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https://github.com/co-rs/mco

Rust Async Coroutine Runtime that combines speed and ease to use
https://github.com/co-rs/mco

async async-runtime asynchronous asyncio goroutine mco networking rust

Last synced: 4 months ago
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Rust Async Coroutine Runtime that combines speed and ease to use

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README 

          
# mco






mco is a high-performance library for programming stackful coroutines with which you can easily develop and maintain

massive concurrent programs. It can be thought as the Rust version of the popular [Goroutine][go].



- [x] Most commonly used APIs

- [ ] The current version support stack expansion



# way mco?

* Elegant coding,No need for async await

* Simple concurrency(CSP model), learning Golang

* Default MAX 6MB Stack Size

* many std like API



> Initial code frok from [May](https://github.com/Xudong-Huang/may) and we add Many improvements(Inspired by [Golang](https://golang.google.cn/),  [parking_lot](https://github.com/Amanieu/parking_lot)  and [crossbeam](https://github.com/crossbeam-rs/crossbeam)) and more...



# mco crates



> mco Powerful standard library



* ``` mco/std/queue ``` Basic queue data structures

* ``` mco/std/sync ```  Includes ``` Mutex/RwLock/WaitGroup/Semphore/chan!()/chan!(1000) ```...and more..

* ``` mco/std/defer ``` Defers evaluation of a block of code until the end of the scope.

* ``` mco/std/map ```  Provides the same concurrency map as Golang, with ```SyncHashMap``` and ```SyncBtreeMap```.It is

  suitable for concurrent environments with too many reads and too few writes

* ``` mco/std/vec ```  Provides the same concurrency vec

* ``` mco/std/time ``` Improve the implementation of a high performance time

* ``` mco/std/lazy ``` Thread/coroutine safe global variable,Lazy struct,OnceCell



> Crates based on mco implementation



* [mco-http](https://github.com/co-rs/mco-http) High-performance coroutine HTTP server and client

* [cdbc](https://github.com/co-rs/cdbc) Database Drivers include mysql, Postgres, AND SQLite

* [fast_log](https://github.com/co-rs/fast_log) High-performance log impl

* [mco-redis](https://github.com/co-rs/mco-redis) Redis client for mco

* [mco-redis-rs](https://github.com/co-rs/mco-redis-rs) fork from ```redis-rs``` Replace only TcpStream with MCO ::TcpStream

* [mco-rpc](https://github.com/co-rs/mco-rpc)  rpc server/client. support bincode/json rpc



## Features



* The stackful coroutine implementation is based on [generator][generator];

* Support schedule on a configurable number of threads for multi-core systems;

* Support coroutine version of a local storage ([CLS][cls]);

* Support efficient asynchronous network I/O;

* Support efficient timer management;

* Support standard synchronization primitives, a semaphore, an MPMC channel, etc;

* Support cancellation of coroutines;

* Support graceful panic handling that will not affect other coroutines;

* Support scoped coroutine creation;

* Support general selection for all the coroutine API;

* All the coroutine API are compatible with the standard library semantics;

* All the coroutine API can be safely called in multi-threaded context;

* Both stable, beta, and nightly channels are supported;

* x86_64 GNU/Linux, x86_64 Windows, x86_64 Mac, aarch64 Linux OS are supported.



* Support High performance chan(like golang)

* Support WaitGroup Support(like golang)

* Support defer!() (like golang)

* Support Rustls

* Support Time (like golang)

* Support error/err!() (like golang)

* Support select match Ok(v)/Err(e)  (like golang)

* Support Lazy/OnceCell

* Support SyncMap(like golang)

* Support Ticker(like golang)



## Usage

```toml

mco = "0.1"

```

A naive echo server implemented with mco:



```rust

#[macro_use]

extern crate mco;



use mco::net::TcpListener;

use std::io::{Read, Write};



fn main() {

    let listener = TcpListener::bind("127.0.0.1:8000").unwrap();

    while let Ok((mut stream, _)) = listener.accept() {

        go!(move || {

            let mut buf = vec![0; 1024 * 16]; // alloc in heap!

            while let Ok(n) = stream.read(&mut buf) {

                if n == 0 {

                    break;

                }

                stream.write_all(&buf[0..n]).unwrap();

            }

        });

    }

}



```



## More examples



### The I/O heavy bound examples



* [An echo server](examples/src/echo.rs)

* [An echo client](examples/src/echo_client.rs)

* [simple HTTP](examples/src/http.rs)

* [simple HTTPS](examples/src/https.rs)

* [tiny  HTTP](https://github.com/co-rs/mco-http)

* [WebSockets](examples/src/websocket.rs)



## Caveat



There is a detailed [document][caveat] that describes mco's main restrictions. In general, there are four things you

should follow when writing programs that use coroutines:



* Don't call thread-blocking API (It will hurt the performance);

* Carefully use Thread Local Storage (access TLS in coroutine might trigger undefined behavior).



> It's considered **unsafe** with the following pattern:

> ```rust

> set_tls();

> // Or another coroutine API that would cause scheduling:

> yield_now(); 

> use_tls();

> ```

> but it's **safe** if your code is not sensitive about the previous state of TLS. Or there is no coroutines scheduling between **set** TLS and **use** TLS.



* Don't run CPU bound tasks for long time, but it's ok if you don't care about fairness;

* Don't run thread::sleep() on mco coroutine

* In most modern operating systems, when starting a process, the standard Thread stack size is usually 8 MB, and mco provides a maximum stack space of 6MB. Typically, operating systems load memory pages on demand, such as starting about 1 million processes on my Mac/Unix system, which requires 15GB of memory space. 

* Don't exceed the coroutine stack. There is a guard page for each coroutine stack. When stack overflow occurs, it will

  trigger segment fault error.



**Note:**

> The first three rules are common when using cooperative asynchronous libraries in Rust. Even using a futures-based system also have these limitations. So what you should really focus on is a coroutine stack size, make sure it's big enough for your applications.



## How to tune a stack size



```rust

mco::config().set_stack_size(6*1024*1024);

```



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