Async Rust is powerful. And it can be a pain to work with (and learn). Async Rust can be a pleasure to work with, though, if we can do it without `Send + Sync + 'static`.
I skimmed the latter parts of this post since I felt like I read it all before, but I think moro is new to me. I was intrigued to find out how scoped span exactly behaves.
asyncfnslp() {
tokio::time::sleep(std::time::Duration::from_millis(1)).await
}
asyncfn_main() {
letvalue = 22;
letresult_fut = moro::async_scope!(|scope| {
dbg!(); // line 8letfuture1 = scope.spawn(async {
slp().await;
dbg!(); // line 11letfuture2 = scope.spawn(async {
slp().await;
dbg!(); // line 14
value // access stack values that outlive scope
});
slp().await;
dbg!(); // line 18letv = future2.await * 2;
v
});
slp().await;
dbg!(); // line 25letv = future1.await * 2;
slp().await;
dbg!(); // line 28
v
});
slp().await;
dbg!(); // line 32letresult = result_fut.await;
eprintln!("{result}"); // prints 88
}
fnmain() {
// same output with `new_current_thread()` of courseletrt = tokio::runtime::Builder::new_multi_thread()
.enable_all()
.build()
.unwrap();
rt.block_on(_main())
}
I think I would put the emphasis slightly differently: I don’t feel the confusion is around the word “spawn”, but it spawns futures rather than tasks. For tasks you might indeed expect them to be picked up in the background (which is what work-stealing does), but futures only execute when polled.
The most interesting part here is the polling only has to take place on the scope itself. That was actually what I wanted to check, but got distracted because all spawns are awaited in the scope in moro’s README example.
f1 and f2 are run concurrently, f3 is run after f2 finishes, but doesn’t have to wait for f1 to finish, which is maybe obvious, but… (see below).
So two things here:
Re-using the spawn terminology here irks me for some reason. I don’t know what would be better though. Would defer_to_scope() be confusing if the job is awaited in the scope?
Even if assumed obvious, a note about execution order when there is a mix of awaited and non-awaited jobs is worth adding to the documentation IMHO.
I skimmed the latter parts of this post since I felt like I read it all before, but I think
morois new to me. I was intrigued to find out how scopedspanexactly behaves.async fn slp() { tokio::time::sleep(std::time::Duration::from_millis(1)).await } async fn _main() { let value = 22; let result_fut = moro::async_scope!(|scope| { dbg!(); // line 8 let future1 = scope.spawn(async { slp().await; dbg!(); // line 11 let future2 = scope.spawn(async { slp().await; dbg!(); // line 14 value // access stack values that outlive scope }); slp().await; dbg!(); // line 18 let v = future2.await * 2; v }); slp().await; dbg!(); // line 25 let v = future1.await * 2; slp().await; dbg!(); // line 28 v }); slp().await; dbg!(); // line 32 let result = result_fut.await; eprintln!("{result}"); // prints 88 } fn main() { // same output with `new_current_thread()` of course let rt = tokio::runtime::Builder::new_multi_thread() .enable_all() .build() .unwrap(); rt.block_on(_main()) }This prints:
So scoped
spawndoesn’t really spawn tasks as one might mistakenly think!I think I would put the emphasis slightly differently: I don’t feel the confusion is around the word “spawn”, but it spawns futures rather than tasks. For tasks you might indeed expect them to be picked up in the background (which is what work-stealing does), but futures only execute when polled.
The most interesting part here is the polling only has to take place on the scope itself. That was actually what I wanted to check, but got distracted because all spawns are awaited in the scope in
moro’s README example.async fn slp() { tokio::time::sleep(std::time::Duration::from_millis(1)).await } async fn _main() { let result_fut = moro::async_scope!(|scope| { dbg!("d1"); scope.spawn(async { dbg!("f1a"); slp().await; slp().await; slp().await; dbg!("f1b"); }); dbg!("d2"); // 11 scope.spawn(async { dbg!("f2a"); slp().await; slp().await; dbg!("f2b"); }); dbg!("d3"); // 14 scope.spawn(async { dbg!("f3a"); slp().await; dbg!("f3b"); }); dbg!("d4"); async { dbg!("b1"); } // never executes }); slp().await; dbg!("o1"); let _ = result_fut.await; } fn main() { let rt = tokio::runtime::Builder::new_multi_thread() .enable_all() .build() .unwrap(); rt.block_on(_main()) }[src/main.rs:32:5] "o1" = "o1" [src/main.rs:7:9] "d1" = "d1" [src/main.rs:15:9] "d2" = "d2" [src/main.rs:22:9] "d3" = "d3" [src/main.rs:28:9] "d4" = "d4" [src/main.rs:9:13] "f1a" = "f1a" [src/main.rs:17:13] "f2a" = "f2a" [src/main.rs:24:13] "f3a" = "f3a" [src/main.rs:26:13] "f3b" = "f3b" [src/main.rs:20:13] "f2b" = "f2b" [src/main.rs:13:13] "f1b" = "f1b"The non-awaited jobs are run concurrently as the moro docs say. But what if we immediately await f2?
[src/main.rs:32:5] "o1" = "o1" [src/main.rs:7:9] "d1" = "d1" [src/main.rs:15:9] "d2" = "d2" [src/main.rs:9:13] "f1a" = "f1a" [src/main.rs:17:13] "f2a" = "f2a" [src/main.rs:20:13] "f2b" = "f2b" [src/main.rs:22:9] "d3" = "d3" [src/main.rs:28:9] "d4" = "d4" [src/main.rs:24:13] "f3a" = "f3a" [src/main.rs:13:13] "f1b" = "f1b" [src/main.rs:26:13] "f3b" = "f3b"f1 and f2 are run concurrently, f3 is run after f2 finishes, but doesn’t have to wait for f1 to finish, which is maybe obvious, but… (see below).
So two things here:
defer_to_scope()be confusing if the job is awaited in the scope?