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I'm having difficulties in making a Tokio client that receives packets from a server and stores them in a queue for the main thread to process, while being able to send packets to the server from another queue at the same time.

I'm trying to make a very simple online game demonstration, having a game client that Sends data (it's own modified states, like player movement) and receives data (Game states modified by other players & server, like an NPC/other players that also moved).

The idea is to have a network thread that accesses two Arcs holding Mutexes to Vec<bytes::Bytes> that store serialized data. One Arc is for IncomingPackets, and the other for OutgoingPackets. IncomingPackets would be filled by packets sent from the server to the client that would be later read by the main thread, and OutgoingPackets would be filled by the main thread with packets that should be sent to the server.

I can't seem to receive or send packets in another thread.

The client would only connect to the server, and the server would allow many clients (which would be served individually).

The explanations around stream's usage and implementation are not newbie-friendly, but I think I should be using them somehow.

I wrote some code, but it does not work and is probably wrong.

(My original code does not compile, so treat this as pseudocode, sorry)

Playground

extern crate byteorder; // 1.3.4
extern crate futures; // 0.3.5
extern crate tokio; // 0.2.21 

use bytes::Bytes;
use futures::future;
use std::error::Error;
use std::sync::{Arc, Mutex};
use tokio::net::TcpStream;

use byteorder::{BigEndian, WriteBytesExt};
use std::io;
use std::time::Duration;
use tokio::io::AsyncReadExt;
use tokio::io::AsyncWriteExt;
use tokio::net::tcp::{ReadHalf, WriteHalf};

//This is the SharedPackets struct that is located in the crate structures
struct SharedPackets {
    data: Mutex<Vec<bytes::Bytes>>,
}

#[tokio::main]
async fn main() -> Result<(), Box<dyn Error>> {
    let mut stream = TcpStream::connect("127.0.0.1:8080").await?;
    let (mut r, mut w) = stream.split();

    let mut inc: Vec<bytes::Bytes> = Vec::new();
    inc.push(Bytes::from("Wow"));

    let mut incoming_packets = Arc::new(SharedPackets {
        data: Mutex::new(inc),
    });

    let mut outg: Vec<bytes::Bytes> = Vec::new();
    outg.push(Bytes::from("Wow"));
    let mut outgoint_packets = Arc::new(SharedPackets {
        data: Mutex::new(outg),
    });

    let mut local_incoming_packets = Arc::clone(&incoming_packets);
    let mut local_outgoint_packets = Arc::clone(&outgoint_packets);
    let mut rarc = Arc::new(Mutex::new(r));
    let mut warc = Arc::new(Mutex::new(w));

    tokio::spawn(async move {
        //send and receive are both async functions that contain an infinite loop
        //they basically use AsyncWriteExt and AsyncReadExt to manipulate both halves of the stream
        //send reads the queue and write this data on the socket
        //recv reads the socket and write this data on the queue
        //both "queues" are manipulated by the main thread
        let mut read = &*rarc.lock().unwrap();
        let mut write = &*warc.lock().unwrap();

        future::try_join(
            send(&mut write, &mut local_outgoint_packets),
            recv(&mut read, &mut local_incoming_packets),
        )
        .await;
    });

    loop {
        //read & write other stuff on both incoming_packets & outgoint_packets
        //until the end of the program
    }
}

async fn recv(reader: &mut ReadHalf<'_>, queue: &mut Arc<SharedPackets>) -> Result<(), io::Error> {
    loop {
        let mut buf: Vec<u8> = vec![0; 4096];

        let n = match reader.read(&mut buf).await {
            Ok(n) if n == 0 => return Ok(()),
            Ok(n) => n,
            Err(e) => {
                eprintln!("failed to read from socket; err = {:?}", e);
                return Err(e);
            }
        };
    }
}

async fn send(writer: &mut WriteHalf<'_>, queue: &mut Arc<SharedPackets>) -> Result<(), io::Error> {
    loop {
        //task::sleep(Duration::from_millis(300)).await;
        {
            let a = vec!["AAAA"];
            for i in a.iter() {
                let mut byte_array = vec![];
                let str_bytes = i.as_bytes();
                WriteBytesExt::write_u32::<BigEndian>(&mut byte_array, str_bytes.len() as u32)
                    .unwrap();
                byte_array.extend(str_bytes);

                writer.write(&byte_array).await?;
            }
        }
    }
}

This does not compile:

