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Stephen Toub describes in his article "The Task-based Asynchronous Pattern" that async methods that implement the Task-based Asynchronous Pattern (TAP) may even use a specific thread such as the UI thread to execute their code. That involves that async methods are allowed to use the calling thread. In this case the async method is not really async and blocks the calling thread. Is that really allowed? It wouldn’t make sense to create an async method that blocks the calling thread, or does it?

Here is the relevant clause of Stephen's article:

Target Environment

It is up to the TAP method’s implementation to determine where asynchronous execution occurs. The developer of the TAP method may choose to execute the workload on the ThreadPool, may choose to implement it using asynchronous I/O and thus without being bound to a thread for the majority of the operation’s execution, may choose to run on a specific thread as need-be, such as the UI thread, or any number of other potential contexts. It may even be the case that a TAP method has no execution to perform, returning a Task that simply represents the occurrence of a condition elsewhere in the system (e.g. a Task<TData> that represents TData arriving at a queued data structure).

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3 Answers 3

up vote 1 down vote accepted

The fact that the method (or part of it) may need to run on the UI thread doesn't mean it has to block, whether you call it from the UI thread or not.

Imagine you have a method Task DownloadAndShowData(), that asynchronously downloads some data and then shows it in the UI. To show the downloaded data on the UI, it needs to execute some code on the UI thread. You could implement it something like this:

async Task DownloadAndShowData()
{
    var data = await DownloadData();
    await uiSchedulerFactory.StartNew(() => ShowData(data));
}

Here, uiSchedulerFactory is a TaskFactory that executes the code on the UI thread (using SynchrnonizationContext).

In this code, the returned Task is completed only after the data is shown in the UI, which used the UI thread. But the method itself doesn't block. If you have a code like:

await DownloadAndShowData();
// some more code

executing on the UI thread, what happens is that when the await is reached, the current method is “paused”, and the UI thread is freed. After the download finishes, ShowData() from above is executed on the UI thread (it can execute, there is nothing blocking the thread). After that is done, the calling method is “unpaused” and // some more code executes.

To sum up, an async method execute some code on the UI thread (which could also be where the calling code is executing), but the async method does not block.

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Thanks for the answer, but I do not agree. How can it be that code that is executed in the UI thread does not block this thread? Maybe there is a misunderstanding in what blocking is. I double checked using a test app. When an async method schedules work to the UI thread the UI thread is definitely blocked. That means for example that a WPF window does not react on any user input as long as the "async" method is executed. See code in following comment. –  Jürgen Bayer Aug 12 '12 at 16:08
    
Here is my test code: private async void Demo() { double result = await CalculateAsync(1000000000); MessageBox.Show("Result: " + result); } private Task<double> CalculateAsync(int number) { TaskFactory uiSchedulerFactory = new TaskFactory(CancellationToken.None, TaskCreationOptions.None, TaskContinuationOptions.None, TaskScheduler.FromCurrentSynchronizationContext()); return uiSchedulerFactory.StartNew(() => { double result = 0; for (int i = 1; i <= number; i++) { result += Math.Sqrt(i); } return result; }); } –  Jürgen Bayer Aug 12 '12 at 16:09
    
The code that's executed on the UI thread does block it, but only for a short while. The thread is not blocked until the whole methods completes. I'll have a look at your example. –  svick Aug 12 '12 at 16:13
    
In your test code, you are performing long calculation on the UI thread, of course that will block it. But the CalculateAsync() method (or the Demo() method) itself doesn't block, it returns almost immediately. That's what I was talking about. –  svick Aug 12 '12 at 16:16
1  
Is it allowed? Yes. Is it a good idea? No. The quote doesn't say what kind of code you should or shouldn't execute on the UI thread, just that you can do that. –  svick Aug 12 '12 at 16:24

A call to await a method that returns a Task object simply delegates to that task object to start the invocation of it's task. From the caller of that task object's point of view, that task object may or may not have been already invoked. If it was already invoked, it may be completed by the time await gets to it, in which case, from the code at await's point of view, the task executes synchronously.

That's one instance. Another is that the Task knows what it needs to do; if what it needs to do can be done quicker synchronously it will simply do it synchronously. One example may be receiving data from a remote source. Many methods that receive data implement TAP, this is because data is being sent by a remote source and being received by your computer in the background. Calling a method to receive a byte "asynchronously" might already have that byte and it would simply be easier to return the byte synchronously. If, no bytes have been received yet then the method would run asynchronously waiting for a byte to be sent by the remote source. When that byte was received, it would inform the caller asynchronously through the continuation or the code following the await.

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Your second instance is a very good point that clarifies Stephen’s statement. –  Jürgen Bayer Aug 12 '12 at 16:48
    
One minor correction: a Task object returned from a TAP method must have been started. It may or may not be complete, but it cannot be in the TaskStatus.Created state. –  Stephen Cleary Aug 12 '12 at 17:55

You may find my async/await intro helpful, particularly the parts discussing the "context".

