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use crate::sync::batch_semaphore::{Semaphore, TryAcquireError};
use crate::sync::mutex::TryLockError;
use std::cell::UnsafeCell;
use std::marker;
use std::marker::PhantomData;
use std::mem::ManuallyDrop;
use std::sync::Arc;
pub(crate) mod owned_read_guard;
pub(crate) mod owned_write_guard;
pub(crate) mod owned_write_guard_mapped;
pub(crate) mod read_guard;
pub(crate) mod write_guard;
pub(crate) mod write_guard_mapped;
pub(crate) use owned_read_guard::OwnedRwLockReadGuard;
pub(crate) use owned_write_guard::OwnedRwLockWriteGuard;
pub(crate) use owned_write_guard_mapped::OwnedRwLockMappedWriteGuard;
pub(crate) use read_guard::RwLockReadGuard;
pub(crate) use write_guard::RwLockWriteGuard;
pub(crate) use write_guard_mapped::RwLockMappedWriteGuard;
#[cfg(not(loom))]
const MAX_READS: u32 = std::u32::MAX >> 3;
#[cfg(loom)]
const MAX_READS: u32 = 10;
/// An asynchronous reader-writer lock.
///
/// This type of lock allows a number of readers or at most one writer at any
/// point in time. The write portion of this lock typically allows modification
/// of the underlying data (exclusive access) and the read portion of this lock
/// typically allows for read-only access (shared access).
///
/// In comparison, a [`Mutex`] does not distinguish between readers or writers
/// that acquire the lock, therefore causing any tasks waiting for the lock to
/// become available to yield. An `RwLock` will allow any number of readers to
/// acquire the lock as long as a writer is not holding the lock.
///
/// The priority policy of Tokio's read-write lock is _fair_ (or
/// [_write-preferring_]), in order to ensure that readers cannot starve
/// writers. Fairness is ensured using a first-in, first-out queue for the tasks
/// awaiting the lock; if a task that wishes to acquire the write lock is at the
/// head of the queue, read locks will not be given out until the write lock has
/// been released. This is in contrast to the Rust standard library's
/// `std::sync::RwLock`, where the priority policy is dependent on the
/// operating system's implementation.
///
/// The type parameter `T` represents the data that this lock protects. It is
/// required that `T` satisfies [`Send`] to be shared across threads. The RAII guards
/// returned from the locking methods implement [`Deref`](trait@std::ops::Deref)
/// (and [`DerefMut`](trait@std::ops::DerefMut)
/// for the `write` methods) to allow access to the content of the lock.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = RwLock::new(5);
///
/// // many reader locks can be held at once
/// {
/// let r1 = lock.read().await;
/// let r2 = lock.read().await;
/// assert_eq!(*r1, 5);
/// assert_eq!(*r2, 5);
/// } // read locks are dropped at this point
///
/// // only one write lock may be held, however
/// {
/// let mut w = lock.write().await;
/// *w += 1;
/// assert_eq!(*w, 6);
/// } // write lock is dropped here
/// }
/// ```
///
/// [`Mutex`]: struct@super::Mutex
/// [`RwLock`]: struct@RwLock
/// [`RwLockReadGuard`]: struct@RwLockReadGuard
/// [`RwLockWriteGuard`]: struct@RwLockWriteGuard
/// [`Send`]: trait@std::marker::Send
/// [_write-preferring_]: https://en.wikipedia.org/wiki/Readers%E2%80%93writer_lock#Priority_policies
#[derive(Debug)]
pub struct RwLock<T: ?Sized> {
// maximum number of concurrent readers
mr: u32,
//semaphore to coordinate read and write access to T
s: Semaphore,
//inner data T
c: UnsafeCell<T>,
}
#[test]
#[cfg(not(loom))]
fn bounds() {
fn check_send<T: Send>() {}
fn check_sync<T: Sync>() {}
fn check_unpin<T: Unpin>() {}
// This has to take a value, since the async fn's return type is unnameable.
