src/timer.rs - third_party/mio - Git at Google

 //! Timer optimized for I/O related operations

 #![allow(deprecated, missing_debug_implementations)]

 extern crate slab;

 use {convert, io, Ready, Poll, PollOpt, Registration, SetReadiness, Token};
 use event::Evented;
 use lazycell::LazyCell;
 use std::{cmp, error, fmt, u64, usize, iter, thread};
 use std::sync::Arc;
 use std::sync::atomic::{AtomicUsize, Ordering};
 use std::time::{Duration, Instant};

 use self::TimerErrorKind::TimerOverflow;

 pub struct Timer<T> {
     // Size of each tick in milliseconds
     tick_ms: u64,
     // Slab of timeout entries
     entries: Slab<Entry<T>>,
     // Timeout wheel. Each tick, the timer will look at the next slot for
     // timeouts that match the current tick.
     wheel: Vec<WheelEntry>,
     // Tick 0's time instant
     start: Instant,
     // The current tick
     tick: Tick,
     // The next entry to possibly timeout
     next: Token,
     // Masks the target tick to get the slot
     mask: u64,
     // Set on registration with Poll
     inner: LazyCell<Inner>,
 }

 pub struct Builder {
     // Approximate duration of each tick
     tick: Duration,
     // Number of slots in the timer wheel
     num_slots: usize,
     // Max number of timeouts that can be in flight at a given time.
     capacity: usize,
 }

 #[derive(Clone, Debug)]
 pub struct Timeout {
     // Reference into the timer entry slab
     token: Token,
     // Tick that it should match up with
     tick: u64,
 }

 struct Inner {
     registration: Registration,
     set_readiness: SetReadiness,
     wakeup_state: WakeupState,
     wakeup_thread: thread::JoinHandle<()>,
 }

 impl Drop for Inner {
     fn drop(&mut self) {
         // 1. Set wakeup state to TERMINATE_THREAD (https://github.com/carllerche/mio/blob/master/src/timer.rs#L451)
         self.wakeup_state.store(TERMINATE_THREAD, Ordering::Release);
         // 2. Wake him up
         self.wakeup_thread.thread().unpark();
     }
 }

 #[derive(Copy, Clone, Debug)]
 struct WheelEntry {
     next_tick: Tick,
     head: Token,
 }

 // Doubly linked list of timer entries. Allows for efficient insertion /
 // removal of timeouts.
 struct Entry<T> {
     state: T,
     links: EntryLinks,
 }

 #[derive(Copy, Clone)]
 struct EntryLinks {
     tick: Tick,
     prev: Token,
     next: Token
 }

 type Tick = u64;

 const TICK_MAX: Tick = u64::MAX;

 // Manages communication with wakeup thread
 type WakeupState = Arc<AtomicUsize>;

 type Slab<T> = slab::Slab<T, ::Token>;

 pub type Result<T> = ::std::result::Result<T, TimerError>;
 // TODO: remove
 pub type TimerResult<T> = Result<T>;


 #[derive(Debug)]
 pub struct TimerError {
     kind: TimerErrorKind,
     desc: &'static str,
 }

 #[derive(Debug)]
 pub enum TimerErrorKind {
     TimerOverflow,
 }

 // TODO: Remove
 pub type OldTimerResult<T> = Result<T>;

 const TERMINATE_THREAD: usize = 0;
 const EMPTY: Token = Token(usize::MAX);

 impl Builder {
     pub fn tick_duration(mut self, duration: Duration) -> Builder {
         self.tick = duration;
         self
     }

     pub fn num_slots(mut self, num_slots: usize) -> Builder {
         self.num_slots = num_slots;
         self
     }

     pub fn capacity(mut self, capacity: usize) -> Builder {
         self.capacity = capacity;
         self
     }

     pub fn build<T>(self) -> Timer<T> {
         Timer::new(convert::millis(self.tick), self.num_slots, self.capacity, Instant::now())
     }
 }

