Crates.io | asynchronous |
lib.rs | asynchronous |
version | 0.4.5 |
source | src |
created_at | 2015-05-04 08:08:25.605911 |
updated_at | 2015-12-16 00:01:49.263868 |
description | Promises Q style , async and event loops |
homepage | |
repository | https://github.com/bcndanos/asynchronous |
max_upload_size | |
id | 2018 |
size | 73,767 |
Asynchronous promises in rust using threads
Crate | Travis |
---|---|
#Overview
This library provides an usefull way to invoke functions (clousures) in a Promise Style using separated threads. A Promise is a Struct that represents the return value or the error that the funcion produces.
It also allows the execution of tasks in Parallel or Series in deferred, joining the result in a Promise.
It includes methods to manage Event Loops, where there are tasks that "emit" events in background, and they are collected by a promise.
This project is based on the Q Promise library for Node JS and Async.js
#License
Dual-licensed to be compatible with the Rust project.
Licensed under the Apache License, Version 2.0 http://www.apache.org/licenses/LICENSE-2.0 or the MIT license http://opensource.org/licenses/MIT, at your option. This file may not be copied, modified, or distributed except according to those terms.
This is a simple setup for a promise based execution:
use asynchronous::Promise;
Promise::new(|| {
// Do something
let ret = 10.0 / 3.0;
if ret > 0.0 { Ok(ret) } else { Err("Incorrect Value") }
}).success(|res| { // res has type f64
// Do something if the previous result is correct
assert_eq!(res, 10.0 / 3.0);
let res_int = res as u32 * 2;
Ok(res_int)
}).finally_sync(|res| { // res has type Result<u32,&str>
// Executed always at the end
assert_eq!(res.unwrap(), 6u32);
});
Deferred execution:
use asynchronous::{Promise,Deferred,ControlFlow};
let d_a = Deferred::<&str, &str>::new(|| { Ok("a") });
let p_b = Promise::<&str, &str>::new(|| { Ok("b") }); // Executed right now
let d1 = Deferred::<u32, &str>::new(|| { Ok(1u32) });
let d2 = Deferred::<u32, &str>::new(|| { Err("Mock Error") });
let d3 = Deferred::<u32, &str>::new(|| { Ok(3u32) });
let d4 = Deferred::<u32, &str>::new(|| { Ok(4u32) });
let d5 = Deferred::<u32, &str>::new(|| { Ok(5u32) });
let promise = Deferred::vec_to_promise(vec![d1,d2,d3], ControlFlow::Parallel);
// Only d1, d2 and d3 are being executed at this time.
assert_eq!("ab", d_a.to_promise().success(|res_a| {
p_b.success(move |res_b| {
Ok(res_a.to_string() + res_b)
}).sync()
}).sync().unwrap());
promise.success(|res| {
// Catch the result. In this case, tasks d4 and d5 never will be executed
Ok(res)
}).fail(|error| {
// Catch the error and execute another Promise
assert_eq!(error, vec![Ok(1u32), Err("Mock Error"), Ok(3u32)]);
Deferred::vec_to_promise(vec![d4,d5], ControlFlow::Series).sync()
}).finally_sync(|res| { // res : Result<Vec<u32>,&str>
// Do something here
assert_eq!(res.unwrap(), vec![4u32, 5u32]);
});
Simple event loop:
use asynchronous::EventLoop;
let el = EventLoop::new().finish_in_ms(100);
el.emit("Event1");
el.emit("Event2");
// Do something here
el.to_promise().finally_sync(|res| { // res: Result<Vec<Ev>,()>
assert_eq!(res.unwrap(), vec!["Event1", "Event2"]);
});