fn check_send_sync_val<T: Send + Sync>(_t: T) {}
check_send::<RwLock<u32>>();
check_sync::<RwLock<u32>>();
check_unpin::<RwLock<u32>>();
check_send::<RwLockReadGuard<'_, u32>>();
check_sync::<RwLockReadGuard<'_, u32>>();
check_unpin::<RwLockReadGuard<'_, u32>>();
check_send::<OwnedRwLockReadGuard<u32, i32>>();
check_sync::<OwnedRwLockReadGuard<u32, i32>>();
check_unpin::<OwnedRwLockReadGuard<u32, i32>>();
check_send::<RwLockWriteGuard<'_, u32>>();
check_sync::<RwLockWriteGuard<'_, u32>>();
check_unpin::<RwLockWriteGuard<'_, u32>>();
check_send::<RwLockMappedWriteGuard<'_, u32>>();
check_sync::<RwLockMappedWriteGuard<'_, u32>>();
check_unpin::<RwLockMappedWriteGuard<'_, u32>>();
check_send::<OwnedRwLockWriteGuard<u32>>();
check_sync::<OwnedRwLockWriteGuard<u32>>();
check_unpin::<OwnedRwLockWriteGuard<u32>>();
check_send::<OwnedRwLockMappedWriteGuard<u32, i32>>();
check_sync::<OwnedRwLockMappedWriteGuard<u32, i32>>();
check_unpin::<OwnedRwLockMappedWriteGuard<u32, i32>>();
let rwlock = Arc::new(RwLock::new(0));
check_send_sync_val(rwlock.read());
check_send_sync_val(Arc::clone(&rwlock).read_owned());
check_send_sync_val(rwlock.write());
check_send_sync_val(Arc::clone(&rwlock).write_owned());
}
// As long as T: Send + Sync, it's fine to send and share RwLock<T> between threads.
// If T were not Send, sending and sharing a RwLock<T> would be bad, since you can access T through
// RwLock<T>.
unsafe impl<T> Send for RwLock<T> where T: ?Sized + Send {}
unsafe impl<T> Sync for RwLock<T> where T: ?Sized + Send + Sync {}
// NB: These impls need to be explicit since we're storing a raw pointer.
// Safety: Stores a raw pointer to `T`, so if `T` is `Sync`, the lock guard over
// `T` is `Send`.
unsafe impl<T> Send for RwLockReadGuard<'_, T> where T: ?Sized + Sync {}
unsafe impl<T> Sync for RwLockReadGuard<'_, T> where T: ?Sized + Send + Sync {}
// T is required to be `Send` because an OwnedRwLockReadGuard can be used to drop the value held in
// the RwLock, unlike RwLockReadGuard.
unsafe impl<T, U> Send for OwnedRwLockReadGuard<T, U>
where
T: ?Sized + Send + Sync,
U: ?Sized + Sync,
{
}
unsafe impl<T, U> Sync for OwnedRwLockReadGuard<T, U>
where
T: ?Sized + Send + Sync,
U: ?Sized + Send + Sync,
{
}
unsafe impl<T> Sync for RwLockWriteGuard<'_, T> where T: ?Sized + Send + Sync {}
unsafe impl<T> Sync for OwnedRwLockWriteGuard<T> where T: ?Sized + Send + Sync {}
unsafe impl<T> Sync for RwLockMappedWriteGuard<'_, T> where T: ?Sized + Send + Sync {}
unsafe impl<T, U> Sync for OwnedRwLockMappedWriteGuard<T, U>
where
T: ?Sized + Send + Sync,
U: ?Sized + Send + Sync,
{
}
// Safety: Stores a raw pointer to `T`, so if `T` is `Sync`, the lock guard over
// `T` is `Send` - but since this is also provides mutable access, we need to
// make sure that `T` is `Send` since its value can be sent across thread
// boundaries.
unsafe impl<T> Send for RwLockWriteGuard<'_, T> where T: ?Sized + Send + Sync {}
unsafe impl<T> Send for OwnedRwLockWriteGuard<T> where T: ?Sized + Send + Sync {}
unsafe impl<T> Send for RwLockMappedWriteGuard<'_, T> where T: ?Sized + Send + Sync {}
unsafe impl<T, U> Send for OwnedRwLockMappedWriteGuard<T, U>
where
T: ?Sized + Send + Sync,
U: ?Sized + Send + Sync,
{
}
impl<T: ?Sized> RwLock<T> {
/// Creates a new instance of an `RwLock<T>` which is unlocked.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// let lock = RwLock::new(5);
/// ```
pub fn new(value: T) -> RwLock<T>
where
T: Sized,
{
RwLock {
mr: MAX_READS,
c: UnsafeCell::new(value),
s: Semaphore::new(MAX_READS as usize),
}
}
/// Creates a new instance of an `RwLock<T>` which is unlocked
/// and allows a maximum of `max_reads` concurrent readers.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// let lock = RwLock::with_max_readers(5, 1024);
/// ```
///
/// # Panics
///
/// Panics if `max_reads` is more than `u32::MAX >> 3`.
