How does Task.Yield work under the hood in Blazor WebAssembly?

Question

How does Task.Yield work under the hood in Mono/WASM runtime (which is used by Blazor WebAssembly)?

To clarify, I believe I have a good understanding of how Task.Yield works in .NET Framework and .NET Core. Mono implementation doesn't look much different, in a nutshell, it comes down to this:

static Task Yield() 
{
    var tcs = new TaskCompletionSource<bool>();
    System.Threading.ThreadPool.QueueUserWorkItem(_ => tcs.TrySetResult(true));
    return tcs.Task;
}

Surprisingly, this works in Blazor WebAssembly, too (try it online):

<label>Tick Count: @tickCount</label><br>

@code 
{
    int tickCount = System.Environment.TickCount;

    protected override void OnAfterRender(bool firstRender)
    {
        if (firstRender) CountAsync();
    }

    static Task Yield() 
    {
        var tcs = new TaskCompletionSource<bool>();
        System.Threading.ThreadPool.QueueUserWorkItem(_ => tcs.TrySetResult(true));
        return tcs.Task;
    }

    async void CountAsync() 
    {
        for (var i = 0; i < 10000; i++) 
        {
            await Yield();
            tickCount = System.Environment.TickCount;
            StateHasChanged();
        }
    }
}

Naturally, it all happens on the same event loop thread in the browser, so I wonder how it works on the lower level.

I suspect, it might be utilizing something like Emscripten's Asyncify, but eventually, does it use some sort of Web Platform API to schedule a continuation callback? And if so, which one exactly (like queueMicrotask, setTimout, Promise.resove().then, etc)?

---

Updated, I've just discovered that Thread.Sleep is implemented as well and it actually blocks the event loop thread 👀

Curious about how that works on the WebAssembly level, too. With JavaScript, I can only think of a busy loop to simulate Thread.Sleep (as Atomics.wait is only available from web worker threads).

Answer 1

It’s setTimeout. There is considerable indirection between that and QueueUserWorkItem, but this is where it bottoms out.

Most of the WebAssembly-specific machinery can be seen in PR 38029. The WebAssembly implementation of RequestWorkerThread calls a private method named QueueCallback, which is implemented in C code as mono_wasm_queue_tp_cb. This in invokes mono_threads_schedule_background_job, which in turn calls schedule_background_exec, which is implemented in TypeScript as:

export function schedule_background_exec(): void {
    ++pump_count;
    if (typeof globalThis.setTimeout === "function") {
        globalThis.setTimeout(pump_message, 0);
    }
}

The setTimeout callback eventually reaches ThreadPool.Callback, which invokes ThreadPoolWorkQueue.Dispatch.

The rest of it is not specific to Blazor at all, and can be studied by reading the source code of the ThreadPoolWorkQueue class. In short, ThreadPool.QueueUserWorkItem enqueues the callback in a ThreadPoolQueue. Enqueueing calls EnsureThreadRequested, which delegates to RequestWorkerThread, implemented as above. ThreadPoolWorkQueue.Dispatch causes some number of asynchronous tasks to be dequeued and executed; among them, the callback passed to QueueUserWorkItem should eventually appear.