use std::cell::UnsafeCell;
use std::marker::PhantomData;
use lock_api::RawRwLock;
use crate::poisonable::PoisonFlag;
use crate::ThreadKey;
mod rwlock;
mod read_lock;
mod write_lock;
mod read_guard;
mod write_guard;
#[cfg(feature = "spin")]
pub type SpinRwLock<T> = RwLock<T, spin::RwLock<()>>;
#[cfg(feature = "parking_lot")]
pub type ParkingRwLock<T> = RwLock<T, parking_lot::RawRwLock>;
/// A 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 blocking any threads waiting for the lock
/// to become available. An `RwLock` will allow any number of readers to
/// acquire the lock as long as a writer is not holding the lock.
///
/// The type parameter T represents the data that this lock protects. It is
/// required that T satisfies [`Send`] to be shared across threads and [`Sync`]
/// to allow concurrent access through readers. The RAII guard returned from
/// the locking methods implement [`Deref`] (and [`DerefMut`] for the `write`
/// methods) to allow access to the content of the lock.
///
/// Locking the mutex on a thread that already locked it is impossible, due to
/// the requirement of the [`ThreadKey`]. Therefore, this will never deadlock.
///
/// [`ThreadKey`]: `crate::ThreadKey`
/// [`Mutex`]: `crate::mutex::Mutex`
/// [`Deref`]: `std::ops::Deref`
/// [`DerefMut`]: `std::ops::DerefMut`
pub struct RwLock<T: ?Sized, R> {
raw: R,
poison: PoisonFlag,
data: UnsafeCell<T>,
}
/// Grants read access to an [`RwLock`]
///
/// This structure is designed to be used in a [`LockCollection`] to indicate
/// that only read access is needed to the data.
///
/// [`LockCollection`]: `crate::LockCollection`
#[repr(transparent)]
struct ReadLock<'l, T: ?Sized, R>(&'l RwLock<T, R>);
/// Grants write access to an [`RwLock`]
///
/// This structure is designed to be used in a [`LockCollection`] to indicate
/// that write access is needed to the data.
///
/// [`LockCollection`]: `crate::LockCollection`
#[repr(transparent)]
struct WriteLock<'l, T: ?Sized, R>(&'l RwLock<T, R>);
/// RAII structure that unlocks the shared read access to a [`RwLock`]
///
/// This is similar to [`RwLockReadRef`], except it does not hold a
/// [`Keyable`].
pub struct RwLockReadRef<'a, T: ?Sized, R: RawRwLock>(
&'a RwLock<T, R>,
PhantomData<R::GuardMarker>,
);
/// RAII structure that unlocks the exclusive write access to a [`RwLock`]
///
/// This is similar to [`RwLockWriteRef`], except it does not hold a
/// [`Keyable`].
pub struct RwLockWriteRef<'a, T: ?Sized, R: RawRwLock>(
&'a RwLock<T, R>,
PhantomData<R::GuardMarker>,
);
/// RAII structure used to release the shared read access of a lock when
/// dropped.
///
/// This structure is created by the [`read`] and [`try_read`] methods on
/// [`RwLock`].
///
/// [`read`]: `RwLock::read`
/// [`try_read`]: `RwLock::try_read`
pub struct RwLockReadGuard<'a, T: ?Sized, R: RawRwLock> {
rwlock: RwLockReadRef<'a, T, R>,
thread_key: ThreadKey,
}
/// RAII structure used to release the exclusive write access of a lock when
/// dropped.