pub fn with_max_readers(value: T, max_reads: u32) -> RwLock<T>
where
T: Sized,
{
assert!(
max_reads <= MAX_READS,
"a RwLock may not be created with more than {} readers",
MAX_READS
);
RwLock {
mr: max_reads,
c: UnsafeCell::new(value),
s: Semaphore::new(max_reads as usize),
}
}
/// Creates a new instance of an `RwLock<T>` which is unlocked.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// static LOCK: RwLock<i32> = RwLock::const_new(5);
/// ```
#[cfg(all(feature = "parking_lot", not(all(loom, test))))]
#[cfg_attr(docsrs, doc(cfg(feature = "parking_lot")))]
pub const fn const_new(value: T) -> RwLock<T>
where
T: Sized,
{
RwLock {
mr: MAX_READS,
c: UnsafeCell::new(value),
s: Semaphore::const_new(MAX_READS as usize),
}
}
/// Creates a new instance of an `RwLock<T>` which is unlocked
/// and allows a maximum of `max_reads` concurrent readers.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// static LOCK: RwLock<i32> = RwLock::const_with_max_readers(5, 1024);
/// ```
#[cfg(all(feature = "parking_lot", not(all(loom, test))))]
#[cfg_attr(docsrs, doc(cfg(feature = "parking_lot")))]
pub const fn const_with_max_readers(value: T, mut max_reads: u32) -> RwLock<T>
where
T: Sized,
{
max_reads &= MAX_READS;
RwLock {
mr: max_reads,
c: UnsafeCell::new(value),
s: Semaphore::const_new(max_reads as usize),
}
}
/// Locks this `RwLock` with shared read access, causing the current task
/// to yield until the lock has been acquired.
///
/// The calling task will yield until there are no writers which hold the
/// lock. There may be other readers inside the lock when the task resumes.
///
/// Note that under the priority policy of [`RwLock`], read locks are not
/// granted until prior write locks, to prevent starvation. Therefore
/// deadlock may occur if a read lock is held by the current task, a write
/// lock attempt is made, and then a subsequent read lock attempt is made
/// by the current task.
///
/// Returns an RAII guard which will drop this read access of the `RwLock`
/// when dropped.
///
/// # Cancel safety
///
/// This method uses a queue to fairly distribute locks in the order they
/// were requested. Cancelling a call to `read` makes you lose your place in
/// the queue.
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = Arc::new(RwLock::new(1));
/// let c_lock = lock.clone();
///
/// let n = lock.read().await;
/// assert_eq!(*n, 1);
///
/// tokio::spawn(async move {
/// // While main has an active read lock, we acquire one too.
/// let r = c_lock.read().await;
/// assert_eq!(*r, 1);
/// }).await.expect("The spawned task has panicked");
///
/// // Drop the guard after the spawned task finishes.
/// drop(n);
///}
/// ```
pub async fn read(&self) -> RwLockReadGuard<'_, T> {
self.s.acquire(1).await.unwrap_or_else(|_| {
// The semaphore was closed. but, we never explicitly close it, and we have a
// handle to it through the Arc, which means that this can never happen.
unreachable!()
});
RwLockReadGuard {
s: &self.s,
data: self.c.get(),
marker: marker::PhantomData,
}
}
/// Locks this `RwLock` with shared read access, causing the current task
/// to yield until the lock has been acquired.
///
/// The calling task will yield until there are no writers which hold the
/// lock. There may be other readers inside the lock when the task resumes.
///
/// This method is identical to [`RwLock::read`], except that the returned
/// guard references the `RwLock` with an [`Arc`] rather than by borrowing
/// it. Therefore, the `RwLock` must be wrapped in an `Arc` to call this
/// method, and the guard will live for the `'static` lifetime, as it keeps
/// the `RwLock` alive by holding an `Arc`.
///
/// Note that under the priority policy of [`RwLock`], read locks are not
/// granted until prior write locks, to prevent starvation. Therefore
/// deadlock may occur if a read lock is held by the current task, a write
/// lock attempt is made, and then a subsequent read lock attempt is made
/// by the current task.
///
/// Returns an RAII guard which will drop this read access of the `RwLock`
/// when dropped.
///
/// # Cancel safety
///
/// This method uses a queue to fairly distribute locks in the order they
/// were requested. Cancelling a call to `read_owned` makes you lose your
/// place in the queue.
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = Arc::new(RwLock::new(1));
/// let c_lock = lock.clone();
///
/// let n = lock.read_owned().await;
/// assert_eq!(*n, 1);
///
/// tokio::spawn(async move {
/// // While main has an active read lock, we acquire one too.
/// let r = c_lock.read_owned().await;
/// assert_eq!(*r, 1);
/// }).await.expect("The spawned task has panicked");
///
/// // Drop the guard after the spawned task finishes.
