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I have the following sample code that zooms each time a button is pressed:


<Window x:Class="WpfApplication12.MainWindow"
        Title="MainWindow" Height="350" Width="525">

    <Canvas x:Name="myCanvas">

            <ScaleTransform x:Name="myScaleTransform" />

        <Button Content="Button" 
                Click="myButton_Click" />


public partial class MainWindow : Window
    public MainWindow()

    private void myButton_Click(object sender, RoutedEventArgs e)
        Console.WriteLine("scale {0}, location: {1}", 

        myScaleTransform.ScaleX =
            myScaleTransform.ScaleY =
            myScaleTransform.ScaleX + 1;

        Console.WriteLine("scale {0}, location: {1}",

    private Point GetMyByttonLocation()
        return new Point(

the output is:

scale 1, location: 296;315
scale 2, location: 296;315

scale 2, location: 346;365
scale 3, location: 346;365

scale 3, location: 396;415
scale 4, location: 396;415

as you can see, there is a problem, that I thought solve by using Application.DoEvents(); but... it does not exist a priori in .NET 4.

What to do?

share|improve this question
Threading? Application.DoEvents() was the poor man's substitute for writing properly multi-threaded applications and extremely poor practice in any event. – Colin Mackay Dec 21 '10 at 17:25
I know that is poor and bad, but I prefer something that nothing at all. – serhio Dec 21 '10 at 17:27
up vote 13 down vote accepted

The old Application.DoEvents() method has been deprecated in WPF in favor of using a Dispatcher or a Background Worker Thread to do the processing as you have described. See the links for a couple of articles on how to use both objects.

If you absolutely must use Application.DoEvents(), then you could simply import the into your application and call the method. However, this really isn't recommended, since you're losing all the advantages that WPF provides.

share|improve this answer
I know that is poor and bad, but I prefer something that nothing at all... How can I use Dispatcher in my situation? – serhio Dec 21 '10 at 17:28
I understand your situation. I was in it when I wrote my first WPF app, but I went ahead and took the time to learn the new library and was much better for it in the long run. I highly recommend taking the time. As for your particular case, it looks to me like you'd want the dispatcher to handle the displaying of the coordinates every time your click event fires. You'd need to read up more on the Dispatcher for the exact implementation. – Dillie-O Dec 21 '10 at 17:36
no, I'd call Application.DoEvents after incrementing myScaleTransform.ScaleX. Don't know if is possible with Dispatcher. – serhio Dec 21 '10 at 17:39
Calling WinForms' DoEvents will not work. – SLaks Dec 21 '10 at 18:00
Removing Application.DoEvents() is almost as annoying as MS removing the "Start" button on Windows 8. – JeffHeaton Aug 1 '14 at 0:24

Try something like this

public static void DoEvents()
                                          new Action(delegate { }));
share|improve this answer
pretty cool. thanks very much. – serhio Dec 21 '10 at 17:42
I even wrote an extension method for application :) public static void DoEvents(this Application a) – serhio Dec 21 '10 at 17:46
@serhio: Neat extension method :) – Fredrik Hedblad Dec 21 '10 at 17:50
I should remark however that in the real application Application.Current sometimes is null... so perhaps its not quite equivalent. – serhio Dec 21 '10 at 18:10
This will not always work as it does not push the frame, if an interrupting instruction being made (I.e. a call to a WCF method which in a synchronic continue to this command) chances are you will not see 'refresh' as it will be blocked.. This is why the answer flq provided from the MSDN resource is more correct than this one. – G.Y Sep 26 '14 at 13:00

Well, I just hit a case where I start work on a method that runs on the Dispatcher thread, and it needs to block without blocking the UI Thread. Turns out that msdn explains how to implement a DoEvents() based on the Dispatcher itself:

public void DoEvents()
    DispatcherFrame frame = new DispatcherFrame();
        new DispatcherOperationCallback(ExitFrame), frame);

public object ExitFrame(object f)
    ((DispatcherFrame)f).Continue = false;

    return null;

(taken from Dispatcher.PushFrame Method)

share|improve this answer
Nice find! This looks safer than the suggested implementation by Meleak. I found a blog post about it – HugoRune Aug 10 '12 at 11:44
@HugoRune That blog post states this approach is unnecessary, and to use the same implementation as Meleak. – Lukazoid Oct 26 '12 at 15:52
@Lukazoid As far as I can tell the simple implementation may cause hard-to-trace lock-ups. (I am not sure about the cause, possibly the problem is code in the dispatcher queue calling DoEvents again, or code in the dispatcher queue generating further dispatcher frames.) In any case, the solution with exitFrame exhibited no such problems so I'd recommend that one. (Or, of course, not using doEvents at all) – HugoRune Oct 26 '12 at 19:03
@HugoRune I agree, I believe most situations requiring a DoEvents can be written differently in a way which does not require it. – Lukazoid Oct 27 '12 at 11:36
Showing an overlay on your window instead of a dialog in combination with caliburn's way to involve VMs when the app is closing ruled out callbacks and required us to block without blocking. I would be delighted if you present me a solution without the DoEvents hack. – flq Oct 27 '12 at 12:05

seems to work as well.