///
/// This structure is created by the [`write`] and [`try_write`] methods on
/// [`RwLock`]
///
/// [`try_write`]: `RwLock::try_write`
pub struct RwLockWriteGuard<'a, T: ?Sized, R: RawRwLock> {
rwlock: RwLockWriteRef<'a, T, R>,
thread_key: ThreadKey,
}
#[cfg(test)]
mod tests {
use crate::lockable::Lockable;
use crate::lockable::RawLock;
use crate::LockCollection;
use crate::RwLock;
use crate::ThreadKey;
use super::*;
#[test]
fn unlocked_when_initialized() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
assert!(!lock.is_locked());
assert!(lock.try_write(key).is_ok());
}
#[test]
fn read_lock_unlocked_when_initialized() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let reader = ReadLock::new(&lock);
assert!(reader.try_lock(key).is_ok());
}
#[test]
fn read_lock_from_works() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::from("Hello, world!");
let reader = ReadLock::from(&lock);
let guard = reader.lock(key);
assert_eq!(*guard, "Hello, world!");
}
#[test]
fn read_lock_scoped_works() {
let mut key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new(42);
let reader = ReadLock::new(&lock);
reader.scoped_lock(&mut key, |num| assert_eq!(*num, 42));
}
#[test]
fn read_lock_scoped_try_fails_during_write() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new(42);
let reader = ReadLock::new(&lock);
let guard = lock.write(key);
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let r = reader.scoped_try_lock(key, |_| {});
assert!(r.is_err());
});
});
drop(guard);
}
#[test]
fn write_lock_unlocked_when_initialized() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let writer = WriteLock::new(&lock);
assert!(writer.try_lock(key).is_ok());
}
#[test]
#[ignore = "We've removed ReadLock"]
fn read_lock_get_ptrs() {
let rwlock = RwLock::new(5);
let readlock = ReadLock::new(&rwlock);
let mut lock_ptrs = Vec::new();
readlock.get_ptrs(&mut lock_ptrs);
assert_eq!(lock_ptrs.len(), 1);
assert!(std::ptr::addr_eq(lock_ptrs[0], &readlock));
}
#[test]
#[ignore = "We've removed WriteLock"]
fn write_lock_get_ptrs() {
let rwlock = RwLock::new(5);
let writelock = WriteLock::new(&rwlock);
let mut lock_ptrs = Vec::new();
writelock.get_ptrs(&mut lock_ptrs);
assert_eq!(lock_ptrs.len(), 1);
assert!(std::ptr::addr_eq(lock_ptrs[0], &writelock));
}
#[test]
fn write_lock_scoped_works() {
let mut key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new(42);
let writer = WriteLock::new(&lock);
writer.scoped_lock(&mut key, |num| assert_eq!(*num, 42));
}
#[test]
fn write_lock_scoped_try_fails_during_write() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new(42);
let writer = WriteLock::new(&lock);
let guard = lock.write(key);
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let r = writer.scoped_try_lock(key, |_| {});
assert!(r.is_err());
});
});
drop(guard);
}
#[test]
fn locked_after_read() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = lock.read(key);
assert!(lock.is_locked());
drop(guard)
}
#[test]
fn locked_after_using_read_lock() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let reader = ReadLock::new(&lock);
let guard = reader.lock(key);
assert!(lock.is_locked());
drop(guard)
}
#[test]
fn locked_after_write() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = lock.write(key);
assert!(lock.is_locked());
drop(guard)
}
#[test]
fn locked_after_using_write_lock() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let writer = WriteLock::new(&lock);
let guard = writer.lock(key);
assert!(lock.is_locked());
drop(guard)
}
#[test]
fn locked_after_scoped_write() {
let mut key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello, world!");
lock.scoped_write(&mut key, |guard| {
assert!(lock.is_locked());
assert_eq!(*guard, "Hello, world!");
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
assert!(lock.try_read(key).is_err());
});
})
})
}
#[test]
fn get_mut_works() {
let key = ThreadKey::get().unwrap();
let mut lock = crate::RwLock::from(42);
let mut_ref = lock.get_mut();
*mut_ref = 24;
lock.scoped_read(key, |guard| assert_eq!(*guard, 24))
}
#[test]
fn try_write_can_fail() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello");
let guard = lock.write(key);
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let r = lock.try_write(key);
assert!(r.is_err());
});
});
drop(guard);
}
#[test]
fn try_read_can_fail() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello");
let guard = lock.write(key);
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let r = lock.try_read(key);
assert!(r.is_err());
});
});
drop(guard);
}
#[test]
fn read_display_works() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = lock.read(key);
assert_eq!(guard.to_string(), "Hello, world!".to_string());
}
#[test]
fn write_display_works() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = lock.write(key);
assert_eq!(guard.to_string(), "Hello, world!".to_string());
