use std::{ cell::UnsafeCell, panic::{RefUnwindSafe, UnwindSafe}, sync::atomic::{AtomicU8, Ordering}, }; pub(crate) struct OnceCell { state: AtomicU8, value: UnsafeCell>, } const INCOMPLETE: u8 = 0x0; const RUNNING: u8 = 0x1; const COMPLETE: u8 = 0x2; // Why do we need `T: Send`? // Thread A creates a `OnceCell` and shares it with // scoped thread B, which fills the cell, which is // then destroyed by A. That is, destructor observes // a sent value. unsafe impl Sync for OnceCell {} unsafe impl Send for OnceCell {} impl RefUnwindSafe for OnceCell {} impl UnwindSafe for OnceCell {} impl OnceCell { pub(crate) const fn new() -> OnceCell { OnceCell { state: AtomicU8::new(INCOMPLETE), value: UnsafeCell::new(None) } } pub(crate) const fn with_value(value: T) -> OnceCell { OnceCell { state: AtomicU8::new(COMPLETE), value: UnsafeCell::new(Some(value)) } } /// Safety: synchronizes with store to value via Release/Acquire. #[inline] pub(crate) fn is_initialized(&self) -> bool { self.state.load(Ordering::Acquire) == COMPLETE } /// Safety: synchronizes with store to value via `is_initialized` or mutex /// lock/unlock, writes value only once because of the mutex. #[cold] pub(crate) fn initialize(&self, f: F) -> Result<(), E> where F: FnOnce() -> Result, { let mut f = Some(f); let mut res: Result<(), E> = Ok(()); let slot: *mut Option = self.value.get(); initialize_inner(&self.state, &mut || { // We are calling user-supplied function and need to be careful. // - if it returns Err, we unlock mutex and return without touching anything // - if it panics, we unlock mutex and propagate panic without touching anything // - if it calls `set` or `get_or_try_init` re-entrantly, we get a deadlock on // mutex, which is important for safety. We *could* detect this and panic, // but that is more complicated // - finally, if it returns Ok, we store the value and store the flag with // `Release`, which synchronizes with `Acquire`s. let f = unsafe { crate::unwrap_unchecked(f.take()) }; match f() { Ok(value) => unsafe { // Safe b/c we have a unique access and no panic may happen // until the cell is marked as initialized. debug_assert!((*slot).is_none()); *slot = Some(value); true }, Err(err) => { res = Err(err); false } } }); res } #[cold] pub(crate) fn wait(&self) { let key = &self.state as *const _ as usize; unsafe { parking_lot_core::park( key, || self.state.load(Ordering::Acquire) != COMPLETE, || (), |_, _| (), parking_lot_core::DEFAULT_PARK_TOKEN, None, ); } } /// Get the reference to the underlying value, without checking if the cell /// is initialized. /// /// # Safety /// /// Caller must ensure that the cell is in initialized state, and that /// the contents are acquired by (synchronized to) this thread. pub(crate) unsafe fn get_unchecked(&self) -> &T { debug_assert!(self.is_initialized()); let slot = &*self.value.get(); crate::unwrap_unchecked(slot.as_ref()) } /// Gets the mutable reference to the underlying value. /// Returns `None` if the cell is empty. pub(crate) fn get_mut(&mut self) -> Option<&mut T> { // Safe b/c we have an exclusive access let slot: &mut Option = unsafe { &mut *self.value.get() }; slot.as_mut() } /// Consumes this `OnceCell`, returning the wrapped value. /// Returns `None` if the cell was empty. pub(crate) fn into_inner(self) -> Option { self.value.into_inner() } } struct Guard<'a> { state: &'a AtomicU8, new_state: u8, } impl<'a> Drop for Guard<'a> { fn drop(&mut self) { self.state.store(self.new_state, Ordering::Release); unsafe { let key = self.state as *const AtomicU8 as usize; parking_lot_core::unpark_all(key, parking_lot_core::DEFAULT_UNPARK_TOKEN); } } } // Note: this is intentionally monomorphic #[inline(never)] fn initialize_inner(state: &AtomicU8, init: &mut dyn FnMut() -> bool) { loop { let exchange = state.compare_exchange_weak(INCOMPLETE, RUNNING, Ordering::Acquire, Ordering::Acquire); match exchange { Ok(_) => { let mut guard = Guard { state, new_state: INCOMPLETE }; if init() { guard.new_state = COMPLETE; } return; } Err(COMPLETE) => return, Err(RUNNING) => unsafe { let key = state as *const AtomicU8 as usize; parking_lot_core::park( key, || state.load(Ordering::Relaxed) == RUNNING, || (), |_, _| (), parking_lot_core::DEFAULT_PARK_TOKEN, None, ); }, Err(INCOMPLETE) => (), Err(_) => debug_assert!(false), } } } #[test] fn test_size() { use std::mem::size_of; assert_eq!(size_of::>(), 1 * size_of::() + size_of::()); }