share|improve this answer
I'm going to use this since it seems a lot safer to me, but I'm going to keep the DoEvents for other cases. – Carter Feb 22 '13 at 22:04
Don't know why but this doesn't work for me. DoEvents() works fine. – miliu Feb 26 '13 at 18:17

One problem with both proposed approaches is that they entail idle CPU usage (up to 12% in my experience). This is suboptimal in some cases, for instance when modal UI behavior is implemented using this technique.

The following variation introduces a minimum delay between frames using a timer (note that it is written here with Rx but can be achieved with any regular timer):

 var minFrameDelay = Observable.Interval(TimeSpan.FromMilliseconds(50)).Take(1).Replay();
 // synchronously add a low-priority no-op to the Dispatcher's queue
 Application.Current.Dispatcher.Invoke(DispatcherPriority.Background, new Action(() => minFrameDelay.Wait()));
share|improve this answer

Since the introduction of async and await its now possible to relinquish the UI thread partway through a (formerly)* synchronous block of code using Task.Delay, e.g.

private async void myButton_Click(object sender, RoutedEventArgs e)
    Console.WriteLine("scale {0}, location: {1}", 

    myScaleTransform.ScaleX =
        myScaleTransform.ScaleY =
        myScaleTransform.ScaleX + 1;

    await Task.Delay(1); // In my experiments, 0 doesn't work. Also, I have noticed
                         // that I need to add as much as 100ms to allow the visual tree
                         // to complete its arrange cycle and for properties to get their
                         // final values (as opposed to NaN for widths etc.)

    Console.WriteLine("scale {0}, location: {1}",

I'll be honest, I've not tried it with the exact code above, but I use it in tight loops when I'm placing many items into an ItemsControl which has an expensive item template, sometimes adding a small delay to give the other stuff on the UI more time.

For example:

        var levelOptions = new ObservableCollection<GameLevelChoiceItem>();

        this.ViewModel[LevelOptionsViewModelKey] = levelOptions;

        var syllabus = await this.LevelRepository.GetSyllabusAsync();
        foreach (var level in syllabus.Levels)
            foreach (var subLevel in level.SubLevels)
                var abilities = new List<GamePlayingAbility>(100);

                foreach (var g in subLevel.Games)
                    var gwa = await this.MetricsRepository.GetGamePlayingAbilityAsync(g.Value);

                double PlayingScore = AssessmentMetricsProcessor.ComputePlayingLevelAbility(abilities);

                levelOptions.Add(new GameLevelChoiceItem()
                        LevelAbilityMetric = PlayingScore,
                        AbilityCaption = PlayingScore.ToString(),
                        LevelCaption = subLevel.Name,
                        LevelDescriptor = level.Ordinal + "." + subLevel.Ordinal,
                        LevelLevels = subLevel.Games.Select(g => g.Value),

                await Task.Delay(100);

On Windows Store, when there's a nice theme transition on the collection, the effect is quite desirable.


  • see comments. When I was quickly writing my answer, I was thinking about the act of taking a synchronous block of code and then relinquishing the thread back to its caller, the effect of which makes the block of code asynchronous. I don't want to completely rephrase my answer because then readers can't see what Servy and I were bickering about.
share|improve this answer
"its now possible to relinquish the UI thread partway through a synchronously block" No, it's not. You've just made the code asynchronous, rather than pumping messages from the UI thread in a synchronous method. Now, a correctly designed WPF application would be one that never blocks the UI thread by synchronously executing long running operations in the UI thread in the first place, using asynchrony to allow the existing message pump to pump messages appropriately. – Servy Nov 3 '14 at 18:36
@Servy Under the covers, the await will cause the compiler to to sign up the rest of the async method as a continuation on the awaited task. That continuation will occur on the UI thread (same sync context). Control then returns to the caller of the async method, i.e. WPFs eventing subsystem, where events will run until the scheduled continuation runs sometime after the delay period expires. – Luke Puplett Nov 3 '14 at 18:48
yes, I'm well aware of that. That's what makes the method asynchronous (the yielding control to the caller and only scheduling a continuation). Your answer states that the method is synchronous when it in fact is using asynchrony to update the UI. – Servy Nov 3 '14 at 18:53
The first method (the OP's code) is synchronous, Servy. The second example is just a tip for keeping the UI going when in a loop or having to pour items into a long list. – Luke Puplett Nov 3 '14 at 18:55
And what you've done is made the synchronous code asynchronous. You haven't kept the UI responsive from within a synchronous method, as your description states, or the answer asks for. – Servy Nov 3 '14 at 18:56

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