 impl Default for Builder {
     fn default() -> Builder {
         Builder {
             tick: Duration::from_millis(100),
             num_slots: 256,
             capacity: 65_536,
         }
     }
 }

 impl<T> Timer<T> {
     fn new(tick_ms: u64, num_slots: usize, capacity: usize, start: Instant) -> Timer<T> {
         let num_slots = num_slots.next_power_of_two();
         let capacity = capacity.next_power_of_two();
         let mask = (num_slots as u64) - 1;
         let wheel = iter::repeat(WheelEntry { next_tick: TICK_MAX, head: EMPTY })
             .take(num_slots).collect();

         Timer {
             tick_ms: tick_ms,
             entries: Slab::with_capacity(capacity),
             wheel: wheel,
             start: start,
             tick: 0,
             next: EMPTY,
             mask: mask,
             inner: LazyCell::new(),
         }
     }

     pub fn set_timeout(&mut self, delay_from_now: Duration, state: T) -> Result<Timeout> {
         let delay_from_start = self.start.elapsed() + delay_from_now;
         self.set_timeout_at(delay_from_start, state)
     }

     fn set_timeout_at(&mut self, delay_from_start: Duration, state: T) -> Result<Timeout> {
         let mut tick = duration_to_tick(delay_from_start, self.tick_ms);
         trace!("setting timeout; delay={:?}; tick={:?}; current-tick={:?}", delay_from_start, tick, self.tick);

         // Always target at least 1 tick in the future
         if tick <= self.tick {
             tick = self.tick + 1;
         }

         self.insert(tick, state)
     }

     fn insert(&mut self, tick: Tick, state: T) -> Result<Timeout> {
         // Get the slot for the requested tick
         let slot = (tick & self.mask) as usize;
         let curr = self.wheel[slot];

         // Insert the new entry
         let token = self.entries.insert(Entry::new(state, tick, curr.head))
             .map_err(|_| TimerError::overflow())?;

         if curr.head != EMPTY {
             // If there was a previous entry, set its prev pointer to the new
             // entry
             self.entries[curr.head].links.prev = token;
         }

         // Update the head slot
         self.wheel[slot] = WheelEntry {
             next_tick: cmp::min(tick, curr.next_tick),
             head: token,
         };

         self.schedule_readiness(tick);

         trace!("inserted timeout; slot={}; token={:?}", slot, token);

         // Return the new timeout
         Ok(Timeout {
             token: token,
             tick: tick
         })
     }

     pub fn cancel_timeout(&mut self, timeout: &Timeout) -> Option<T> {
         let links = match self.entries.get(timeout.token) {
             Some(e) => e.links,
             None => return None
         };

         // Sanity check
         if links.tick != timeout.tick {
             return None;
         }

         self.unlink(&links, timeout.token);
         self.entries.remove(timeout.token).map(|e| e.state)
     }

     pub fn poll(&mut self) -> Option<T> {
         let target_tick = current_tick(self.start, self.tick_ms);
         self.poll_to(target_tick)
     }

     fn poll_to(&mut self, mut target_tick: Tick) -> Option<T> {
         trace!("tick_to; target_tick={}; current_tick={}", target_tick, self.tick);

         if target_tick < self.tick {
             target_tick = self.tick;
         }

         while self.tick <= target_tick {
             let curr = self.next;

             trace!("ticking; curr={:?}", curr);

             if curr == EMPTY {
                 self.tick += 1;

                 let slot = self.slot_for(self.tick);
                 self.next = self.wheel[slot].head;

                 // Handle the case when a slot has a single timeout which gets
                 // canceled before the timeout expires. In this case, the
                 // slot's head is EMPTY but there is a value for next_tick. Not
                 // resetting next_tick here causes the timer to get stuck in a
                 // loop.
                 if self.next == EMPTY {
                     self.wheel[slot].next_tick = TICK_MAX;
                 }
             } else {
                 let slot = self.slot_for(self.tick);

                 if curr == self.wheel[slot].head {
                     self.wheel[slot].next_tick = TICK_MAX;
                 }

                 let links = self.entries[curr].links;

                 if links.tick <= self.tick {
                     trace!("triggering; token={:?}", curr);

