Exemplarische Vorgehensweise: Hosten von Direct3D9-Inhalt in WPF

In dieser exemplarischen Vorgehensweise wird gezeigt, wie Direct3D9-Inhalte in einer WPF-Anwendung (Windows Presentation Foundation) gehostet werden.

In dieser exemplarischen Vorgehensweise führen Sie folgende Aufgaben aus:

• Erstellen Sie ein WPF-Projekt, um den Direct3D9-Inhalt zu hosten.

• Importieren Sie den Direct3D9-Inhalt.

• Zeigen Sie den Direct3D9-Inhalt mithilfe der D3DImage-Klasse an.

Wenn Sie fertig sind, wissen Sie, wie Sie Direct3D9-Inhalte in einer WPF-Anwendung hosten.

Voraussetzungen

Zum Abschließen dieser exemplarischen Vorgehensweise benötigen Sie Folgendes:

• Visual Studio.

• DirectX SDK 9 oder höher.

• Eine DLL, die Direct3D9-Inhalte in einem WPF-kompatiblen Format enthält. Weitere Informationen finden Sie unter Interaktion zwischen WPF und Direct3D9 und Exemplarische Vorgehensweise: Erstellen von Direct3D9-Inhalten für das Hosting in WPF.

Erstellen des WPF-Projekts

Im ersten Schritt erstellen Sie das Projekt für die WPF-Anwendung.

So erstellen Sie das WPF-Projekt

Erstellen Sie ein neues WPF-Anwendungsprojekt in Visual C# mit dem Namen D3DHost. Weitere Informationen finden Sie unter Exemplarische Vorgehensweise: Meine erste WPF-Desktopanwendung.

„MainWindow.xaml“ wird im WPF-Designer geöffnet.

Importieren des Direct3D9-Inhalts

Sie importieren den Direct3D9-Inhalt aus einer nicht verwalteten DLL mithilfe des DllImport-Attributs.

So importieren Sie Direct3D9-Inhalte

1. Öffnen Sie „MainWindow.xaml.cs“ im Code-Editor.

2. Ersetzen Sie den automatisch generierten Code durch den folgenden Code.

   using System;
   using System.Collections.Generic;
   using System.Linq;
   using System.Text;
   using System.Windows;
   using System.Windows.Controls;
   using System.Windows.Data;
   using System.Windows.Documents;
   using System.Windows.Input;
   using System.Windows.Interop;
   using System.Windows.Media;
   using System.Windows.Media.Imaging;
   using System.Windows.Navigation;
   using System.Windows.Shapes;
   using System.Windows.Threading;
   using System.Runtime.InteropServices;
   using System.Security.Permissions;
   
   namespace D3DHost
   {
       public partial class MainWindow : Window
       {
           public MainWindow()
           {
               InitializeComponent();
   
               // Set up the initial state for the D3DImage.
               HRESULT.Check(SetSize(512, 512));
               HRESULT.Check(SetAlpha(false));
               HRESULT.Check(SetNumDesiredSamples(4));
   
               //
               // Optional: Subscribing to the IsFrontBufferAvailableChanged event.
               //
               // If you don't render every frame (e.g. you only render in
               // reaction to a button click), you should subscribe to the
               // IsFrontBufferAvailableChanged event to be notified when rendered content
               // is no longer being displayed. This event also notifies you when
               // the D3DImage is capable of being displayed again.
   
               // For example, in the button click case, if you don't render again when
               // the IsFrontBufferAvailable property is set to true, your
               // D3DImage won't display anything until the next button click.
               //
               // Because this application renders every frame, there is no need to
               // handle the IsFrontBufferAvailableChanged event.
               //
               CompositionTarget.Rendering += new EventHandler(CompositionTarget_Rendering);
   
               //
               // Optional: Multi-adapter optimization
               //
               // The surface is created initially on a particular adapter.
               // If the WPF window is dragged to another adapter, WPF
               // ensures that the D3DImage still shows up on the new
               // adapter.
               //
               // This process is slow on Windows XP.
               //
               // Performance is better on Vista with a 9Ex device. It's only
               // slow when the D3DImage crosses a video-card boundary.
               //
               // To work around this issue, you can move your surface when
               // the D3DImage is displayed on another adapter. To
               // determine when that is the case, transform a point on the
               // D3DImage into screen space and find out which adapter
               // contains that screen space point.
               //
               // When your D3DImage straddles two adapters, nothing
               // can be done, because one will be updating slowly.
               //
               _adapterTimer = new DispatcherTimer();
               _adapterTimer.Tick += new EventHandler(AdapterTimer_Tick);
               _adapterTimer.Interval = new TimeSpan(0, 0, 0, 0, 500);
               _adapterTimer.Start();
   
