Expand description
Monoio
A thread-per-core Rust runtime with io_uring/epoll/kqueue.
Design Goal
Monoio is a pure io_uring/epoll/kqueue Rust async runtime. Part of the design has been borrowed from Tokio and Tokio-uring. However, unlike Tokio-uring, Monoio does not run on top of another runtime, rendering it more efficient.
Moreover, Monoio is designed with a thread-per-core model in mind. Users do not need to worry about tasks being Send
or Sync
, as thread local storage can be used safely. In other words, the data does not escape the thread on await points, unlike on work-stealing runtimes such as Tokio. This is because for some use cases, specifically those targeted by this runtime, it is not necessary to make task schedulable between threads. For example, if we were to write a load balancer like NGINX, we would write it in a thread-per-core way. The thread local data does not need to be shared between threads, so the Sync
and Send
do not need to be implemented in the first place.
As you may have guessed, this runtime is primarily targeted at servers, where operations are io-bound on network sockets, and therefore the use of native asynchronous I/O APIs maximizes the throughput of the server. In order for Monoio to be as efficient as possible, we’ve enabled some unstable Rust features, and we’ve designed a whole new IO abstraction, which unfortunately may cause some compatibility problems. Our benchmarks probe that, for our use-cases, Monoio has a better performance than other Rust runtimes.
Quick Start
To use monoio, you need the latest nightly rust toolchain. If you already installed it, please make sure it is the latest version.
To force using nightly, create a file named rust-toolchain
and write nightly
in it. Also, you can use cargo +nightly
to build or run.
Also, if you want to use io_uring, you must make sure your kernel supports it(5.6+). And, memlock is configured as a proper number. If your kernel version does not meet the requirements, you can try to use the legacy driver to start, currently supports Linux and macOS(ref here).
🚧Experimental windows support is on the way.
Here is a basic example of how to use Monoio.
/// A echo example.
///
/// Run the example and `nc 127.0.0.1 50002` in another shell.
/// All your input will be echoed out.
use monoio::io::{AsyncReadRent, AsyncWriteRentExt};
use monoio::net::{TcpListener, TcpStream};
#[monoio::main]
async fn main() {
let listener = TcpListener::bind("127.0.0.1:50002").unwrap();
println!("listening");
loop {
let incoming = listener.accept().await;
match incoming {
Ok((stream, addr)) => {
println!("accepted a connection from {}", addr);
monoio::spawn(echo(stream));
}
Err(e) => {
println!("accepted connection failed: {}", e);
return;
}
}
}
}
async fn echo(mut stream: TcpStream) -> std::io::Result<()> {
let mut buf: Vec<u8> = Vec::with_capacity(8 * 1024);
let mut res;
loop {
// read
(res, buf) = stream.read(buf).await;
if res? == 0 {
return Ok(());
}
// write all
(res, buf) = stream.write_all(buf).await;
res?;
// clear
buf.clear();
}
}
You can find more example code in examples
of this repository.
Limitations
- On Linux 5.6 or newer, Monoio can use uring or epoll as io driver. On lower versions of Linux, it can only run in epoll mode. On macOS, kqueue can be used. Other platforms are currently not supported.
- Monoio can not solve all problems. If the workload is very unbalanced, it may cause performance degradation than Tokio since CPU cores may not be fully utilized.
Contributors
Thanks for their contributions!
Community
Monoio is a subproject of CloudWeGo. We are committed to building a cloud native ecosystem.
Associated Projects
- local-sync: A thread local channel.
- monoio-tls: TLS wrapper for Monoio.
- monoio-codec: Codec utility for Monoio.
HTTP framework and RPC framework are on the way.
Licenses
Monoio is licensed under the MIT license or Apache license.
During developing we referenced a lot from Tokio, Mio, Tokio-uring and other related projects. We would like to thank the authors of these projects.
Modules
- Utilities for working with buffers.
- Filesystem manipulation operations.
- IO traits
- Useful macros.
- Network related Currently, TCP/UnixStream/UnixDatagram are implemented.
- Task impl
- Utilities for tracking time.
- Common utils
Macros
- Wait on multiple concurrent branches, returning when all branches complete.
- pinDeprecatedPins a value on the stack.
- The macro. See the module level documentation for the description and examples.
- Wait on multiple concurrent branches, returning when the first branch completes, cancelling the remaining branches.
- Do syscall and return Result<T, std::io::Error>
- Do syscall and return Result<T, std::io::Error>
- Wait on multiple concurrent branches, returning when all branches complete with
Ok(_)
or on the firstErr(_)
.
Structs
- Fake driver only for conditionally building.
- Driver with uring.
- Driver with Poll-like syscall.
- Monoio runtime
- Runtime builder
Enums
- Fusion Runtime is a wrapper of io_uring driver or legacy driver based runtime.
Traits
- Buildable trait.
- Core driver trait.
Functions
- Spawns a new asynchronous task, returning a
JoinHandle
for it. - Start a monoio runtime.
Type Aliases
- A specialized
Result
type forio-uring
operations with buffers.