                     // Unlink will also advance self.next
                     self.unlink(&links, curr);

                     // Remove and return the token
                     return self.entries.remove(curr)
                         .map(|e| e.state);
                 } else {
                     let next_tick = self.wheel[slot].next_tick;
                     self.wheel[slot].next_tick = cmp::min(next_tick, links.tick);
                     self.next = links.next;
                 }
             }
         }

         // No more timeouts to poll
         if let Some(inner) = self.inner.borrow() {
             trace!("unsetting readiness");
             let _ = inner.set_readiness.set_readiness(Ready::empty());

             if let Some(tick) = self.next_tick() {
                 self.schedule_readiness(tick);
             }
         }

         None
     }

     fn unlink(&mut self, links: &EntryLinks, token: Token) {
        trace!("unlinking timeout; slot={}; token={:?}",
                self.slot_for(links.tick), token);

         if links.prev == EMPTY {
             let slot = self.slot_for(links.tick);
             self.wheel[slot].head = links.next;
         } else {
             self.entries[links.prev].links.next = links.next;
         }

         if links.next != EMPTY {
             self.entries[links.next].links.prev = links.prev;

             if token == self.next {
                 self.next = links.next;
             }
         } else if token == self.next {
             self.next = EMPTY;
         }
     }

     fn schedule_readiness(&self, tick: Tick) {
         if let Some(inner) = self.inner.borrow() {
             // Coordinate setting readiness w/ the wakeup thread
             let mut curr = inner.wakeup_state.load(Ordering::Acquire);

             loop {
                 if curr as Tick <= tick {
                     // Nothing to do, wakeup is already scheduled
                     return;
                 }

                 // Attempt to move the wakeup time forward
                 trace!("advancing the wakeup time; target={}; curr={}", tick, curr);
                 let actual = inner.wakeup_state.compare_and_swap(curr, tick as usize, Ordering::Release);

                 if actual == curr {
                     // Signal to the wakeup thread that the wakeup time has
                     // been changed.
                     trace!("unparking wakeup thread");
                     inner.wakeup_thread.thread().unpark();
                     return;
                 }

                 curr = actual;
             }
         }
     }

     // Next tick containing a timeout
     fn next_tick(&self) -> Option<Tick> {
         if self.next != EMPTY {
             let slot = self.slot_for(self.entries[self.next].links.tick);

             if self.wheel[slot].next_tick == self.tick {
                 // There is data ready right now
                 return Some(self.tick);
             }
         }

         self.wheel.iter().map(|e| e.next_tick).min()
     }

     fn slot_for(&self, tick: Tick) -> usize {
         (self.mask & tick) as usize
     }
 }

 impl<T> Default for Timer<T> {
     fn default() -> Timer<T> {
         Builder::default().build()
     }
 }

 impl<T> Evented for Timer<T> {
     fn register(&self, poll: &Poll, token: Token, interest: Ready, opts: PollOpt) -> io::Result<()> {
         if self.inner.borrow().is_some() {
             return Err(io::Error::new(io::ErrorKind::Other, "timer already registered"));
         }

         let (registration, set_readiness) = Registration::new(poll, token, interest, opts);
         let wakeup_state = Arc::new(AtomicUsize::new(usize::MAX));
         let thread_handle = spawn_wakeup_thread(
             wakeup_state.clone(),
             set_readiness.clone(),
             self.start, self.tick_ms);

         self.inner.fill(Inner {
             registration: registration,
             set_readiness: set_readiness,
             wakeup_state: wakeup_state,
             wakeup_thread: thread_handle,
         }).ok().expect("timer already registered");

         if let Some(next_tick) = self.next_tick() {
             self.schedule_readiness(next_tick);
         }