error: future cannot be sent between threads safely
   --> src/main.rs:46:5
    |
46  |     tokio::spawn(async move {
    |     ^^^^^^^^^^^^ future created by async block is not `Send`
    | 
   ::: /playground/.cargo/registry/src/github.com-1ecc6299db9ec823/tokio-0.2.21/src/task/spawn.rs:127:21
    |
127 |         T: Future + Send + 'static,
    |                     ---- required by this bound in `tokio::spawn`
    |
    = help: within `impl futures::Future`, the trait `std::marker::Send` is not implemented for `std::sync::MutexGuard<'_, tokio::net::tcp::ReadHalf<'_>>`
note: future is not `Send` as this value is used across an await
   --> src/main.rs:55:9
    |
52  |           let mut read = &*rarc.lock().unwrap();
    |                            -------------------- has type `std::sync::MutexGuard<'_, tokio::net::tcp::ReadHalf<'_>>` which is not `Send`
...
55  | /         future::try_join(
56  | |             send(&mut write, &mut local_outgoint_packets),
57  | |             recv(&mut read, &mut local_incoming_packets),
58  | |         )
59  | |         .await;
    | |______________^ await occurs here, with `rarc.lock().unwrap()` maybe used later
60  |       });
    |       - `rarc.lock().unwrap()` is later dropped here
help: consider moving this into a `let` binding to create a shorter lived borrow
   --> src/main.rs:52:25
    |
52  |         let mut read = &*rarc.lock().unwrap();
    |                         ^^^^^^^^^^^^^^^^^^^^^

error: future cannot be sent between threads safely
   --> src/main.rs:46:5
    |
46  |     tokio::spawn(async move {
    |     ^^^^^^^^^^^^ future created by async block is not `Send`
    | 
   ::: /playground/.cargo/registry/src/github.com-1ecc6299db9ec823/tokio-0.2.21/src/task/spawn.rs:127:21
    |
127 |         T: Future + Send + 'static,
    |                     ---- required by this bound in `tokio::spawn`
    |
    = help: within `impl futures::Future`, the trait `std::marker::Send` is not implemented for `std::sync::MutexGuard<'_, tokio::net::tcp::WriteHalf<'_>>`
note: future is not `Send` as this value is used across an await
   --> src/main.rs:55:9
    |
53  |           let mut write = &*warc.lock().unwrap();
    |                             -------------------- has type `std::sync::MutexGuard<'_, tokio::net::tcp::WriteHalf<'_>>` which is not `Send`
54  | 
55  | /         future::try_join(
56  | |             send(&mut write, &mut local_outgoint_packets),
57  | |             recv(&mut read, &mut local_incoming_packets),
58  | |         )
59  | |         .await;
    | |______________^ await occurs here, with `warc.lock().unwrap()` maybe used later
60  |       });
    |       - `warc.lock().unwrap()` is later dropped here
help: consider moving this into a `let` binding to create a shorter lived borrow
   --> src/main.rs:53:26
    |
53  |         let mut write = &*warc.lock().unwrap();
    |                          ^^^^^^^^^^^^^^^^^^^^^

I think this is the least of the problems, because I'm really new with tokio.

I could not find an example of this, do you know any performant approach to this problem?

9
  • 1
    Did you try moving the cloning of the packets outside the closure? Also, you should never really be passing a reference to an Arc. The whole point of the Arc is that you can clone it without actually creating a copy of all the underlying data. I strongly suggest that you get this down to an example that someone can at least try to compile on their machine in a single file. – richardpringle Jul 21 '20 at 16:32
  • Yes! but i still have a problem when i try to run a future inside a thread, it also does not work. Most of the stuff i tried end up on this problem future created by async block is not "Send" – Ollegn Jul 21 '20 at 17:02
  • I did update my question to address your comment @richardpringle , with a try to also use arc with the Read/Write Halves, but with no success. – Ollegn Jul 21 '20 at 17:08
  • It's hard to answer your question because it doesn't include a minimal reproducible example. We can't tell what crates (and their versions), types, traits, fields, etc. are present in the code. It would make it easier for us to help you if you try to reproduce your error on the Rust Playground if possible, otherwise in a brand new Cargo project, then edit your question to include the additional info. There are Rust-specific MRE tips you can use to reduce your original code for posting here. Thanks! – Shepmaster Jul 21 '20 at 17:11
  • You keep using the word thread, but threads are a specific thing. You never create any threads in the code shown here. Tokio may (or may not!) create threads and your code may (or may not!) actually run on different threads. Why do you have the requirement to have multiple threads? – Shepmaster Jul 21 '20 at 17:15
0
+50

Why don't you use channels for sending/receiveing data from/to other tasks? There's a plenty of helpful examples here how to share data between tasks

EDIT: I looked at your code, noticed you're using wrong mutex. You should use tokio::sync::Mutex when dealing with async code. Secondly, there were issues with references in arc. I've moved creating arcs to spawned task and add cloning to send/reacv functions.

extern crate futures; // 0.3.5; // 0.1.36std;
extern crate tokio; // 0.2.21;
extern crate byteorder; // 1.3.4;


use std::{error::Error};
use std::sync::{Arc};
use tokio::sync::Mutex;
use tokio::net::TcpStream;
use futures::{future};
use bytes::Bytes;

use std::io;
use std::time::Duration;
use tokio::io::AsyncWriteExt;
use tokio::io::AsyncReadExt;
use tokio::net::tcp::{ReadHalf, WriteHalf};
use byteorder::{BigEndian, WriteBytesExt};




//This is the SharedPackets struct that is located in the crate structures
struct SharedPackets {
   data: Mutex<Vec<bytes::Bytes>>
}