A common example is to download some information, parse it into a data structure, and then update the UI, like this:

private async Task GetInfoAndUpdateUIAsync()
{
  var info = await GetInfoAsync();
  UpdateUI(info);
}

private async Task<MyInfo> GetInfoAsync()
{
  using (var client = new HttpClient())
  {
    var httpResponse = await client.GetStringAsync(...);
    return MyInfo.Parse(httpResponse);
  }
}

Walkthrough

You can call GetInfoAndUpdateUIAsync from the UI context (e.g., an async void event handler).

When GetInfoAndUpdateUIAsync starts executing, it executes (synchronously) on the UI thread. The first thing it does is call GetInfoAsync.

GetInfoAsync also starts executing (synchronously) on the UI thread. It creates an HttpClient and then uses it to start downloading some data from a URL. When GetInfoAsync performs its await, it saves its state and returns an incomplete Task<MyInfo> to GetInfoAndUpdateUIAsync.

GetInfoAndUpdateUIAsync does an await on the returned Task<MyInfo>, which is not complete. So it also saves its state and returns. This continues on back up to the original caller (e.g., an async void event handler). The UI thread is now free to do other work.

When the HttpClient finishes downloading the data, its returned Task<string> will complete. This will schedule the continuation of GetInfoAsync on the UI thread.

GetInfoAsync will then continue executing on the UI thread. It parses the response into a data structure (MyInfo.Parse) while running on the UI thread, and then reaches the end of the method, completing the Task<MyInfo> task it returned earlier.

When the Task<MyInfo> completes, it schedules the continuation of GetInfoAndUpdateUIAsync to the UI thread. GetInfoAndUpdateUIAsync then calls UpdateUI(info) (synchronously) on the UI thread.

Conclusion

This is an example where various parts of the async methods will execute (synchronously) on the UI thread, yet the UI thread is not blocked.

When async methods continue after they await a Task, they will resume in the same context by default. This "context" is the current SynchronizationContext (e.g., the UI context) if it is not null, otherwise it's the current TaskScheduler. You can override the default behavior by awaiting the result of ConfigureAwait(false), which will cause the method continuation to run on a thread pool thread.

One More Note

In this example, we're doing some things on the UI thread that don't really have to be done on the UI thread. In particular, the parsing of the HTTP response into a MyInfo structure.

We can change GetInfoAsync to be a bit more efficient by overriding the default context capturing:

private async Task<MyInfo> GetInfoAsync()
{
  using (var client = new HttpClient())
  {
    var httpResponse = await client.GetStringAsync(...).ConfigureAwait(false);
    return MyInfo.Parse(httpResponse);
  }
}

Now, when the HTTP response comes in and GetInfoAsync continues executing, it will continue executing on a thread pool thread instead of the UI thread. So MyInfo.Parse will execute on the thread pool rather than the UI. When it's done parsing, the Task<MyInfo> will complete, and GetInfoAndUpdateUIAsync will continue executing on the UI thread.

We can't do the same thing with GetInfoAndUpdateUIAsync, because UpdateUI needs to run on the UI thread.

So this leads to a best practice: use ConfigureAwait(false) in your "library" async methods.

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A method decorated with async is not itself asynchronous. An async method is one that awaits another method that could be asynchronous (i.e. returns a Task-derived object). He's talking about TAP: methods that return Task and how the Task can be executed synchronously, if needed. This answer really has nothing to do with the question. –  Peter Ritchie Aug 12 '12 at 16:11
    
Thanks for the answer which is very informative. But it does not really answer my question. I was aware of how the synchronization context is handled. The actual problem was that it obviously is allowed that an async method not only execute code parts on the UI thread, but schedules all work to any thread, i.e. the UI thread (using a TaskFactory that works with the current sync context for example), and therefore blocks this thread for the time it is executed. –  Jürgen Bayer Aug 12 '12 at 16:15
    
@Peter: Disagree. My answer clearly describes how async methods may be asynchronous. Also, tasks returned from TAP methods cannot be executed synchronously. By definition, if they have a delegate, they are already started before returning. (By the definition of TAP, I mean). –  Stephen Cleary Aug 12 '12 at 16:41
    
@JürgenBayer: Is that really allowed? Yes, but not recommended. It wouldn’t make sense to create an async method that blocks the calling thread, or does it? No, it does not. –  Stephen Cleary Aug 12 '12 at 16:42
    
@StephenCleary Tasks can be a representation of a result, and thus are not executed asynchronously--they're not executed at all; but everything in that TAP implementation would have been executed synchronously (independent of async). As soon as an async method returns without having executed all its code, it's asynchronous. The fact that the rest of the code is run on the UI thread doesn't make it synchronous. Running at a "later time" makes it asynchronous. But, irrelevant, TAP is independent from async/await and can be implemented without it. i.e. the question was about TAP. –  Peter Ritchie Aug 12 '12 at 17:18

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