         Ok(())
     }

     fn reregister(&self, poll: &Poll, token: Token, interest: Ready, opts: PollOpt) -> io::Result<()> {
         match self.inner.borrow() {
             Some(inner) => inner.registration.update(poll, token, interest, opts),
             None => Err(io::Error::new(io::ErrorKind::Other, "receiver not registered")),
         }
     }

     fn deregister(&self, poll: &Poll) -> io::Result<()> {
         match self.inner.borrow() {
             Some(inner) => inner.registration.deregister(poll),
             None => Err(io::Error::new(io::ErrorKind::Other, "receiver not registered")),
         }
     }
 }

 impl fmt::Debug for Inner {
     fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
         fmt.debug_struct("Inner")
             .field("registration", &self.registration)
             .field("wakeup_state", &self.wakeup_state.load(Ordering::Relaxed))
             .finish()
     }
 }

 fn spawn_wakeup_thread(state: WakeupState, set_readiness: SetReadiness, start: Instant, tick_ms: u64) -> thread::JoinHandle<()> {
     thread::spawn(move || {
         let mut sleep_until_tick = state.load(Ordering::Acquire) as Tick;

         loop {
             if sleep_until_tick == TERMINATE_THREAD as Tick {
                 return;
             }

             let now_tick = current_tick(start, tick_ms);

             trace!("wakeup thread: sleep_until_tick={:?}; now_tick={:?}", sleep_until_tick, now_tick);

             if now_tick < sleep_until_tick {
                 // Calling park_timeout with u64::MAX leads to undefined
                 // behavior in pthread, causing the park to return immediately
                 // and causing the thread to tightly spin. Instead of u64::MAX
                 // on large values, simply use a blocking park.
                 match tick_ms.checked_mul(sleep_until_tick - now_tick) {
                     Some(sleep_duration) => {
                         trace!("sleeping; tick_ms={}; now_tick={}; sleep_until_tick={}; duration={:?}",
                                tick_ms, now_tick, sleep_until_tick, sleep_duration);
                         thread::park_timeout(Duration::from_millis(sleep_duration));
                     }
                     None => {
                         trace!("sleeping; tick_ms={}; now_tick={}; blocking sleep",
                                tick_ms, now_tick);
                         thread::park();
                     }
                 }
                 sleep_until_tick = state.load(Ordering::Acquire) as Tick;
             } else {
                 let actual = state.compare_and_swap(sleep_until_tick as usize, usize::MAX, Ordering::AcqRel) as Tick;

                 if actual == sleep_until_tick {
                     trace!("setting readiness from wakeup thread");
                     let _ = set_readiness.set_readiness(Ready::readable());
                     sleep_until_tick = usize::MAX as Tick;
                 } else {
                     sleep_until_tick = actual as Tick;
                 }
             }
         }
     })
 }

 fn duration_to_tick(elapsed: Duration, tick_ms: u64) -> Tick {
     // Calculate tick rounding up to the closest one
     let elapsed_ms = convert::millis(elapsed);
     elapsed_ms.saturating_add(tick_ms / 2) / tick_ms
 }

 fn current_tick(start: Instant, tick_ms: u64) -> Tick {
     duration_to_tick(start.elapsed(), tick_ms)
 }

 impl<T> Entry<T> {
     fn new(state: T, tick: u64, next: Token) -> Entry<T> {
         Entry {
             state: state,
             links: EntryLinks {
                 tick: tick,
                 prev: EMPTY,
                 next: next,
             },
         }
     }
 }

 impl fmt::Display for TimerError {
     fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
         write!(fmt, "{}: {}", self.kind, self.desc)
     }
 }

 impl TimerError {
     fn overflow() -> TimerError {
         TimerError {
             kind: TimerOverflow,
             desc: "too many timer entries"
         }
     }
 }

 impl error::Error for TimerError {
     fn description(&self) -> &str {
         self.desc
     }
 }

 impl fmt::Display for TimerErrorKind {
     fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
         match *self {
             TimerOverflow => write!(fmt, "TimerOverflow"),
         }
     }
 }
	//! Timer optimized for I/O related operations

