Crate state [] [src]

state - safe and effortless state management

This crate allows you to safely and effortlessly manage global and/or thread-local state. Three primitives are provided for state management:

Usage

Include state in your Cargo.toml [dependencies]:

[dependencies]
state = "0.2"

Thread-local state management is not enabled by default. You can enable it via the tls feature:

[dependencies]
state = { version = "0.2", features = ["tls"] }

This crate requires Rust nightly due to the instability of the const_fn feature. Ensure the feature is enabled by adding the following to your top-level crate attributes:

#![feature(const_fn)]

Use Cases

Read-Only Singleton

Suppose you have the following structure which is initialized in main after receiving input from the user:

struct Configuration {
    name: String,
    number: isize,
    verbose: bool
}

fn main() {
    let config = Configuration {
        /* fill in structure at run-time from user input */
    };
}

You'd like to access this structure later, at any point in the program, without any synchronization overhead. Prior to state, assuming you needed to setup the structure after program start, your options were:

  1. Use static mut and unsafe to set an Option<Configuration> to Some. Retrieve by checking for Some.
  2. Use lazy_static with a RwLock to set an RwLock<Option<Configuration>> to Some. Retrieve by locking and checking for Some, paying the cost of synchronization.

With state, you can use LocalStorage and call set and get, as follows:

static CONFIG: LocalStorage<Configuration> = LocalStorage::new();

fn main() {
    CONFIG.set(|| Configuration {
        /* fill in structure at run-time from user input */
    });

    /* at any point later in the program, in any thread */
    let config = CONFIG.get();
}

Read/Write Singleton

Following from the previous example, let's now say that we want to be able to modify our singleton Configuration structure as the program evolves. We have two options:

  1. If we want to maintain the same state in any thread, we can use a Storage structure and wrap our Configuration structure in a synchronization primitive.
  2. If we want to maintain different state in any thread, we can continue to use a LocalStorage structure and wrap our LocalStorage type in a Cell structure for internal mutability.

In this example, we'll choose 1. The next example illustrates an instance of 2.

The following implements 1 by using a Storage structure and wrapping the Configuration type with a RwLock:

static CONFIG: Storage<RwLock<Configuration>> = Storage::new();

fn main() {
    let config = Configuration {
        /* fill in structure at run-time from user input */
    };

    // Make the config avaiable globally.
    CONFIG.set(RwLock::new(config));

    /* at any point later in the program, in any thread */
    let mut_config = CONFIG.get().write();
}

Mutable, thread-local data

Imagine you want to count the number of invocations to a function per thread. You'd like to store the count in a Cell<usize> and use count.set(count.get() + 1) to increment the count. Prior to state, your only option was to use the thread_local! macro. state provides a more flexible, and arguably simpler solution via LocalStorage. This scanario is implemented in the folloiwng:

static COUNT: LocalStorage<Cell<usize>> = LocalStorage::new();

fn function_to_measure() {
    let count = COUNT.get();
    count.set(count.get() + 1);
}

fn main() {
    // setup the initializer for thread-local state
    COUNT.set(|| Cell::new(0));

    // spin up many threads that call `function_to_measure`.
    let mut threads = vec![];
    for i in 0..10 {
        threads.push(thread::spawn(|| {
            function_to_measure();
            COUNT.get().get()
        }));
    }

    // retrieve the total
    let total: usize = threads.into_iter()
        .map(|t| t.join().unwrap())
        .sum();

    assert_eq!(total, 10);
}

Performance

state is heavily tuned to perform optimally. get{_local} and set{_local} calls to a Container incur overhead due to type lookup. Storage, on the other hand, is optimal for global storage retrieval; it is slightly faster than accessing global state initialized through lazy_static!, more so across many threads. LocalStorage incurs slight overhead due to thread lookup. However, LocalStorage has no synchronization overhead, so retrieval from LocalStorage is faster than through Storage across many threads.

Keep in mind that state allows global initialization at any point in the program. Other solutions, such as lazy_static! and thread_local! allow initialization only a priori. In other words, state's abilities are a superset of those provided by lazy_static! and thread_local!.

When To Use

You should avoid using state as much as possible. Instead, thread state manually throughout your program when feasible.

Structs

Container

A container for global type-based state.

LocalStorage

A single storage location for global access to thread-local values.

Storage

A single storage location for global access to a value.