
         (tail & !self.mark_bit) == head
     }

     /// Returns `true` if the channel is full.
     pub(crate) fn is_full(&self) -> bool {
         let tail = self.tail.load(Ordering::SeqCst);
         let head = self.head.load(Ordering::SeqCst);

         // Is the head lagging one lap behind tail?
         //
         // Note: If the tail changes just before we load the head, that means there was a moment
         // when the channel was not full, so it is safe to just return `false`.
         head.wrapping_add(self.one_lap) == tail & !self.mark_bit
     }
 }

 impl<T> Drop for Channel<T> {
     fn drop(&mut self) {
         // Get the index of the head.
         let hix = self.head.load(Ordering::Relaxed) & (self.mark_bit - 1);

         // Loop over all slots that hold a message and drop them.
         for i in 0..self.len() {
             // Compute the index of the next slot holding a message.
             let index = if hix + i < self.cap { hix + i } else { hix + i - self.cap };

             unsafe {
                 debug_assert!(index < self.buffer.len());
                 let slot = self.buffer.get_unchecked_mut(index);
                 let msg = &mut *slot.msg.get();
                 msg.as_mut_ptr().drop_in_place();
             }
         }
     }
 }
	//! Bounded channel based on a preallocated array.
	//!
	//! This flavor has a fixed, positive capacity.
	//!
	//! The implementation is based on Dmitry Vyukov's bounded MPMC queue.
	//!
	//! Source:
	//! - <http://www.1024cores.net/home/lock-free-algorithms/queues/bounded-mpmc-queue>
	//! - <https://docs.google.com/document/d/1yIAYmbvL3JxOKOjuCyon7JhW4cSv1wy5hC0ApeGMV9s/pub>

	use super::context::Context;
	use super::error::*;
	use super::select::{Operation, Selected, Token};
	use super::utils::{Backoff, CachePadded};
	use super::waker::SyncWaker;

	use crate::cell::UnsafeCell;
	use crate::mem::MaybeUninit;
	use crate::ptr;
	use crate::sync::atomic::{self, AtomicUsize, Ordering};
	use crate::time::Instant;

	/// A slot in a channel.
	struct Slot<T> {
	/// The current stamp.
	stamp: AtomicUsize,

	/// The message in this slot.
	msg: UnsafeCell<MaybeUninit<T>>,
	}

	/// The token type for the array flavor.
	#[derive(Debug)]
	pub(crate) struct ArrayToken {
	/// Slot to read from or write to.
	slot: *const u8,

	/// Stamp to store into the slot after reading or writing.
	stamp: usize,
	}

	impl Default for ArrayToken {
	#[inline]
	fn default() -> Self {
	ArrayToken { slot: ptr::null(), stamp: 0 }
	}
	}

	/// Bounded channel based on a preallocated array.
	pub(crate) struct Channel<T> {
	/// The head of the channel.
	///
	/// This value is a "stamp" consisting of an index into the buffer, a mark bit, and a lap, but
	/// packed into a single `usize`. The lower bits represent the index, while the upper bits
	/// represent the lap. The mark bit in the head is always zero.
	///
	/// Messages are popped from the head of the channel.
	head: CachePadded<AtomicUsize>,

	/// The tail of the channel.
	///
	/// This value is a "stamp" consisting of an index into the buffer, a mark bit, and a lap, but
	/// packed into a single `usize`. The lower bits represent the index, while the upper bits
	/// represent the lap. The mark bit indicates that the channel is disconnected.
	///
	/// Messages are pushed into the tail of the channel.
	tail: CachePadded<AtomicUsize>,

	/// The buffer holding slots.
	buffer: Box<[Slot<T>]>,

	/// The channel capacity.
	cap: usize,

	/// A stamp with the value of `{ lap: 1, mark: 0, index: 0 }`.
	one_lap: usize,

	/// If this bit is set in the tail, that means the channel is disconnected.
	mark_bit: usize,

	/// Senders waiting while the channel is full.
	senders: SyncWaker,

	/// Receivers waiting while the channel is empty and not disconnected.
	receivers: SyncWaker,
	}

	impl<T> Channel<T> {
	/// Creates a bounded channel of capacity `cap`.
	pub(crate) fn with_capacity(cap: usize) -> Self {
	assert!(cap > 0, "capacity must be positive");

	// Compute constants `mark_bit` and `one_lap`.
	let mark_bit = (cap + 1).next_power_of_two();
	let one_lap = mark_bit * 2;