	#![allow(deprecated, missing_debug_implementations)]

	extern crate slab;

	use {convert, io, Ready, Poll, PollOpt, Registration, SetReadiness, Token};
	use event::Evented;
	use lazycell::LazyCell;
	use std::{cmp, error, fmt, u64, usize, iter, thread};
	use std::sync::Arc;
	use std::sync::atomic::{AtomicUsize, Ordering};
	use std::time::{Duration, Instant};

	use self::TimerErrorKind::TimerOverflow;

	pub struct Timer<T> {
	// Size of each tick in milliseconds
	tick_ms: u64,
	// Slab of timeout entries
	entries: Slab<Entry<T>>,
	// Timeout wheel. Each tick, the timer will look at the next slot for
	// timeouts that match the current tick.
	wheel: Vec<WheelEntry>,
	// Tick 0's time instant
	start: Instant,
	// The current tick
	tick: Tick,
	// The next entry to possibly timeout
	next: Token,
	// Masks the target tick to get the slot
	mask: u64,
	// Set on registration with Poll
	inner: LazyCell<Inner>,
	}

	pub struct Builder {
	// Approximate duration of each tick
	tick: Duration,
	// Number of slots in the timer wheel
	num_slots: usize,
	// Max number of timeouts that can be in flight at a given time.
	capacity: usize,
	}

	#[derive(Clone, Debug)]
	pub struct Timeout {
	// Reference into the timer entry slab
	token: Token,
	// Tick that it should match up with
	tick: u64,
	}

	struct Inner {
	registration: Registration,
	set_readiness: SetReadiness,
	wakeup_state: WakeupState,
	wakeup_thread: thread::JoinHandle<()>,
	}

	impl Drop for Inner {
	fn drop(&mut self) {
	// 1. Set wakeup state to TERMINATE_THREAD (https://github.com/carllerche/mio/blob/master/src/timer.rs#L451)
	self.wakeup_state.store(TERMINATE_THREAD, Ordering::Release);
	// 2. Wake him up
	self.wakeup_thread.thread().unpark();
	}
	}

	#[derive(Copy, Clone, Debug)]
	struct WheelEntry {
	next_tick: Tick,
	head: Token,
	}

	// Doubly linked list of timer entries. Allows for efficient insertion /
	// removal of timeouts.
	struct Entry<T> {
	state: T,
	links: EntryLinks,
	}

	#[derive(Copy, Clone)]
	struct EntryLinks {
	tick: Tick,
	prev: Token,
	next: Token
	}

	type Tick = u64;

	const TICK_MAX: Tick = u64::MAX;

	// Manages communication with wakeup thread
	type WakeupState = Arc<AtomicUsize>;

	type Slab<T> = slab::Slab<T, ::Token>;

	pub type Result<T> = ::std::result::Result<T, TimerError>;
	// TODO: remove
	pub type TimerResult<T> = Result<T>;


	#[derive(Debug)]
	pub struct TimerError {
	kind: TimerErrorKind,
	desc: &'static str,
	}

	#[derive(Debug)]
	pub enum TimerErrorKind {
	TimerOverflow,
	}

	// TODO: Remove
	pub type OldTimerResult<T> = Result<T>;

	const TERMINATE_THREAD: usize = 0;
	const EMPTY: Token = Token(usize::MAX);

	impl Builder {
	pub fn tick_duration(mut self, duration: Duration) -> Builder {
	self.tick = duration;
	self
	}

	pub fn num_slots(mut self, num_slots: usize) -> Builder {
	self.num_slots = num_slots;
	self
	}

	pub fn capacity(mut self, capacity: usize) -> Builder {
	self.capacity = capacity;
	self
	}

	pub fn build<T>(self) -> Timer<T> {
	Timer::new(convert::millis(self.tick), self.num_slots, self.capacity, Instant::now())
	}
	}