}
#[test]
fn read_ref_display_works() {
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = unsafe { lock.try_read_no_key().unwrap() };
assert_eq!(guard.to_string(), "Hello, world!".to_string());
}
#[test]
fn write_ref_display_works() {
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = unsafe { lock.try_write_no_key().unwrap() };
assert_eq!(guard.to_string(), "Hello, world!".to_string());
}
#[test]
fn dropping_read_ref_releases_rwlock() {
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = unsafe { lock.try_read_no_key().unwrap() };
drop(guard);
assert!(!lock.is_locked());
}
#[test]
fn dropping_write_guard_releases_rwlock() {
let key = ThreadKey::get().unwrap();
let lock: crate::RwLock<_> = RwLock::new("Hello, world!");
let guard = lock.write(key);
drop(guard);
assert!(!lock.is_locked());
}
#[test]
fn unlock_write() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello, world");
let mut guard = lock.write(key);
*guard = "Goodbye, world!";
let key = RwLock::unlock_write(guard);
let guard = lock.read(key);
assert_eq!(*guard, "Goodbye, world!");
}
#[test]
fn unlock_read() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello, world");
let guard = lock.read(key);
assert_eq!(*guard, "Hello, world");
let key = RwLock::unlock_read(guard);
let guard = lock.write(key);
assert_eq!(*guard, "Hello, world");
}
#[test]
fn unlock_read_lock() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello, world");
let reader = ReadLock::new(&lock);
let guard = reader.lock(key);
let key = ReadLock::unlock(guard);
lock.write(key);
}
#[test]
fn unlock_write_lock() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("Hello, world");
let writer = WriteLock::from(&lock);
let guard = writer.lock(key);
let key = WriteLock::unlock(guard);
lock.write(key);
}
#[test]
#[ignore = "We've removed ReadLock"]
fn read_lock_in_collection() {
let mut key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("hi");
let collection = LockCollection::try_new(ReadLock::new(&lock)).unwrap();
collection.scoped_lock(&mut key, |guard| {
assert_eq!(*guard, "hi");
});
collection.scoped_read(&mut key, |guard| {
assert_eq!(*guard, "hi");
});
assert!(collection
.scoped_try_lock(&mut key, |guard| {
assert_eq!(*guard, "hi");
})
.is_ok());
assert!(collection
.scoped_try_read(&mut key, |guard| {
assert_eq!(*guard, "hi");
})
.is_ok());
let guard = collection.lock(key);
assert_eq!(**guard, "hi");
let key = LockCollection::<ReadLock<_, _>>::unlock(guard);
let guard = collection.read(key);
assert_eq!(**guard, "hi");
let key = LockCollection::<ReadLock<_, _>>::unlock(guard);
let guard = lock.write(key);
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let guard = collection.try_lock(key);
assert!(guard.is_err());
});
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let guard = collection.try_read(key);
assert!(guard.is_err());
});
});
drop(guard);
}
#[test]
fn write_lock_in_collection() {
let mut key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("hi");
let collection = LockCollection::try_new(WriteLock::new(&lock)).unwrap();
collection.scoped_lock(&mut key, |guard| {
assert_eq!(*guard, "hi");
});
assert!(collection
.scoped_try_lock(&mut key, |guard| {
assert_eq!(*guard, "hi");
})
.is_ok());
let guard = collection.lock(key);
assert_eq!(**guard, "hi");
let key = LockCollection::<WriteLock<_, _>>::unlock(guard);
let guard = lock.write(key);
std::thread::scope(|s| {
s.spawn(|| {
let key = ThreadKey::get().unwrap();
let guard = collection.try_lock(key);
assert!(guard.is_err());
});
});
drop(guard);
}
#[test]
fn read_ref_as_ref() {
let key = ThreadKey::get().unwrap();
let lock = LockCollection::new(crate::RwLock::new("hi"));
let guard = lock.read(key);
assert_eq!(*(*guard).as_ref(), "hi");
}
#[test]
fn read_guard_as_ref() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("hi");
let guard = lock.read(key);
assert_eq!(*guard.as_ref(), "hi");
}
#[test]
fn write_ref_as_ref() {
let key = ThreadKey::get().unwrap();
let lock = LockCollection::new(crate::RwLock::new("hi"));
let guard = lock.lock(key);
assert_eq!(*(*guard).as_ref(), "hi");
}
#[test]
fn write_guard_as_ref() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("hi");
let guard = lock.write(key);
assert_eq!(*guard.as_ref(), "hi");
}
#[test]
fn write_guard_as_mut() {
let key = ThreadKey::get().unwrap();
let lock = crate::RwLock::new("hi");
let mut guard = lock.write(key);
assert_eq!(*guard.as_mut(), "hi");
*guard.as_mut() = "foo";
assert_eq!(*guard.as_mut(), "foo");
}
#[test]
fn poison_read_lock() {
let lock = crate::RwLock::new("hi");
let reader = ReadLock::new(&lock);
reader.poison();
assert!(lock.poison.is_poisoned());
}
#[test]
fn poison_write_lock() {
let lock = crate::RwLock::new("hi");
let reader = WriteLock::new(&lock);
reader.poison();
assert!(lock.poison.is_poisoned());
}
}
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