	// Head is initialized to `{ lap: 0, mark: 0, index: 0 }`.
	let head = 0;
	// Tail is initialized to `{ lap: 0, mark: 0, index: 0 }`.
	let tail = 0;

	// Allocate a buffer of `cap` slots initialized
	// with stamps.
	let buffer: Box<[Slot<T>]> = (0..cap)
	.map(\|i\| {
	// Set the stamp to `{ lap: 0, mark: 0, index: i }`.
	Slot { stamp: AtomicUsize::new(i), msg: UnsafeCell::new(MaybeUninit::uninit()) }
	})
	.collect();

	Channel {
	buffer,
	cap,
	one_lap,
	mark_bit,
	head: CachePadded::new(AtomicUsize::new(head)),
	tail: CachePadded::new(AtomicUsize::new(tail)),
	senders: SyncWaker::new(),
	receivers: SyncWaker::new(),
	}
	}

	/// Attempts to reserve a slot for sending a message.
	fn start_send(&self, token: &mut Token) -> bool {
	let backoff = Backoff::new();
	let mut tail = self.tail.load(Ordering::Relaxed);

	loop {
	// Check if the channel is disconnected.
	if tail & self.mark_bit != 0 {
	token.array.slot = ptr::null();
	token.array.stamp = 0;
	return true;
	}

	// Deconstruct the tail.
	let index = tail & (self.mark_bit - 1);
	let lap = tail & !(self.one_lap - 1);

	// Inspect the corresponding slot.
	debug_assert!(index < self.buffer.len());
	let slot = unsafe { self.buffer.get_unchecked(index) };
	let stamp = slot.stamp.load(Ordering::Acquire);

	// If the tail and the stamp match, we may attempt to push.
	if tail == stamp {
	let new_tail = if index + 1 < self.cap {
	// Same lap, incremented index.
	// Set to `{ lap: lap, mark: 0, index: index + 1 }`.
	tail + 1
	} else {
	// One lap forward, index wraps around to zero.
	// Set to `{ lap: lap.wrapping_add(1), mark: 0, index: 0 }`.
	lap.wrapping_add(self.one_lap)
	};

	// Try moving the tail.
	match self.tail.compare_exchange_weak(
	tail,
	new_tail,
	Ordering::SeqCst,
	Ordering::Relaxed,
	) {
	Ok(_) => {
	// Prepare the token for the follow-up call to `write`.
	token.array.slot = slot as const Slot<T> as const u8;
	token.array.stamp = tail + 1;
	return true;
	}
	Err(_) => {
	backoff.spin_light();
	tail = self.tail.load(Ordering::Relaxed);
	}
	}
	} else if stamp.wrapping_add(self.one_lap) == tail + 1 {
	atomic::fence(Ordering::SeqCst);
	let head = self.head.load(Ordering::Relaxed);

	// If the head lags one lap behind the tail as well...
	if head.wrapping_add(self.one_lap) == tail {
	// ...then the channel is full.
	return false;
	}

	backoff.spin_light();
	tail = self.tail.load(Ordering::Relaxed);
	} else {
	// Snooze because we need to wait for the stamp to get updated.
	backoff.spin_heavy();
	tail = self.tail.load(Ordering::Relaxed);
	}
	}
	}

	/// Writes a message into the channel.
	pub(crate) unsafe fn write(&self, token: &mut Token, msg: T) -> Result<(), T> {
	// If there is no slot, the channel is disconnected.
	if token.array.slot.is_null() {
	return Err(msg);
	}

	let slot: &Slot<T> = &(token.array.slot as const Slot<T>);

	// Write the message into the slot and update the stamp.
	slot.msg.get().write(MaybeUninit::new(msg));
	slot.stamp.store(token.array.stamp, Ordering::Release);

	// Wake a sleeping receiver.
	self.receivers.notify();
	Ok(())
	}

	/// Attempts to reserve a slot for receiving a message.
	fn start_recv(&self, token: &mut Token) -> bool {
	let backoff = Backoff::new();
	let mut head = self.head.load(Ordering::Relaxed);

	loop {
	// Deconstruct the head.
	let index = head & (self.mark_bit - 1);
	let lap = head & !(self.one_lap - 1);

	// Inspect the corresponding slot.
	debug_assert!(index < self.buffer.len());
	let slot = unsafe { self.buffer.get_unchecked(index) };
	let stamp = slot.stamp.load(Ordering::Acquire);