	impl Default for Builder {
	fn default() -> Builder {
	Builder {
	tick: Duration::from_millis(100),
	num_slots: 256,
	capacity: 65_536,
	}
	}
	}

	impl<T> Timer<T> {
	fn new(tick_ms: u64, num_slots: usize, capacity: usize, start: Instant) -> Timer<T> {
	let num_slots = num_slots.next_power_of_two();
	let capacity = capacity.next_power_of_two();
	let mask = (num_slots as u64) - 1;
	let wheel = iter::repeat(WheelEntry { next_tick: TICK_MAX, head: EMPTY })
	.take(num_slots).collect();

	Timer {
	tick_ms: tick_ms,
	entries: Slab::with_capacity(capacity),
	wheel: wheel,
	start: start,
	tick: 0,
	next: EMPTY,
	mask: mask,
	inner: LazyCell::new(),
	}
	}

	pub fn set_timeout(&mut self, delay_from_now: Duration, state: T) -> Result<Timeout> {
	let delay_from_start = self.start.elapsed() + delay_from_now;
	self.set_timeout_at(delay_from_start, state)
	}

	fn set_timeout_at(&mut self, delay_from_start: Duration, state: T) -> Result<Timeout> {
	let mut tick = duration_to_tick(delay_from_start, self.tick_ms);
	trace!("setting timeout; delay={:?}; tick={:?}; current-tick={:?}", delay_from_start, tick, self.tick);

	// Always target at least 1 tick in the future
	if tick <= self.tick {
	tick = self.tick + 1;
	}

	self.insert(tick, state)
	}

	fn insert(&mut self, tick: Tick, state: T) -> Result<Timeout> {
	// Get the slot for the requested tick
	let slot = (tick & self.mask) as usize;
	let curr = self.wheel[slot];

	// Insert the new entry
	let token = self.entries.insert(Entry::new(state, tick, curr.head))
	.map_err(\|_\| TimerError::overflow())?;

	if curr.head != EMPTY {
	// If there was a previous entry, set its prev pointer to the new
	// entry
	self.entries[curr.head].links.prev = token;
	}

	// Update the head slot
	self.wheel[slot] = WheelEntry {
	next_tick: cmp::min(tick, curr.next_tick),
	head: token,
	};

	self.schedule_readiness(tick);

	trace!("inserted timeout; slot={}; token={:?}", slot, token);

	// Return the new timeout
	Ok(Timeout {
	token: token,
	tick: tick
	})
	}

	pub fn cancel_timeout(&mut self, timeout: &Timeout) -> Option<T> {
	let links = match self.entries.get(timeout.token) {
	Some(e) => e.links,
	None => return None
	};

	// Sanity check
	if links.tick != timeout.tick {
	return None;
	}

	self.unlink(&links, timeout.token);
	self.entries.remove(timeout.token).map(\|e\| e.state)
	}

	pub fn poll(&mut self) -> Option<T> {
	let target_tick = current_tick(self.start, self.tick_ms);
	self.poll_to(target_tick)
	}

	fn poll_to(&mut self, mut target_tick: Tick) -> Option<T> {
	trace!("tick_to; target_tick={}; current_tick={}", target_tick, self.tick);

	if target_tick < self.tick {
	target_tick = self.tick;
	}

	while self.tick <= target_tick {
	let curr = self.next;

	trace!("ticking; curr={:?}", curr);

	if curr == EMPTY {
	self.tick += 1;

	let slot = self.slot_for(self.tick);
	self.next = self.wheel[slot].head;

	// Handle the case when a slot has a single timeout which gets
	// canceled before the timeout expires. In this case, the
	// slot's head is EMPTY but there is a value for next_tick. Not
	// resetting next_tick here causes the timer to get stuck in a
	// loop.
	if self.next == EMPTY {
	self.wheel[slot].next_tick = TICK_MAX;
	}
	} else {
	let slot = self.slot_for(self.tick);

	if curr == self.wheel[slot].head {
	self.wheel[slot].next_tick = TICK_MAX;
	}

	let links = self.entries[curr].links;

	if links.tick <= self.tick {
	trace!("triggering; token={:?}", curr);

