spin 0.9.8

Spin-based synchronization primitives
Documentation
# spin-rs

[![Crates.io version](https://img.shields.io/crates/v/spin.svg)](https://crates.io/crates/spin)
[![docs.rs](https://docs.rs/spin/badge.svg)](https://docs.rs/spin/)
[![Build Status](https://travis-ci.org/mvdnes/spin-rs.svg)](https://travis-ci.org/mvdnes/spin-rs)

Spin-based synchronization primitives.

This crate provides [spin-based](https://en.wikipedia.org/wiki/Spinlock)
versions of the primitives in `std::sync`. Because synchronization is done
through spinning, the primitives are suitable for use in `no_std` environments.

Before deciding to use `spin`, we recommend reading
[this superb blog post](https://matklad.github.io/2020/01/02/spinlocks-considered-harmful.html)
by [@matklad](https://github.com/matklad/) that discusses the pros and cons of
spinlocks. If you have access to `std`, it's likely that the primitives in
`std::sync` will serve you better except in very specific circumstances.

## Features

- `Mutex`, `RwLock`, `Once`, `Lazy` and `Barrier` equivalents
- Support for `no_std` environments
- [`lock_api`]https://crates.io/crates/lock_api compatibility
- Upgradeable `RwLock` guards
- Guards can be sent and shared between threads
- Guard leaking
- Ticket locks
- Different strategies for dealing with contention

## Usage

Include the following under the `[dependencies]` section in your `Cargo.toml` file.

```toml
spin = "x.y"
```

## Example

When calling `lock` on a `Mutex` you will get a guard value that provides access
to the data. When this guard is dropped, the mutex will become available again.

```rust
extern crate spin;
use std::{sync::Arc, thread};

fn main() {
    let counter = Arc::new(spin::Mutex::new(0));

    let thread = thread::spawn({
        let counter = counter.clone();
        move || {
            for _ in 0..100 {
                *counter.lock() += 1;
            }
        }
    });

    for _ in 0..100 {
        *counter.lock() += 1;
    }

    thread.join().unwrap();

    assert_eq!(*counter.lock(), 200);
}
```

## Feature flags

The crate comes with a few feature flags that you may wish to use.

- `mutex` enables the `Mutex` type.

- `spin_mutex` enables the `SpinMutex` type.

- `ticket_mutex` enables the `TicketMutex` type.

- `use_ticket_mutex` switches to a ticket lock for the implementation of `Mutex`. This
  is recommended only on targets for which ordinary spinning locks perform very badly
  because it will change the implementation used by other crates that depend on `spin`.

- `rwlock` enables the `RwLock` type.

- `once` enables the `Once` type.

- `lazy` enables the `Lazy` type.

- `barrier` enables the `Barrier` type.

- `lock_api` enables support for [`lock_api`]https://crates.io/crates/lock_api

- `std` enables support for thread yielding instead of spinning.

- `portable_atomic` enables usage of the `portable-atomic` crate
  to support platforms without native atomic operations (Cortex-M0, etc.).
  The `portable_atomic_unsafe_assume_single_core` cfg or `critical-section` feature
  of `portable-atomic` crate must also be set by the final binary crate.

  When using the cfg, this can be done by adapting the following snippet to the `.cargo/config` file:
  ```
  [target.<target>]
  rustflags = [ "--cfg", "portable_atomic_unsafe_assume_single_core" ]
  ```
  Note that this cfg is unsafe by nature, and enabling it for multicore systems is unsound.

  When using the `critical-section` feature, you need to implement the critical-section
  implementation that sound for your system by implementing an unsafe trait.
  See [the documentation for the `portable-atomic` crate]https://docs.rs/portable-atomic/latest/portable_atomic/#optional-cfg
  for more information.

## Remarks

It is often desirable to have a lock shared between threads. Wrapping the lock in an
`std::sync::Arc` is route through which this might be achieved.

Locks provide zero-overhead access to their data when accessed through a mutable
reference by using their `get_mut` methods.

The behaviour of these lock is similar to their namesakes in `std::sync`. they
differ on the following:

- Locks will not be poisoned in case of failure.
- Threads will not yield to the OS scheduler when encounter a lock that cannot be
  accessed. Instead, they will 'spin' in a busy loop until the lock becomes available.

Many of the feature flags listed above are enabled by default. If you're writing a
library, we recommend disabling those that you don't use to avoid increasing compilation
time for your crate's users. You can do this like so:

```
[dependencies]
spin = { version = "x.y", default-features = false, features = [...] }
```

## Minimum Safe Rust Version (MSRV)

This crate is guaranteed to compile on a Minimum Safe Rust Version (MSRV) of 1.38.0 and above.
This version will not be changed without a minor version bump.

## License

`spin` is distributed under the MIT License, (See `LICENSE`).