#[tokio::main]
async fn main() -> Result<(), Box<dyn Error>> {
    
    let mut inc : Vec<bytes::Bytes> = Vec::new();
    inc.push(Bytes::from("Wow"));

    let mut incoming_packets = Arc::new(SharedPackets {
        data: Mutex::new(inc)
    });

    let mut outg : Vec<bytes::Bytes> = Vec::new();
    outg.push(Bytes::from("Wow"));
    let mut outgoint_packets = Arc::new(SharedPackets {
        data: Mutex::new(outg)
    });

    let mut local_incoming_packets = Arc::clone(&incoming_packets);
    let mut local_outgoint_packets = Arc::clone(&outgoint_packets);
   

    tokio::spawn(async move {
    let mut stream = TcpStream::connect("127.0.0.1:8080").await.unwrap();
    let (mut r, mut w) = stream.split();
    let mut rarc = Arc::new(Mutex::new(& mut r));
    let mut warc = Arc::new(Mutex::new(& mut w));
 

        //send and receive are both async functions that contain an infinite loop
        //they basically use AsyncWriteExt and AsyncReadExt to manipulate both halves of the stream
        //send reads the queue and write this data on the socket
        //recv reads the socket and write this data on the queue
        //both "queues" are manipulated by the main thread
        //let mut read = &*rarc.lock().await;
        //let mut write = &*warc.lock().await;

        future::try_join(send(warc.clone(), &mut local_outgoint_packets), recv(rarc.clone(), &mut local_incoming_packets)).await;
    });

   
    loop {
        //read & write other stuff on both incoming_packets & outgoint_packets
        //until the end of the program
    }
}


async fn recv(readerw: Arc<Mutex<&mut ReadHalf<'_>>>, queue: &mut Arc<SharedPackets>) -> Result<(), io::Error> {
let mut reader = readerw.lock().await;
loop {

    let mut buf : Vec<u8> = vec![0; 4096];

    let n = match reader.read(&mut buf).await {
        Ok(n) if n == 0 => return Ok(()),
        Ok(n) => n,
        Err(e) => {
            eprintln!("failed to read from socket; err = {:?}", e);
            return Err(e);
        }
    };                   
}
}



async fn send(writerw: Arc<Mutex<&mut WriteHalf<'_>>>, queue: &mut Arc<SharedPackets>) -> Result<(), io::Error> {
let mut writer = writerw.lock().await;
loop{
     //task::sleep(Duration::from_millis(300)).await;
     { 
         let a = vec!["AAAA"];
         for i in a.iter() {
            let mut byte_array = vec![];
            let str_bytes = i.as_bytes();
            WriteBytesExt::write_u32::<BigEndian>(&mut byte_array, str_bytes.len() as u32).unwrap();
            byte_array.extend(str_bytes);

            writer.write(&byte_array).await?;
         }
     }
}
}

Here is full code without errors, didn't test it though: Playground link

4
  • Aren't mpsc channels some sort of IPC? they don't look like they can support remote protocols like TCP/UPD Streams, basically falling of the scope of the question Altogether, (at least it is what it seems by the mentioned link). – Ollegn Jul 23 '20 at 22:50
  • yes, but if in your use-case you could read a value from TcpStream and propagate it through channel to other tasks, it would be useful. But it seems to me you want to send stream reader and writer directly somewhere. – ktrapez Jul 24 '20 at 8:49
  • Btw I’ve edited post and fixed things causing build errors, maybe that will help you. – ktrapez Jul 27 '20 at 20:43
  • i'm testing your answer on my real code, i'll update after i finish some tests – Ollegn Jul 28 '20 at 16:26
-1

Here's an example that's a bit contrived, but it should help:

Playground link

use std::{sync::Arc, time::Duration};
use tokio::{self, net::TcpStream, sync::Mutex};

#[tokio::main]
async fn main() {
    let mut incoming_packets = Arc::new(Mutex::new(vec![b"Wow".to_vec()]));

    let mut local_incoming_packets = incoming_packets.clone();

    tokio::spawn(async move {
        for i in 0usize..10 {
            tokio::time::delay_for(Duration::from_millis(200)).await;
            let mut packets = local_incoming_packets.lock().await;

            packets.push(i.to_ne_bytes().to_vec());
        }
    });

    loop {
        tokio::time::delay_for(Duration::from_millis(200)).await;
        let packets = incoming_packets.lock().await;
        dbg!(packets);
    }
}

You can see that I have to clone outside of the async move block since that block takes ownership of everything inside it. I'm not sure about r and w but you might need to move those inside the block as well before you can pass mutable references to them. I can update my answer if you provide code that includes all of the proper use statements.

One thing that you need to remember is that main() can technically exit before the code that has been spawned.

Also, note that I used tokio::sync::Mutex so that you can yield while waiting to acquire the lock.

1
  • Thanks for the answer, but i still can't send packets with tokio using a TcpStream – Ollegn Jul 21 '20 at 12:51

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