	// Unlink will also advance self.next
	self.unlink(&links, curr);

	// Remove and return the token
	return self.entries.remove(curr)
	.map(\|e\| e.state);
	} else {
	let next_tick = self.wheel[slot].next_tick;
	self.wheel[slot].next_tick = cmp::min(next_tick, links.tick);
	self.next = links.next;
	}
	}
	}

	// No more timeouts to poll
	if let Some(inner) = self.inner.borrow() {
	trace!("unsetting readiness");
	let _ = inner.set_readiness.set_readiness(Ready::empty());

	if let Some(tick) = self.next_tick() {
	self.schedule_readiness(tick);
	}
	}

	None
	}

	fn unlink(&mut self, links: &EntryLinks, token: Token) {
	trace!("unlinking timeout; slot={}; token={:?}",
	self.slot_for(links.tick), token);

	if links.prev == EMPTY {
	let slot = self.slot_for(links.tick);
	self.wheel[slot].head = links.next;
	} else {
	self.entries[links.prev].links.next = links.next;
	}

	if links.next != EMPTY {
	self.entries[links.next].links.prev = links.prev;

	if token == self.next {
	self.next = links.next;
	}
	} else if token == self.next {
	self.next = EMPTY;
	}
	}

	fn schedule_readiness(&self, tick: Tick) {
	if let Some(inner) = self.inner.borrow() {
	// Coordinate setting readiness w/ the wakeup thread
	let mut curr = inner.wakeup_state.load(Ordering::Acquire);

	loop {
	if curr as Tick <= tick {
	// Nothing to do, wakeup is already scheduled
	return;
	}

	// Attempt to move the wakeup time forward
	trace!("advancing the wakeup time; target={}; curr={}", tick, curr);
	let actual = inner.wakeup_state.compare_and_swap(curr, tick as usize, Ordering::Release);

	if actual == curr {
	// Signal to the wakeup thread that the wakeup time has
	// been changed.
	trace!("unparking wakeup thread");
	inner.wakeup_thread.thread().unpark();
	return;
	}

	curr = actual;
	}
	}
	}

	// Next tick containing a timeout
	fn next_tick(&self) -> Option<Tick> {
	if self.next != EMPTY {
	let slot = self.slot_for(self.entries[self.next].links.tick);

	if self.wheel[slot].next_tick == self.tick {
	// There is data ready right now
	return Some(self.tick);
	}
	}

	self.wheel.iter().map(\|e\| e.next_tick).min()
	}

	fn slot_for(&self, tick: Tick) -> usize {
	(self.mask & tick) as usize
	}
	}

	impl<T> Default for Timer<T> {
	fn default() -> Timer<T> {
	Builder::default().build()
	}
	}

	impl<T> Evented for Timer<T> {
	fn register(&self, poll: &Poll, token: Token, interest: Ready, opts: PollOpt) -> io::Result<()> {
	if self.inner.borrow().is_some() {
	return Err(io::Error::new(io::ErrorKind::Other, "timer already registered"));
	}

	let (registration, set_readiness) = Registration::new(poll, token, interest, opts);
	let wakeup_state = Arc::new(AtomicUsize::new(usize::MAX));
	let thread_handle = spawn_wakeup_thread(
	wakeup_state.clone(),
	set_readiness.clone(),
	self.start, self.tick_ms);

	self.inner.fill(Inner {
	registration: registration,
	set_readiness: set_readiness,
	wakeup_state: wakeup_state,
	wakeup_thread: thread_handle,
	}).ok().expect("timer already registered");

	if let Some(next_tick) = self.next_tick() {
	self.schedule_readiness(next_tick);
	}

