src/libstd/sync/mod.rs - third_party/rust - Git at Google

 //! Useful synchronization primitives.
 //!
 //! ## The need for synchronization
 //!
 //! Conceptually, a Rust program is a series of operations which will
 //! be executed on a computer. The timeline of events happening in the
 //! program is consistent with the order of the operations in the code.
 //!
 //! Consider the following code, operating on some global static variables:
 //!
 //! ```rust
 //! static mut A: u32 = 0;
 //! static mut B: u32 = 0;
 //! static mut C: u32 = 0;
 //!
 //! fn main() {
 //!     unsafe {
 //!         A = 3;
 //!         B = 4;
 //!         A = A + B;
 //!         C = B;
 //!         println!("{} {} {}", A, B, C);
 //!         C = A;
 //!     }
 //! }
 //! ```
 //!
 //! It appears as if some variables stored in memory are changed, an addition
 //! is performed, result is stored in `A` and the variable `C` is
 //! modified twice.
 //!
 //! When only a single thread is involved, the results are as expected:
 //! the line `7 4 4` gets printed.
 //!
 //! As for what happens behind the scenes, when optimizations are enabled the
 //! final generated machine code might look very different from the code:
 //!
 //! - The first store to `C` might be moved before the store to `A` or `B`,
 //!   _as if_ we had written `C = 4; A = 3; B = 4`.
 //!
 //! - Assignment of `A + B` to `A` might be removed, since the sum can be stored
 //!   in a temporary location until it gets printed, with the global variable
 //!   never getting updated.
 //!
 //! - The final result could be determined just by looking at the code
 //!   at compile time, so [constant folding] might turn the whole
 //!   block into a simple `println!("7 4 4")`.
 //!
 //! The compiler is allowed to perform any combination of these
 //! optimizations, as long as the final optimized code, when executed,
 //! produces the same results as the one without optimizations.
 //!
 //! Due to the [concurrency] involved in modern computers, assumptions
 //! about the program's execution order are often wrong. Access to
 //! global variables can lead to nondeterministic results, **even if**
 //! compiler optimizations are disabled, and it is **still possible**
 //! to introduce synchronization bugs.
 //!
 //! Note that thanks to Rust's safety guarantees, accessing global (static)
 //! variables requires `unsafe` code, assuming we don't use any of the
 //! synchronization primitives in this module.
 //!
 //! [constant folding]: https://en.wikipedia.org/wiki/Constant_folding
 //! [concurrency]: https://en.wikipedia.org/wiki/Concurrency_(computer_science)
 //!
 //! ## Out-of-order execution
 //!
 //! Instructions can execute in a different order from the one we define, due to
 //! various reasons:
 //!
 //! - The **compiler** reordering instructions: If the compiler can issue an
 //!   instruction at an earlier point, it will try to do so. For example, it
 //!   might hoist memory loads at the top of a code block, so that the CPU can
 //!   start [prefetching] the values from memory.
 //!
 //!   In single-threaded scenarios, this can cause issues when writing
 //!   signal handlers or certain kinds of low-level code.
 //!   Use [compiler fences] to prevent this reordering.
 //!
 //! - A **single processor** executing instructions [out-of-order]:
 //!   Modern CPUs are capable of [superscalar] execution,
 //!   i.e., multiple instructions might be executing at the same time,
 //!   even though the machine code describes a sequential process.
 //!
 //!   This kind of reordering is handled transparently by the CPU.
 //!
 //! - A **multiprocessor** system executing multiple hardware threads
 //!   at the same time: In multi-threaded scenarios, you can use two
 //!   kinds of primitives to deal with synchronization:
 //!   - [memory fences] to ensure memory accesses are made visible to
 //!   other CPUs in the right order.
 //!   - [atomic operations] to ensure simultaneous access to the same
 //!   memory location doesn't lead to undefined behavior.
 //!
 //! [prefetching]: https://en.wikipedia.org/wiki/Cache_prefetching
 //! [compiler fences]: crate::sync::atomic::compiler_fence
 //! [out-of-order]: https://en.wikipedia.org/wiki/Out-of-order_execution
 //! [superscalar]: https://en.wikipedia.org/wiki/Superscalar_processor
 //! [memory fences]: crate::sync::atomic::fence
 //! [atomic operations]: crate::sync::atomic
 //!
 //! ## Higher-level synchronization objects
 //!
 //! Most of the low-level synchronization primitives are quite error-prone and
 //! inconvenient to use, which is why the standard library also exposes some
 //! higher-level synchronization objects.
 //!
 //! These abstractions can be built out of lower-level primitives.
 //! For efficiency, the sync objects in the standard library are usually
 //! implemented with help from the operating system's kernel, which is
 //! able to reschedule the threads while they are blocked on acquiring
 //! a lock.
 //!
 //! The following is an overview of the available synchronization
 //! objects:
 //!
 //! - [`Arc`]: Atomically Reference-Counted pointer, which can be used
 //!   in multithreaded environments to prolong the lifetime of some
 //!   data until all the threads have finished using it.
 //!
 //! - [`Barrier`]: Ensures multiple threads will wait for each other
 //!   to reach a point in the program, before continuing execution all
 //!   together.
 //!
 //! - [`Condvar`]: Condition Variable, providing the ability to block
 //!   a thread while waiting for an event to occur.
 //!
 //! - [`mpsc`]: Multi-producer, single-consumer queues, used for
 //!   message-based communication. Can provide a lightweight
 //!   inter-thread synchronisation mechanism, at the cost of some
 //!   extra memory.
 //!
 //! - [`Mutex`]: Mutual Exclusion mechanism, which ensures that at
 //!   most one thread at a time is able to access some data.
 //!
 //! - [`Once`]: Used for thread-safe, one-time initialization of a
 //!   global variable.
 //!
 //! - [`RwLock`]: Provides a mutual exclusion mechanism which allows
 //!   multiple readers at the same time, while allowing only one
 //!   writer at a time. In some cases, this can be more efficient than
 //!   a mutex.
 //!
 //! [`Arc`]: crate::sync::Arc
 //! [`Barrier`]: crate::sync::Barrier
 //! [`Condvar`]: crate::sync::Condvar
 //! [`mpsc`]: crate::sync::mpsc
 //! [`Mutex`]: crate::sync::Mutex
 //! [`Once`]: crate::sync::Once
 //! [`RwLock`]: crate::sync::RwLock

