//! The global epoch //! //! The last bit in this number is unused and is always zero. Every so often the global epoch is //! incremented, i.e. we say it "advances". A pinned participant may advance the global epoch only //! if all currently pinned participants have been pinned in the current epoch. //! //! If an object became garbage in some epoch, then we can be sure that after two advancements no //! participant will hold a reference to it. That is the crux of safe memory reclamation. use crate::primitive::sync::atomic::{AtomicUsize, Ordering}; /// An epoch that can be marked as pinned or unpinned. /// /// Internally, the epoch is represented as an integer that wraps around at some unspecified point /// and a flag that represents whether it is pinned or unpinned. #[derive(Copy, Clone, Default, Debug, Eq, PartialEq)] pub(crate) struct Epoch { /// The least significant bit is set if pinned. The rest of the bits hold the epoch. data: usize, } impl Epoch { /// Returns the starting epoch in unpinned state. #[inline] pub(crate) fn starting() -> Self { Self::default() } /// Returns the number of epochs `self` is ahead of `rhs`. /// /// Internally, epochs are represented as numbers in the range `(isize::MIN / 2) .. (isize::MAX /// / 2)`, so the returned distance will be in the same interval. pub(crate) fn wrapping_sub(self, rhs: Self) -> isize { // The result is the same with `(self.data & !1).wrapping_sub(rhs.data & !1) as isize >> 1`, // because the possible difference of LSB in `(self.data & !1).wrapping_sub(rhs.data & !1)` // will be ignored in the shift operation. self.data.wrapping_sub(rhs.data & !1) as isize >> 1 } /// Returns `true` if the epoch is marked as pinned. #[inline] pub(crate) fn is_pinned(self) -> bool { (self.data & 1) == 1 } /// Returns the same epoch, but marked as pinned. #[inline] pub(crate) fn pinned(self) -> Epoch { Epoch { data: self.data | 1, } } /// Returns the same epoch, but marked as unpinned. #[inline] pub(crate) fn unpinned(self) -> Epoch { Epoch { data: self.data & !1, } } /// Returns the successor epoch. /// /// The returned epoch will be marked as pinned only if the previous one was as well. #[inline] pub(crate) fn successor(self) -> Epoch { Epoch { data: self.data.wrapping_add(2), } } } /// An atomic value that holds an `Epoch`. #[derive(Default, Debug)] pub(crate) struct AtomicEpoch { /// Since `Epoch` is just a wrapper around `usize`, an `AtomicEpoch` is similarly represented /// using an `AtomicUsize`. data: AtomicUsize, } impl AtomicEpoch { /// Creates a new atomic epoch. #[inline] pub(crate) fn new(epoch: Epoch) -> Self { let data = AtomicUsize::new(epoch.data); AtomicEpoch { data } } /// Loads a value from the atomic epoch. #[inline] pub(crate) fn load(&self, ord: Ordering) -> Epoch { Epoch { data: self.data.load(ord), } } /// Stores a value into the atomic epoch. #[inline] pub(crate) fn store(&self, epoch: Epoch, ord: Ordering) { self.data.store(epoch.data, ord); } /// Stores a value into the atomic epoch if the current value is the same as `current`. /// /// The return value is a result indicating whether the new value was written and containing /// the previous value. On success this value is guaranteed to be equal to `current`. /// /// This method takes two `Ordering` arguments to describe the memory /// ordering of this operation. `success` describes the required ordering for the /// read-modify-write operation that takes place if the comparison with `current` succeeds. /// `failure` describes the required ordering for the load operation that takes place when /// the comparison fails. Using `Acquire` as success ordering makes the store part /// of this operation `Relaxed`, and using `Release` makes the successful load /// `Relaxed`. The failure ordering can only be `SeqCst`, `Acquire` or `Relaxed` /// and must be equivalent to or weaker than the success ordering. #[inline] pub(crate) fn compare_exchange( &self, current: Epoch, new: Epoch, success: Ordering, failure: Ordering, ) -> Result { match self .data .compare_exchange(current.data, new.data, success, failure) { Ok(data) => Ok(Epoch { data }), Err(data) => Err(Epoch { data }), } } }