wasmtime/tests/all/async_functions.rs

use anyhow::Result;
use std::future::Future;
use std::pin::Pin;
use std::task::{Context, Poll, RawWaker, RawWakerVTable, Waker};
use wasmtime::*;

fn async_store() -> Store<()> {
    Store::new(&Engine::new(Config::new().async_support(true)).unwrap(), ())
}

fn run_smoke_test(store: &mut Store<()>, func: Func) {
    run(func.call_async(&mut *store, &[])).unwrap();
    run(func.call_async(&mut *store, &[])).unwrap();
}

fn run_smoke_typed_test(store: &mut Store<()>, func: Func) {
    let func = func.typed::<(), (), _>(&store).unwrap();
    run(func.call_async(&mut *store, ())).unwrap();
    run(func.call_async(&mut *store, ())).unwrap();
}

#[test]
fn smoke() {
    let mut store = async_store();
    let func = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        move |_caller, _params, _results| Box::new(async { Ok(()) }),
    );
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);

    let func = Func::wrap0_async(&mut store, move |_caller| Box::new(async { Ok(()) }));
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);
}

#[test]
fn smoke_host_func() -> Result<()> {
    let mut store = async_store();
    let mut linker = Linker::new(store.engine());

    linker.func_new_async(
        "",
        "first",
        FuncType::new(None, None),
        move |_caller, _params, _results| Box::new(async { Ok(()) }),
    )?;

    linker.func_wrap0_async("", "second", move |_caller| Box::new(async { Ok(()) }))?;

    let func = linker
        .get(&mut store, "", Some("first"))
        .unwrap()
        .into_func()
        .unwrap();
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);

    let func = linker
        .get(&mut store, "", Some("second"))
        .unwrap()
        .into_func()
        .unwrap();
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);

    Ok(())
}

#[test]
fn smoke_with_suspension() {
    let mut store = async_store();
    let func = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        move |_caller, _params, _results| {
            Box::new(async {
                PendingOnce::default().await;
                Ok(())
            })
        },
    );
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);

    let func = Func::wrap0_async(&mut store, move |_caller| {
        Box::new(async {
            PendingOnce::default().await;
            Ok(())
        })
    });
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);
}

#[test]
fn smoke_host_func_with_suspension() -> Result<()> {
    let mut store = async_store();
    let mut linker = Linker::new(store.engine());

    linker.func_new_async(
        "",
        "first",
        FuncType::new(None, None),
        move |_caller, _params, _results| {
            Box::new(async {
                PendingOnce::default().await;
                Ok(())
            })
        },
    )?;

    linker.func_wrap0_async("", "second", move |_caller| {
        Box::new(async {
            PendingOnce::default().await;
            Ok(())
        })
    })?;

    let func = linker
        .get(&mut store, "", Some("first"))
        .unwrap()
        .into_func()
        .unwrap();
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);

    let func = linker
        .get(&mut store, "", Some("second"))
        .unwrap()
        .into_func()
        .unwrap();
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);

    Ok(())
}

#[test]
fn recursive_call() {
    let mut store = async_store();
    let async_wasm_func = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        |_caller, _params, _results| {
            Box::new(async {
                PendingOnce::default().await;
                Ok(())
            })
        },
    );

    // Create an imported function which recursively invokes another wasm
    // function asynchronously, although this one is just our own host function
    // which suffices for this test.
    let func2 = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        move |mut caller, _params, _results| {
            Box::new(async move {
                async_wasm_func.call_async(&mut caller, &[]).await?;
                Ok(())
            })
        },
    );

    // Create an instance which calls an async import twice.
    let module = Module::new(
        store.engine(),
        "
            (module
                (import \"\" \"\" (func))
                (func (export \"\")
                    ;; call imported function which recursively does an async
                    ;; call
                    call 0
                    ;; do it again, and our various pointers all better align
                    call 0))
        ",
    )
    .unwrap();

    run(async {
        let instance = Instance::new_async(&mut store, &module, &[func2.into()]).await?;
        let func = instance.get_func(&mut store, "").unwrap();
        func.call_async(&mut store, &[]).await
    })
    .unwrap();
}