 #![stable(feature = "rust1", since = "1.0.0")]

 #[stable(feature = "rust1", since = "1.0.0")]
 pub use alloc_crate::sync::{Arc, Weak};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use core::sync::atomic;

 #[stable(feature = "rust1", since = "1.0.0")]
 pub use self::barrier::{Barrier, BarrierWaitResult};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use self::condvar::{Condvar, WaitTimeoutResult};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use self::mutex::{Mutex, MutexGuard};
 #[stable(feature = "rust1", since = "1.0.0")]
 #[allow(deprecated)]
 pub use self::once::{Once, OnceState, ONCE_INIT};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use self::rwlock::{RwLock, RwLockReadGuard, RwLockWriteGuard};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use crate::sys_common::poison::{LockResult, PoisonError, TryLockError, TryLockResult};

 pub mod mpsc;

 mod barrier;
 mod condvar;
 mod mutex;
 mod once;
 mod rwlock;
	//! Useful synchronization primitives.
	//!
	//! ## The need for synchronization
	//!
	//! Conceptually, a Rust program is a series of operations which will
	//! be executed on a computer. The timeline of events happening in the
	//! program is consistent with the order of the operations in the code.
	//!
	//! Consider the following code, operating on some global static variables:
	//!
	//! ```rust
	//! static mut A: u32 = 0;
	//! static mut B: u32 = 0;
	//! static mut C: u32 = 0;
	//!
	//! fn main() {
	//! unsafe {
	//! A = 3;
	//! B = 4;
	//! A = A + B;
	//! C = B;
	//! println!("{} {} {}", A, B, C);
	//! C = A;
	//! }
	//! }
	//! ```
	//!
	//! It appears as if some variables stored in memory are changed, an addition
	//! is performed, result is stored in `A` and the variable `C` is
	//! modified twice.
	//!
	//! When only a single thread is involved, the results are as expected:
	//! the line `7 4 4` gets printed.
	//!
	//! As for what happens behind the scenes, when optimizations are enabled the
	//! final generated machine code might look very different from the code:
	//!
	//! - The first store to `C` might be moved before the store to `A` or `B`,
	//! _as if_ we had written `C = 4; A = 3; B = 4`.
	//!
	//! - Assignment of `A + B` to `A` might be removed, since the sum can be stored
	//! in a temporary location until it gets printed, with the global variable
	//! never getting updated.
	//!
	//! - The final result could be determined just by looking at the code
	//! at compile time, so [constant folding] might turn the whole
	//! block into a simple `println!("7 4 4")`.
	//!
	//! The compiler is allowed to perform any combination of these
	//! optimizations, as long as the final optimized code, when executed,
	//! produces the same results as the one without optimizations.
	//!
	//! Due to the [concurrency] involved in modern computers, assumptions
	//! about the program's execution order are often wrong. Access to
	//! global variables can lead to nondeterministic results, even if
	//! compiler optimizations are disabled, and it is still possible
	//! to introduce synchronization bugs.
	//!
	//! Note that thanks to Rust's safety guarantees, accessing global (static)
	//! variables requires `unsafe` code, assuming we don't use any of the
	//! synchronization primitives in this module.
	//!
	//! [constant folding]: https://en.wikipedia.org/wiki/Constant_folding
	//! [concurrency]: https://en.wikipedia.org/wiki/Concurrency_(computer_science)
	//!
	//! ## Out-of-order execution
	//!
	//! Instructions can execute in a different order from the one we define, due to
	//! various reasons:
	//!
	//! - The compiler reordering instructions: If the compiler can issue an
	//! instruction at an earlier point, it will try to do so. For example, it
	//! might hoist memory loads at the top of a code block, so that the CPU can
	//! start [prefetching] the values from memory.
	//!
	//! In single-threaded scenarios, this can cause issues when writing
	//! signal handlers or certain kinds of low-level code.
	//! Use [compiler fences] to prevent this reordering.
	//!
	//! - A single processor executing instructions [out-of-order]:
	//! Modern CPUs are capable of [superscalar] execution,
	//! i.e., multiple instructions might be executing at the same time,
	//! even though the machine code describes a sequential process.
	//!
	//! This kind of reordering is handled transparently by the CPU.
	//!
	//! - A multiprocessor system executing multiple hardware threads
	//! at the same time: In multi-threaded scenarios, you can use two
	//! kinds of primitives to deal with synchronization:
	//! - [memory fences] to ensure memory accesses are made visible to
	//! other CPUs in the right order.
	//! - [atomic operations] to ensure simultaneous access to the same
	//! memory location doesn't lead to undefined behavior.
	//!
	//! [prefetching]: https://en.wikipedia.org/wiki/Cache_prefetching
	//! [compiler fences]: crate::sync::atomic::compiler_fence
	//! [out-of-order]: https://en.wikipedia.org/wiki/Out-of-order_execution
	//! [superscalar]: https://en.wikipedia.org/wiki/Superscalar_processor
	//! [memory fences]: crate::sync::atomic::fence
	//! [atomic operations]: crate::sync::atomic
	//!
	//! ## Higher-level synchronization objects
	//!
	//! Most of the low-level synchronization primitives are quite error-prone and
	//! inconvenient to use, which is why the standard library also exposes some
	//! higher-level synchronization objects.
	//!
	//! These abstractions can be built out of lower-level primitives.
	//! For efficiency, the sync objects in the standard library are usually
	//! implemented with help from the operating system's kernel, which is
	//! able to reschedule the threads while they are blocked on acquiring
	//! a lock.
	//!
	//! The following is an overview of the available synchronization
	//! objects:
	//!
	//! - [`Arc`]: Atomically Reference-Counted pointer, which can be used
	//! in multithreaded environments to prolong the lifetime of some
	//! data until all the threads have finished using it.
	//!
	//! - [`Barrier`]: Ensures multiple threads will wait for each other
	//! to reach a point in the program, before continuing execution all
	//! together.
	//!
	//! - [`Condvar`]: Condition Variable, providing the ability to block
	//! a thread while waiting for an event to occur.
	//!
	//! - [`mpsc`]: Multi-producer, single-consumer queues, used for
	//! message-based communication. Can provide a lightweight
	//! inter-thread synchronisation mechanism, at the cost of some
	//! extra memory.
	//!
	//! - [`Mutex`]: Mutual Exclusion mechanism, which ensures that at
	//! most one thread at a time is able to access some data.
	//!
	//! - [`Once`]: Used for thread-safe, one-time initialization of a
	//! global variable.
	//!
	//! - [`RwLock`]: Provides a mutual exclusion mechanism which allows
	//! multiple readers at the same time, while allowing only one
	//! writer at a time. In some cases, this can be more efficient than
	//! a mutex.
	//!
	//! [`Arc`]: crate::sync::Arc
	//! [`Barrier`]: crate::sync::Barrier
	//! [`Condvar`]: crate::sync::Condvar
	//! [`mpsc`]: crate::sync::mpsc
	//! [`Mutex`]: crate::sync::Mutex
	//! [`Once`]: crate::sync::Once
	//! [`RwLock`]: crate::sync::RwLock

	#![stable(feature = "rust1", since = "1.0.0")]

	#[stable(feature = "rust1", since = "1.0.0")]
	pub use alloc_crate::sync::{Arc, Weak};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use core::sync::atomic;

	#[stable(feature = "rust1", since = "1.0.0")]
	pub use self::barrier::{Barrier, BarrierWaitResult};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use self::condvar::{Condvar, WaitTimeoutResult};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use self::mutex::{Mutex, MutexGuard};
	#[stable(feature = "rust1", since = "1.0.0")]
	#[allow(deprecated)]
	pub use self::once::{Once, OnceState, ONCE_INIT};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use self::rwlock::{RwLock, RwLockReadGuard, RwLockWriteGuard};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use crate::sys_common::poison::{LockResult, PoisonError, TryLockError, TryLockResult};

	pub mod mpsc;

	mod barrier;
	mod condvar;
	mod mutex;
	mod once;
	mod rwlock;