/// drop(n);
///}
/// ```
pub async fn read_owned(self: Arc<Self>) -> OwnedRwLockReadGuard<T> {
self.s.acquire(1).await.unwrap_or_else(|_| {
// The semaphore was closed. but, we never explicitly close it, and we have a
// handle to it through the Arc, which means that this can never happen.
unreachable!()
});
OwnedRwLockReadGuard {
data: self.c.get(),
lock: ManuallyDrop::new(self),
_p: PhantomData,
}
}
/// Attempts to acquire this `RwLock` with shared read access.
///
/// If the access couldn't be acquired immediately, returns [`TryLockError`].
/// Otherwise, an RAII guard is returned which will release read access
/// when dropped.
///
/// [`TryLockError`]: TryLockError
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = Arc::new(RwLock::new(1));
/// let c_lock = lock.clone();
///
/// let v = lock.try_read().unwrap();
/// assert_eq!(*v, 1);
///
/// tokio::spawn(async move {
/// // While main has an active read lock, we acquire one too.
/// let n = c_lock.read().await;
/// assert_eq!(*n, 1);
/// }).await.expect("The spawned task has panicked");
///
/// // Drop the guard when spawned task finishes.
/// drop(v);
/// }
/// ```
pub fn try_read(&self) -> Result<RwLockReadGuard<'_, T>, TryLockError> {
match self.s.try_acquire(1) {
Ok(permit) => permit,
Err(TryAcquireError::NoPermits) => return Err(TryLockError(())),
Err(TryAcquireError::Closed) => unreachable!(),
}
Ok(RwLockReadGuard {
s: &self.s,
data: self.c.get(),
marker: marker::PhantomData,
})
}
/// Attempts to acquire this `RwLock` with shared read access.
///
/// If the access couldn't be acquired immediately, returns [`TryLockError`].
/// Otherwise, an RAII guard is returned which will release read access
/// when dropped.
///
/// This method is identical to [`RwLock::try_read`], except that the
/// returned guard references the `RwLock` with an [`Arc`] rather than by
/// borrowing it. Therefore, the `RwLock` must be wrapped in an `Arc` to
/// call this method, and the guard will live for the `'static` lifetime,
/// as it keeps the `RwLock` alive by holding an `Arc`.
///
/// [`TryLockError`]: TryLockError
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = Arc::new(RwLock::new(1));
/// let c_lock = lock.clone();
///
/// let v = lock.try_read_owned().unwrap();
/// assert_eq!(*v, 1);
///
/// tokio::spawn(async move {
/// // While main has an active read lock, we acquire one too.
/// let n = c_lock.read_owned().await;
/// assert_eq!(*n, 1);
/// }).await.expect("The spawned task has panicked");
///
/// // Drop the guard when spawned task finishes.
/// drop(v);
/// }
/// ```
pub fn try_read_owned(self: Arc<Self>) -> Result<OwnedRwLockReadGuard<T>, TryLockError> {
match self.s.try_acquire(1) {
Ok(permit) => permit,
Err(TryAcquireError::NoPermits) => return Err(TryLockError(())),
Err(TryAcquireError::Closed) => unreachable!(),
}
Ok(OwnedRwLockReadGuard {
data: self.c.get(),
lock: ManuallyDrop::new(self),
_p: PhantomData,
})
}
/// Locks this `RwLock` with exclusive write access, causing the current
/// task to yield until the lock has been acquired.
///
/// The calling task will yield while other writers or readers currently
/// have access to the lock.
///
/// Returns an RAII guard which will drop the write access of this `RwLock`
/// when dropped.
///
/// # Cancel safety
///
/// This method uses a queue to fairly distribute locks in the order they
/// were requested. Cancelling a call to `write` makes you lose your place
/// in the queue.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = RwLock::new(1);
///
/// let mut n = lock.write().await;
/// *n = 2;
///}
/// ```
pub async fn write(&self) -> RwLockWriteGuard<'_, T> {
self.s.acquire(self.mr).await.unwrap_or_else(|_| {
// The semaphore was closed. but, we never explicitly close it, and we have a
// handle to it through the Arc, which means that this can never happen.
unreachable!()
});
RwLockWriteGuard {
permits_acquired: self.mr,
s: &self.s,
data: self.c.get(),
marker: marker::PhantomData,
}
}
/// Locks this `RwLock` with exclusive write access, causing the current
/// task to yield until the lock has been acquired.
///
/// The calling task will yield while other writers or readers currently
/// have access to the lock.