	// If the stamp is ahead of the head by 1, we may attempt to pop.
	if head + 1 == stamp {
	let new = if index + 1 < self.cap {
	// Same lap, incremented index.
	// Set to `{ lap: lap, mark: 0, index: index + 1 }`.
	head + 1
	} else {
	// One lap forward, index wraps around to zero.
	// Set to `{ lap: lap.wrapping_add(1), mark: 0, index: 0 }`.
	lap.wrapping_add(self.one_lap)
	};

	// Try moving the head.
	match self.head.compare_exchange_weak(
	head,
	new,
	Ordering::SeqCst,
	Ordering::Relaxed,
	) {
	Ok(_) => {
	// Prepare the token for the follow-up call to `read`.
	token.array.slot = slot as const Slot<T> as const u8;
	token.array.stamp = head.wrapping_add(self.one_lap);
	return true;
	}
	Err(_) => {
	backoff.spin_light();
	head = self.head.load(Ordering::Relaxed);
	}
	}
	} else if stamp == head {
	atomic::fence(Ordering::SeqCst);
	let tail = self.tail.load(Ordering::Relaxed);

	// If the tail equals the head, that means the channel is empty.
	if (tail & !self.mark_bit) == head {
	// If the channel is disconnected...
	if tail & self.mark_bit != 0 {
	// ...then receive an error.
	token.array.slot = ptr::null();
	token.array.stamp = 0;
	return true;
	} else {
	// Otherwise, the receive operation is not ready.
	return false;
	}
	}

	backoff.spin_light();
	head = self.head.load(Ordering::Relaxed);
	} else {
	// Snooze because we need to wait for the stamp to get updated.
	backoff.spin_heavy();
	head = self.head.load(Ordering::Relaxed);
	}
	}
	}

	/// Reads a message from the channel.
	pub(crate) unsafe fn read(&self, token: &mut Token) -> Result<T, ()> {
	if token.array.slot.is_null() {
	// The channel is disconnected.
	return Err(());
	}

	let slot: &Slot<T> = &(token.array.slot as const Slot<T>);

	// Read the message from the slot and update the stamp.
	let msg = slot.msg.get().read().assume_init();
	slot.stamp.store(token.array.stamp, Ordering::Release);

	// Wake a sleeping sender.
	self.senders.notify();
	Ok(msg)
	}

	/// Attempts to send a message into the channel.
	pub(crate) fn try_send(&self, msg: T) -> Result<(), TrySendError<T>> {
	let token = &mut Token::default();
	if self.start_send(token) {
	unsafe { self.write(token, msg).map_err(TrySendError::Disconnected) }
	} else {
	Err(TrySendError::Full(msg))
	}
	}

	/// Sends a message into the channel.
	pub(crate) fn send(
	&self,
	msg: T,
	deadline: Option<Instant>,
	) -> Result<(), SendTimeoutError<T>> {
	let token = &mut Token::default();
	loop {
	// Try sending a message several times.
	let backoff = Backoff::new();
	loop {
	if self.start_send(token) {
	let res = unsafe { self.write(token, msg) };
	return res.map_err(SendTimeoutError::Disconnected);
	}

	if backoff.is_completed() {
	break;
	} else {
	backoff.spin_light();
	}
	}

	if let Some(d) = deadline {
	if Instant::now() >= d {
	return Err(SendTimeoutError::Timeout(msg));
	}
	}

	Context::with(\|cx\| {
	// Prepare for blocking until a receiver wakes us up.
	let oper = Operation::hook(token);
	self.senders.register(oper, cx);

	// Has the channel become ready just now?
	if !self.is_full() \|\| self.is_disconnected() {
	let _ = cx.try_select(Selected::Aborted);
	}

	// Block the current thread.
	let sel = cx.wait_until(deadline);

	match sel {
	Selected::Waiting => unreachable!(),
	Selected::Aborted \| Selected::Disconnected => {
	self.senders.unregister(oper).unwrap();
	}
	Selected::Operation(_) => {}
	}
	});
	}
	}

	/// Attempts to receive a message without blocking.
	pub(crate) fn try_recv(&self) -> Result<T, TryRecvError> {
	let token = &mut Token::default();

	if self.start_recv(token) {
	unsafe { self.read(token).map_err(\|_\| TryRecvError::Disconnected) }
	} else {
	Err(TryRecvError::Empty)
	}
	}