#[test]
fn suspend_while_suspending() {
    let mut store = async_store();

    // Create a synchronous function which calls our asynchronous function and
    // runs it locally. This shouldn't generally happen but we know everything
    // is synchronous in this test so it's fine for us to do this.
    //
    // The purpose of this test is intended to stress various cases in how
    // we manage pointers in ways that are not necessarily common but are still
    // possible in safe code.
    let async_thunk = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        |_caller, _params, _results| Box::new(async { Ok(()) }),
    );
    let sync_call_async_thunk = Func::new(
        &mut store,
        FuncType::new(None, None),
        move |mut caller, _params, _results| {
            run(async_thunk.call_async(&mut caller, &[]))?;
            Ok(())
        },
    );

    // A small async function that simply awaits once to pump the loops and
    // then finishes.
    let async_import = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        move |_caller, _params, _results| {
            Box::new(async move {
                PendingOnce::default().await;
                Ok(())
            })
        },
    );

    let module = Module::new(
        store.engine(),
        "
            (module
                (import \"\" \"\" (func $sync_call_async_thunk))
                (import \"\" \"\" (func $async_import))
                (func (export \"\")
                    ;; Set some store-local state and pointers
                    call $sync_call_async_thunk
                    ;; .. and hopefully it's all still configured correctly
                    call $async_import))
        ",
    )
    .unwrap();
    run(async {
        let instance = Instance::new_async(
            &mut store,
            &module,
            &[sync_call_async_thunk.into(), async_import.into()],
        )
        .await?;
        let func = instance.get_func(&mut store, "").unwrap();
        func.call_async(&mut store, &[]).await
    })
    .unwrap();
}

#[test]
fn cancel_during_run() {
    let mut store = Store::new(&Engine::new(Config::new().async_support(true)).unwrap(), 0);

    let async_thunk = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        move |mut caller, _params, _results| {
            assert_eq!(*caller.data(), 0);
            *caller.data_mut() = 1;
            let dtor = SetOnDrop(caller);
            Box::new(async move {
                drop(&dtor);
                PendingOnce::default().await;
                Ok(())
            })
        },
    );
    // Shouldn't have called anything yet...
    assert_eq!(*store.data(), 0);

    // Create our future, but as per async conventions this still doesn't
    // actually do anything. No wasm or host function has been called yet.
    let mut future = Pin::from(Box::new(async_thunk.call_async(&mut store, &[])));

    // Push the future forward one tick, which actually runs the host code in
    // our async func. Our future is designed to be pending once, however.
    let poll = future
        .as_mut()
        .poll(&mut Context::from_waker(&dummy_waker()));
    assert!(poll.is_pending());

    // Now that our future is running (on a separate, now-suspended fiber), drop
    // the future and that should deallocate all the Rust bits as well.
    drop(future);
    assert_eq!(*store.data(), 2);

    struct SetOnDrop<'a>(Caller<'a, usize>);

    impl Drop for SetOnDrop<'_> {
        fn drop(&mut self) {
            assert_eq!(*self.0.data(), 1);
            *self.0.data_mut() = 2;
        }
    }
}

#[derive(Default)]
struct PendingOnce {
    already_polled: bool,
}

impl Future for PendingOnce {
    type Output = ();

    fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll<()> {
        if self.already_polled {
            Poll::Ready(())
        } else {
            self.already_polled = true;
            cx.waker().wake_by_ref();
            Poll::Pending
        }
    }
}

fn run<F: Future>(future: F) -> F::Output {
    let mut f = Pin::from(Box::new(future));
    let waker = dummy_waker();
    let mut cx = Context::from_waker(&waker);
    loop {
        match f.as_mut().poll(&mut cx) {
            Poll::Ready(val) => break val,
            Poll::Pending => {}
        }
    }
}

fn dummy_waker() -> Waker {
    return unsafe { Waker::from_raw(clone(5 as *const _)) };

