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// Copyright 2016 Amanieu d'Antras

//

// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or

// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or

// http://opensource.org/licenses/MIT>, at your option. This file may not be

// copied, modified, or distributed except according to those terms.

use crate::raw_mutex::RawMutex;

use lock_api;

/// A mutual exclusion primitive useful for protecting shared data

///

/// This mutex will block threads waiting for the lock to become available. The

/// mutex can be statically initialized or created by the `new`

/// constructor. Each mutex has a type parameter which represents the data that

/// it is protecting. The data can only be accessed through the RAII guards

/// returned from `lock` and `try_lock`, which guarantees that the data is only

/// ever accessed when the mutex is locked.

///

/// # Fairness

///

/// A typical unfair lock can often end up in a situation where a single thread

/// quickly acquires and releases the same mutex in succession, which can starve

/// other threads waiting to acquire the mutex. While this improves throughput

/// because it doesn't force a context switch when a thread tries to re-acquire

/// a mutex it has just released, this can starve other threads.

///

/// This mutex uses [eventual fairness](https://trac.webkit.org/changeset/203350)

/// to ensure that the lock will be fair on average without sacrificing

/// throughput. This is done by forcing a fair unlock on average every 0.5ms,

/// which will force the lock to go to the next thread waiting for the mutex.

///

/// Additionally, any critical section longer than 1ms will always use a fair

/// unlock, which has a negligible impact on throughput considering the length

/// of the critical section.

///

/// You can also force a fair unlock by calling `MutexGuard::unlock_fair` when

/// unlocking a mutex instead of simply dropping the `MutexGuard`.

///

/// # Differences from the standard library `Mutex`

///

/// - No poisoning, the lock is released normally on panic.

/// - Only requires 1 byte of space, whereas the standard library boxes the

///   `Mutex` due to platform limitations.

/// - Can be statically constructed.

/// - Does not require any drop glue when dropped.

/// - Inline fast path for the uncontended case.

/// - Efficient handling of micro-contention using adaptive spinning.

/// - Allows raw locking & unlocking without a guard.

/// - Supports eventual fairness so that the mutex is fair on average.

/// - Optionally allows making the mutex fair by calling `MutexGuard::unlock_fair`.

///

/// # Examples

///

/// ```

/// use parking_lot::Mutex;

/// use std::sync::{Arc, mpsc::channel};

/// use std::thread;

///

/// const N: usize = 10;

///

/// // Spawn a few threads to increment a shared variable (non-atomically), and

/// // let the main thread know once all increments are done.

/// //

/// // Here we're using an Arc to share memory among threads, and the data inside

/// // the Arc is protected with a mutex.

/// let data = Arc::new(Mutex::new(0));

///

/// let (tx, rx) = channel();

/// for _ in 0..10 {

///     let (data, tx) = (Arc::clone(&data), tx.clone());

///     thread::spawn(move || {

///         // The shared state can only be accessed once the lock is held.

///         // Our non-atomic increment is safe because we're the only thread

///         // which can access the shared state when the lock is held.

///         let mut data = data.lock();

///         *data += 1;

///         if *data == N {

///             tx.send(()).unwrap();

///         }

///         // the lock is unlocked here when `data` goes out of scope.

///     });

/// }

///

/// rx.recv().unwrap();

/// ```

pub type Mutex<T> = lock_api::Mutex<RawMutex, T>;

/// Creates a new mutex in an unlocked state ready for use.

///

/// This allows creating a mutex in a constant context on stable Rust.

pub const fn const_mutex<T>(val: T) -> Mutex<T> {

    Mutex::const_new(<RawMutex as lock_api::RawMutex>::INIT, val)

/// An RAII implementation of a "scoped lock" of a mutex. When this structure is

/// dropped (falls out of scope), the lock will be unlocked.

///

/// The data protected by the mutex can be accessed through this guard via its

/// `Deref` and `DerefMut` implementations.

pub type MutexGuard<'a, T> = lock_api::MutexGuard<'a, RawMutex, T>;

/// An RAII mutex guard returned by `MutexGuard::map`, which can point to a

/// subfield of the protected data.

///

/// The main difference between `MappedMutexGuard` and `MutexGuard` is that the

/// former doesn't support temporarily unlocking and re-locking, since that

/// could introduce soundness issues if the locked object is modified by another

/// thread.

pub type MappedMutexGuard<'a, T> = lock_api::MappedMutexGuard<'a, RawMutex, T>;

#[cfg(test)]

mod tests {

    use crate::{Condvar, Mutex};

    use std::sync::atomic::{AtomicUsize, Ordering};

    use std::sync::mpsc::channel;

    use std::sync::Arc;

    use std::thread;

    #[cfg(feature = "serde")]

    use bincode::{deserialize, serialize};

    struct Packet<T>(Arc<(Mutex<T>, Condvar)>);

    #[derive(Eq, PartialEq, Debug)]

    struct NonCopy(i32);

    unsafe impl<T: Send> Send for Packet<T> {}

    unsafe impl<T> Sync for Packet<T> {}

    #[test]

    fn smoke() {

        let m = Mutex::new(());

        drop(m.lock());

        drop(m.lock());