///
/// This method is identical to [`RwLock::write`], except that the returned
/// guard references the `RwLock` with an [`Arc`] rather than by borrowing
/// it. Therefore, the `RwLock` must be wrapped in an `Arc` to call this
/// method, and the guard will live for the `'static` lifetime, as it keeps
/// the `RwLock` alive by holding an `Arc`.
///
/// Returns an RAII guard which will drop the write access of this `RwLock`
/// when dropped.
///
/// # Cancel safety
///
/// This method uses a queue to fairly distribute locks in the order they
/// were requested. Cancelling a call to `write_owned` makes you lose your
/// place in the queue.
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let lock = Arc::new(RwLock::new(1));
///
/// let mut n = lock.write_owned().await;
/// *n = 2;
///}
/// ```
pub async fn write_owned(self: Arc<Self>) -> OwnedRwLockWriteGuard<T> {
self.s.acquire(self.mr).await.unwrap_or_else(|_| {
// The semaphore was closed. but, we never explicitly close it, and we have a
// handle to it through the Arc, which means that this can never happen.
unreachable!()
});
OwnedRwLockWriteGuard {
permits_acquired: self.mr,
data: self.c.get(),
lock: ManuallyDrop::new(self),
_p: PhantomData,
}
}
/// Attempts to acquire this `RwLock` with exclusive write access.
///
/// If the access couldn't be acquired immediately, returns [`TryLockError`].
/// Otherwise, an RAII guard is returned which will release write access
/// when dropped.
///
/// [`TryLockError`]: TryLockError
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let rw = RwLock::new(1);
///
/// let v = rw.read().await;
/// assert_eq!(*v, 1);
///
/// assert!(rw.try_write().is_err());
/// }
/// ```
pub fn try_write(&self) -> Result<RwLockWriteGuard<'_, T>, TryLockError> {
match self.s.try_acquire(self.mr) {
Ok(permit) => permit,
Err(TryAcquireError::NoPermits) => return Err(TryLockError(())),
Err(TryAcquireError::Closed) => unreachable!(),
}
Ok(RwLockWriteGuard {
permits_acquired: self.mr,
s: &self.s,
data: self.c.get(),
marker: marker::PhantomData,
})
}
/// Attempts to acquire this `RwLock` with exclusive write access.
///
/// If the access couldn't be acquired immediately, returns [`TryLockError`].
/// Otherwise, an RAII guard is returned which will release write access
/// when dropped.
///
/// This method is identical to [`RwLock::try_write`], except that the
/// returned guard references the `RwLock` with an [`Arc`] rather than by
/// borrowing it. Therefore, the `RwLock` must be wrapped in an `Arc` to
/// call this method, and the guard will live for the `'static` lifetime,
/// as it keeps the `RwLock` alive by holding an `Arc`.
///
/// [`TryLockError`]: TryLockError
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use tokio::sync::RwLock;
///
/// #[tokio::main]
/// async fn main() {
/// let rw = Arc::new(RwLock::new(1));
///
/// let v = Arc::clone(&rw).read_owned().await;
/// assert_eq!(*v, 1);
///
/// assert!(rw.try_write_owned().is_err());
/// }
/// ```
pub fn try_write_owned(self: Arc<Self>) -> Result<OwnedRwLockWriteGuard<T>, TryLockError> {
match self.s.try_acquire(self.mr) {
Ok(permit) => permit,
Err(TryAcquireError::NoPermits) => return Err(TryLockError(())),
Err(TryAcquireError::Closed) => unreachable!(),
}
Ok(OwnedRwLockWriteGuard {
permits_acquired: self.mr,
data: self.c.get(),
lock: ManuallyDrop::new(self),
_p: PhantomData,
})
}
/// Returns a mutable reference to the underlying data.
///
/// Since this call borrows the `RwLock` mutably, no actual locking needs to
/// take place -- the mutable borrow statically guarantees no locks exist.
///
/// # Examples
///
/// ```
/// use tokio::sync::RwLock;
///
/// fn main() {
/// let mut lock = RwLock::new(1);
///
/// let n = lock.get_mut();
/// *n = 2;
/// }
/// ```
pub fn get_mut(&mut self) -> &mut T {
unsafe {
// Safety: This is https://github.com/rust-lang/rust/pull/76936
&mut *self.c.get()
}
}
/// Consumes the lock, returning the underlying data.
pub fn into_inner(self) -> T
where
T: Sized,
{
self.c.into_inner()
}
}
impl<T> From<T> for RwLock<T> {
fn from(s: T) -> Self {
Self::new(s)
}
}
impl<T: ?Sized> Default for RwLock<T>
where
T: Default,
{
fn default() -> Self {
Self::new(T::default())
}
}