    unsafe fn clone(ptr: *const ()) -> RawWaker {
        assert_eq!(ptr as usize, 5);
        const VTABLE: RawWakerVTable = RawWakerVTable::new(clone, wake, wake_by_ref, drop);
        RawWaker::new(ptr, &VTABLE)
    }

    unsafe fn wake(ptr: *const ()) {
        assert_eq!(ptr as usize, 5);
    }

    unsafe fn wake_by_ref(ptr: *const ()) {
        assert_eq!(ptr as usize, 5);
    }

    unsafe fn drop(ptr: *const ()) {
        assert_eq!(ptr as usize, 5);
    }
}

#[test]
fn iloop_with_fuel() {
    let engine = Engine::new(Config::new().async_support(true).consume_fuel(true)).unwrap();
    let mut store = Store::new(&engine, ());
    store.out_of_fuel_async_yield(1_000, 10);
    let module = Module::new(
        &engine,
        "
            (module
                (func (loop br 0))
                (start 0)
            )
        ",
    )
    .unwrap();
    let instance = Instance::new_async(&mut store, &module, &[]);
    let mut f = Pin::from(Box::new(instance));
    let waker = dummy_waker();
    let mut cx = Context::from_waker(&waker);

    // This should yield a bunch of times...
    for _ in 0..100 {
        assert!(f.as_mut().poll(&mut cx).is_pending());
    }

    // ... but it should eventually also finish.
    loop {
        match f.as_mut().poll(&mut cx) {
            Poll::Ready(_) => break,
            Poll::Pending => {}
        }
    }
}

#[test]
fn fuel_eventually_finishes() {
    let engine = Engine::new(Config::new().async_support(true).consume_fuel(true)).unwrap();
    let mut store = Store::new(&engine, ());
    store.out_of_fuel_async_yield(u32::max_value(), 10);
    let module = Module::new(
        &engine,
        "
            (module
                (func
                    (local i32)
                    i32.const 100
                    local.set 0
                    (loop
                        local.get 0
                        i32.const -1
                        i32.add
                        local.tee 0
                        br_if 0)
                )
                (start 0)
            )
        ",
    )
    .unwrap();
    let instance = Instance::new_async(&mut store, &module, &[]);
    run(instance).unwrap();
}

#[test]
fn async_with_pooling_stacks() {
    let mut config = Config::new();
    config.async_support(true);
    config.allocation_strategy(InstanceAllocationStrategy::Pooling {
        strategy: PoolingAllocationStrategy::NextAvailable,
        module_limits: ModuleLimits {
            memory_pages: 1,
            table_elements: 0,
            ..Default::default()
        },
        instance_limits: InstanceLimits {
            count: 1,
            memory_reservation_size: 1,
        },
    });

    let engine = Engine::new(&config).unwrap();
    let mut store = Store::new(&engine, ());
    let func = Func::new_async(
        &mut store,
        FuncType::new(None, None),
        move |_caller, _params, _results| Box::new(async { Ok(()) }),
    );

    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);
}

#[test]
fn async_host_func_with_pooling_stacks() -> Result<()> {
    let mut config = Config::new();
    config.async_support(true);
    config.allocation_strategy(InstanceAllocationStrategy::Pooling {
        strategy: PoolingAllocationStrategy::NextAvailable,
        module_limits: ModuleLimits {
            memory_pages: 1,
            table_elements: 0,
            ..Default::default()
        },
        instance_limits: InstanceLimits {
            count: 1,
            memory_reservation_size: 1,
        },
    });

    let mut store = Store::new(&Engine::new(&config)?, ());
    let mut linker = Linker::new(store.engine());
    linker.func_new_async(
        "",
        "",
        FuncType::new(None, None),
        move |_caller, _params, _results| Box::new(async { Ok(()) }),
    )?;

    let func = linker
        .get(&mut store, "", Some(""))
        .unwrap()
        .into_func()
        .unwrap();
    run_smoke_test(&mut store, func);
    run_smoke_typed_test(&mut store, func);
    Ok(())
}

fn execute_across_threads<F: Future + Send + 'static>(future: F) {
    let mut future = Pin::from(Box::new(future));
    let poll = future
        .as_mut()
        .poll(&mut Context::from_waker(&dummy_waker()));
    assert!(poll.is_pending());

    std::thread::spawn(move || {
        let poll = future
            .as_mut()
            .poll(&mut Context::from_waker(&dummy_waker()));
        assert!(!poll.is_pending());
    })
    .join()
    .unwrap();
}