	Ok(())
	}

	fn reregister(&self, poll: &Poll, token: Token, interest: Ready, opts: PollOpt) -> io::Result<()> {
	match self.inner.borrow() {
	Some(inner) => inner.registration.update(poll, token, interest, opts),
	None => Err(io::Error::new(io::ErrorKind::Other, "receiver not registered")),
	}
	}

	fn deregister(&self, poll: &Poll) -> io::Result<()> {
	match self.inner.borrow() {
	Some(inner) => inner.registration.deregister(poll),
	None => Err(io::Error::new(io::ErrorKind::Other, "receiver not registered")),
	}
	}
	}

	impl fmt::Debug for Inner {
	fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
	fmt.debug_struct("Inner")
	.field("registration", &self.registration)
	.field("wakeup_state", &self.wakeup_state.load(Ordering::Relaxed))
	.finish()
	}
	}

	fn spawn_wakeup_thread(state: WakeupState, set_readiness: SetReadiness, start: Instant, tick_ms: u64) -> thread::JoinHandle<()> {
	thread::spawn(move \|\| {
	let mut sleep_until_tick = state.load(Ordering::Acquire) as Tick;

	loop {
	if sleep_until_tick == TERMINATE_THREAD as Tick {
	return;
	}

	let now_tick = current_tick(start, tick_ms);

	trace!("wakeup thread: sleep_until_tick={:?}; now_tick={:?}", sleep_until_tick, now_tick);

	if now_tick < sleep_until_tick {
	// Calling park_timeout with u64::MAX leads to undefined
	// behavior in pthread, causing the park to return immediately
	// and causing the thread to tightly spin. Instead of u64::MAX
	// on large values, simply use a blocking park.
	match tick_ms.checked_mul(sleep_until_tick - now_tick) {
	Some(sleep_duration) => {
	trace!("sleeping; tick_ms={}; now_tick={}; sleep_until_tick={}; duration={:?}",
	tick_ms, now_tick, sleep_until_tick, sleep_duration);
	thread::park_timeout(Duration::from_millis(sleep_duration));
	}
	None => {
	trace!("sleeping; tick_ms={}; now_tick={}; blocking sleep",
	tick_ms, now_tick);
	thread::park();
	}
	}
	sleep_until_tick = state.load(Ordering::Acquire) as Tick;
	} else {
	let actual = state.compare_and_swap(sleep_until_tick as usize, usize::MAX, Ordering::AcqRel) as Tick;

	if actual == sleep_until_tick {
	trace!("setting readiness from wakeup thread");
	let _ = set_readiness.set_readiness(Ready::readable());
	sleep_until_tick = usize::MAX as Tick;
	} else {
	sleep_until_tick = actual as Tick;
	}
	}
	}
	})
	}

	fn duration_to_tick(elapsed: Duration, tick_ms: u64) -> Tick {
	// Calculate tick rounding up to the closest one
	let elapsed_ms = convert::millis(elapsed);
	elapsed_ms.saturating_add(tick_ms / 2) / tick_ms
	}

	fn current_tick(start: Instant, tick_ms: u64) -> Tick {
	duration_to_tick(start.elapsed(), tick_ms)
	}

	impl<T> Entry<T> {
	fn new(state: T, tick: u64, next: Token) -> Entry<T> {
	Entry {
	state: state,
	links: EntryLinks {
	tick: tick,
	prev: EMPTY,
	next: next,
	},
	}
	}
	}

	impl fmt::Display for TimerError {
	fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
	write!(fmt, "{}: {}", self.kind, self.desc)
	}
	}

	impl TimerError {
	fn overflow() -> TimerError {
	TimerError {
	kind: TimerOverflow,
	desc: "too many timer entries"
	}
	}
	}

	impl error::Error for TimerError {
	fn description(&self) -> &str {
	self.desc
	}
	}

	impl fmt::Display for TimerErrorKind {
	fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
	match *self {
	TimerOverflow => write!(fmt, "TimerOverflow"),
	}
	}
	}