	/// Receives a message from the channel.
	pub(crate) fn recv(&self, deadline: Option<Instant>) -> Result<T, RecvTimeoutError> {
	let token = &mut Token::default();
	loop {
	if self.start_recv(token) {
	let res = unsafe { self.read(token) };
	return res.map_err(\|_\| RecvTimeoutError::Disconnected);
	}

	if let Some(d) = deadline {
	if Instant::now() >= d {
	return Err(RecvTimeoutError::Timeout);
	}
	}

	Context::with(\|cx\| {
	// Prepare for blocking until a sender wakes us up.
	let oper = Operation::hook(token);
	self.receivers.register(oper, cx);

	// Has the channel become ready just now?
	if !self.is_empty() \|\| self.is_disconnected() {
	let _ = cx.try_select(Selected::Aborted);
	}

	// Block the current thread.
	let sel = cx.wait_until(deadline);

	match sel {
	Selected::Waiting => unreachable!(),
	Selected::Aborted \| Selected::Disconnected => {
	self.receivers.unregister(oper).unwrap();
	// If the channel was disconnected, we still have to check for remaining
	// messages.
	}
	Selected::Operation(_) => {}
	}
	});
	}
	}

	/// Returns the current number of messages inside the channel.
	pub(crate) fn len(&self) -> usize {
	loop {
	// Load the tail, then load the head.
	let tail = self.tail.load(Ordering::SeqCst);
	let head = self.head.load(Ordering::SeqCst);

	// If the tail didn't change, we've got consistent values to work with.
	if self.tail.load(Ordering::SeqCst) == tail {
	let hix = head & (self.mark_bit - 1);
	let tix = tail & (self.mark_bit - 1);

	return if hix < tix {
	tix - hix
	} else if hix > tix {
	self.cap - hix + tix
	} else if (tail & !self.mark_bit) == head {
	0
	} else {
	self.cap
	};
	}
	}
	}

	/// Returns the capacity of the channel.
	#[allow(clippy::unnecessary_wraps)] // This is intentional.
	pub(crate) fn capacity(&self) -> Option<usize> {
	Some(self.cap)
	}

	/// Disconnects the channel and wakes up all blocked senders and receivers.
	///
	/// Returns `true` if this call disconnected the channel.
	pub(crate) fn disconnect(&self) -> bool {
	let tail = self.tail.fetch_or(self.mark_bit, Ordering::SeqCst);

	if tail & self.mark_bit == 0 {
	self.senders.disconnect();
	self.receivers.disconnect();
	true
	} else {
	false
	}
	}

	/// Returns `true` if the channel is disconnected.
	pub(crate) fn is_disconnected(&self) -> bool {
	self.tail.load(Ordering::SeqCst) & self.mark_bit != 0
	}

	/// Returns `true` if the channel is empty.
	pub(crate) fn is_empty(&self) -> bool {
	let head = self.head.load(Ordering::SeqCst);
	let tail = self.tail.load(Ordering::SeqCst);

	// Is the tail equal to the head?
	//
	// Note: If the head changes just before we load the tail, that means there was a moment
	// when the channel was not empty, so it is safe to just return `false`.
	(tail & !self.mark_bit) == head
	}

	/// Returns `true` if the channel is full.
	pub(crate) fn is_full(&self) -> bool {
	let tail = self.tail.load(Ordering::SeqCst);
	let head = self.head.load(Ordering::SeqCst);

	// Is the head lagging one lap behind tail?
	//
	// Note: If the tail changes just before we load the head, that means there was a moment
	// when the channel was not full, so it is safe to just return `false`.
	head.wrapping_add(self.one_lap) == tail & !self.mark_bit
	}
	}

	impl<T> Drop for Channel<T> {
	fn drop(&mut self) {
	// Get the index of the head.
	let hix = self.head.load(Ordering::Relaxed) & (self.mark_bit - 1);

	// Loop over all slots that hold a message and drop them.
	for i in 0..self.len() {
	// Compute the index of the next slot holding a message.
	let index = if hix + i < self.cap { hix + i } else { hix + i - self.cap };

	unsafe {
	debug_assert!(index < self.buffer.len());
	let slot = self.buffer.get_unchecked_mut(index);
	let msg = &mut *slot.msg.get();
	msg.as_mut_ptr().drop_in_place();
	}
	}
	}
	}