#[test]
fn resume_separate_thread() {
    // This test will poll the following future on two threads. Simulating a
    // trap requires accessing TLS info, so that should be preserved correctly.
    execute_across_threads(async {
        let mut store = async_store();
        let module = Module::new(
            store.engine(),
            "
            (module
                (import \"\" \"\" (func))
                (start 0)
            )
            ",
        )
        .unwrap();
        let func = Func::wrap0_async(&mut store, |_| {
            Box::new(async {
                PendingOnce::default().await;
                Err::<(), _>(wasmtime::Trap::new("test"))
            })
        });
        let result = Instance::new_async(&mut store, &module, &[func.into()]).await;
        assert!(result.is_err());
    });
}

#[test]
fn resume_separate_thread2() {
    // This test will poll the following future on two threads. Catching a
    // signal requires looking up TLS information to determine whether it's a
    // trap to handle or not, so that must be preserved correctly across threads.
    execute_across_threads(async {
        let mut store = async_store();
        let module = Module::new(
            store.engine(),
            "
            (module
                (import \"\" \"\" (func))
                (func $start
                    call 0
                    unreachable)
                (start $start)
            )
            ",
        )
        .unwrap();
        let func = Func::wrap0_async(&mut store, |_| {
            Box::new(async { PendingOnce::default().await })
        });
        let result = Instance::new_async(&mut store, &module, &[func.into()]).await;
        assert!(result.is_err());
    });
}

#[test]
fn resume_separate_thread3() {
    // This test doesn't actually do anything with cross-thread polls, but
    // instead it deals with scheduling futures at "odd" times.
    //
    // First we'll set up a *synchronous* call which will initialize TLS info.
    // This call is simply to a host-defined function, but it still has the same
    // "enter into wasm" semantics since it's just calling a trampoline. In this
    // situation we'll set up the TLS info so it's in place while the body of
    // the function executes...
    let mut store = Store::new(&Engine::default(), None);
    let f = Func::wrap(&mut store, move |mut caller: Caller<'_, _>| {
        // ... and the execution of this host-defined function (while the TLS
        // info is initialized), will set up a recursive call into wasm. This
        // recursive call will be done asynchronously so we can suspend it
        // halfway through.
        let f = async {
            let mut store = async_store();
            let module = Module::new(
                store.engine(),
                "
                    (module
                        (import \"\" \"\" (func))
                        (start 0)
                    )
                ",
            )
            .unwrap();
            let func = Func::wrap0_async(&mut store, |_| {
                Box::new(async { PendingOnce::default().await })
            });
            drop(Instance::new_async(&mut store, &module, &[func.into()]).await);
            unreachable!()
        };
        let mut future = Pin::from(Box::new(f));
        let poll = future
            .as_mut()
            .poll(&mut Context::from_waker(&dummy_waker()));
        assert!(poll.is_pending());

        // ... so at this point our call into wasm is suspended. The call into
        // wasm will have overwritten TLS info, and we sure hope that the
        // information is restored at this point. Note that we squirrel away the
        // future somewhere else to get dropped later. If we were to drop it
        // here then we would reenter the future's suspended stack to clean it
        // up, which would do more alterations of TLS information we're not
        // testing here.
        *caller.data_mut() = Some(future);

        // ... all in all this function will need access to the original TLS
        // information to raise the trap. This TLS information should be
        // restored even though the asynchronous execution is suspended.
        Err::<(), _>(wasmtime::Trap::new(""))
    });
    assert!(f.call(&mut store, &[]).is_err());
}