    #[test]

    fn lots_and_lots() {

        const J: u32 = 1000;

        const K: u32 = 3;

        let m = Arc::new(Mutex::new(0));

        fn inc(m: &Mutex<u32>) {

            for _ in 0..J {

                *m.lock() += 1;

        let (tx, rx) = channel();

        for _ in 0..K {

            let tx2 = tx.clone();

            let m2 = m.clone();

            thread::spawn(move || {

                inc(&m2);

                tx2.send(()).unwrap();

});

            let tx2 = tx.clone();

            let m2 = m.clone();

            thread::spawn(move || {

                inc(&m2);

                tx2.send(()).unwrap();

});

        drop(tx);

        for _ in 0..2 * K {

            rx.recv().unwrap();

        assert_eq!(*m.lock(), J * K * 2);

    #[test]

    fn try_lock() {

        let m = Mutex::new(());

        *m.try_lock().unwrap() = ();

    #[test]

    fn test_into_inner() {

        let m = Mutex::new(NonCopy(10));

        assert_eq!(m.into_inner(), NonCopy(10));

    #[test]

    fn test_into_inner_drop() {

        struct Foo(Arc<AtomicUsize>);

        impl Drop for Foo {

            fn drop(&mut self) {

                self.0.fetch_add(1, Ordering::SeqCst);

        let num_drops = Arc::new(AtomicUsize::new(0));

        let m = Mutex::new(Foo(num_drops.clone()));

        assert_eq!(num_drops.load(Ordering::SeqCst), 0);

            let _inner = m.into_inner();

            assert_eq!(num_drops.load(Ordering::SeqCst), 0);

        assert_eq!(num_drops.load(Ordering::SeqCst), 1);

    #[test]

    fn test_get_mut() {

        let mut m = Mutex::new(NonCopy(10));

        *m.get_mut() = NonCopy(20);

        assert_eq!(m.into_inner(), NonCopy(20));

    #[test]

    fn test_mutex_arc_condvar() {

        let packet = Packet(Arc::new((Mutex::new(false), Condvar::new())));

        let packet2 = Packet(packet.0.clone());

        let (tx, rx) = channel();

        let _t = thread::spawn(move || {

            // wait until parent gets in

            rx.recv().unwrap();

            let &(ref lock, ref cvar) = &*packet2.0;

            let mut lock = lock.lock();

            *lock = true;

            cvar.notify_one();

});

        let &(ref lock, ref cvar) = &*packet.0;

        let mut lock = lock.lock();

        tx.send(()).unwrap();

        assert!(!*lock);

        while !*lock {

            cvar.wait(&mut lock);

    #[test]

    fn test_mutex_arc_nested() {

        // Tests nested mutexes and access

        // to underlying data.

        let arc = Arc::new(Mutex::new(1));

        let arc2 = Arc::new(Mutex::new(arc));

        let (tx, rx) = channel();

        let _t = thread::spawn(move || {

            let lock = arc2.lock();

            let lock2 = lock.lock();

            assert_eq!(*lock2, 1);

            tx.send(()).unwrap();

});

        rx.recv().unwrap();

    #[test]

    fn test_mutex_arc_access_in_unwind() {

        let arc = Arc::new(Mutex::new(1));

        let arc2 = arc.clone();

        let _ = thread::spawn(move || {

            struct Unwinder {

                i: Arc<Mutex<i32>>,

            impl Drop for Unwinder {

                fn drop(&mut self) {

                    *self.i.lock() += 1;

            let _u = Unwinder { i: arc2 };

            panic!();

})

        .join();

        let lock = arc.lock();

        assert_eq!(*lock, 2);

    #[test]

    fn test_mutex_unsized() {

        let mutex: &Mutex<[i32]> = &Mutex::new([1, 2, 3]);

            let b = &mut *mutex.lock();

            b[0] = 4;

            b[2] = 5;

        let comp: &[i32] = &[4, 2, 5];

        assert_eq!(&*mutex.lock(), comp);

    #[test]

    fn test_mutexguard_sync() {

        fn sync<T: Sync>(_: T) {}

        let mutex = Mutex::new(());

        sync(mutex.lock());

    #[test]

    fn test_mutex_debug() {

        let mutex = Mutex::new(vec![0u8, 10]);

        assert_eq!(format!("{:?}", mutex), "Mutex { data: [0, 10] }");

        let _lock = mutex.lock();

        assert_eq!(format!("{:?}", mutex), "Mutex { data: <locked> }");

    #[cfg(feature = "serde")]

    #[test]

    fn test_serde() {

        let contents: Vec<u8> = vec![0, 1, 2];

        let mutex = Mutex::new(contents.clone());

        let serialized = serialize(&mutex).unwrap();

        let deserialized: Mutex<Vec<u8>> = deserialize(&serialized).unwrap();

        assert_eq!(*(mutex.lock()), *(deserialized.lock()));

        assert_eq!(contents, *(deserialized.lock()));