               //
               // Optional: Surface resizing
               //
               // The D3DImage is scaled when WPF renders it at a size
               // different from the natural size of the surface. If the
               // D3DImage is scaled up significantly, image quality
               // degrades.
               //
               // To avoid this, you can either create a very large
               // texture initially, or you can create new surfaces as
               // the size changes. Below is a very simple example of
               // how to do the latter.
               //
               // By creating a timer at Render priority, you are guaranteed
               // that new surfaces are created while the element
               // is still being arranged. A 200 ms interval gives
               // a good balance between image quality and performance.
               // You must be careful not to create new surfaces too
               // frequently. Frequently allocating a new surface may
               // fragment or exhaust video memory. This issue is more
               // significant on XDDM than it is on WDDM, because WDDM
               // can page out video memory.
               //
               // Another approach is deriving from the Image class,
               // participating in layout by overriding the ArrangeOverride method, and
               // updating size in the overriden method. Performance will degrade
               // if you resize too frequently.
               //
               // Blurry D3DImages can still occur due to subpixel
               // alignments.
               //
               _sizeTimer = new DispatcherTimer(DispatcherPriority.Render);
               _sizeTimer.Tick += new EventHandler(SizeTimer_Tick);
               _sizeTimer.Interval = new TimeSpan(0, 0, 0, 0, 200);
               _sizeTimer.Start();
           }
   
           ~MainWindow()
           {
               Destroy();
           }
   
           void AdapterTimer_Tick(object sender, EventArgs e)
           {
               POINT p = new POINT(imgelt.PointToScreen(new Point(0, 0)));
   
               HRESULT.Check(SetAdapter(p));
           }
   
           void SizeTimer_Tick(object sender, EventArgs e)
           {
               // The following code does not account for RenderTransforms.
               // To handle that case, you must transform up to the root and
               // check the size there.
   
               // Given that the D3DImage is at 96.0 DPI, its Width and Height
               // properties will always be integers. ActualWidth/Height
               // may not be integers, so they are cast to integers.
               uint actualWidth = (uint)imgelt.ActualWidth;
               uint actualHeight = (uint)imgelt.ActualHeight;
               if ((actualWidth > 0 && actualHeight > 0) &&
                   (actualWidth != (uint)d3dimg.Width || actualHeight != (uint)d3dimg.Height))
               {
                   HRESULT.Check(SetSize(actualWidth, actualHeight));
               }
           }
   
           void CompositionTarget_Rendering(object sender, EventArgs e)
           {
               RenderingEventArgs args = (RenderingEventArgs)e;
   
               // It's possible for Rendering to call back twice in the same frame
               // so only render when we haven't already rendered in this frame.
               if (d3dimg.IsFrontBufferAvailable && _lastRender != args.RenderingTime)
               {
                   IntPtr pSurface = IntPtr.Zero;
                   HRESULT.Check(GetBackBufferNoRef(out pSurface));
                   if (pSurface != IntPtr.Zero)
                   {
                       d3dimg.Lock();
                       // Repeatedly calling SetBackBuffer with the same IntPtr is
                       // a no-op. There is no performance penalty.
                       d3dimg.SetBackBuffer(D3DResourceType.IDirect3DSurface9, pSurface);
                       HRESULT.Check(Render());
                       d3dimg.AddDirtyRect(new Int32Rect(0, 0, d3dimg.PixelWidth, d3dimg.PixelHeight));
                       d3dimg.Unlock();
   
                       _lastRender = args.RenderingTime;
                   }
               }
           }
   
           DispatcherTimer _sizeTimer;
           DispatcherTimer _adapterTimer;
           TimeSpan _lastRender;
   
           // Import the methods exported by the unmanaged Direct3D content.
   
           [DllImport("D3DCode.dll")]
           static extern int GetBackBufferNoRef(out IntPtr pSurface);
   
           [DllImport("D3DCode.dll")]
           static extern int SetSize(uint width, uint height);
   
           [DllImport("D3DCode.dll")]
           static extern int SetAlpha(bool useAlpha);
   
           [DllImport("D3DCode.dll")]
           static extern int SetNumDesiredSamples(uint numSamples);
   
           [StructLayout(LayoutKind.Sequential)]
           struct POINT
           {
               public POINT(Point p)
               {
                   x = (int)p.X;
                   y = (int)p.Y;
               }
   
               public int x;
               public int y;
           }
   
           [DllImport("D3DCode.dll")]
           static extern int SetAdapter(POINT screenSpacePoint);
   
           [DllImport("D3DCode.dll")]
           static extern int Render();
   
           [DllImport("D3DCode.dll")]
           static extern void Destroy();
       }
   
       public static class HRESULT
       {
           public static void Check(int hr)
           {
               Marshal.ThrowExceptionForHR(hr);
           }
       }
   }
   

Hosting des Direct3D9-Inhalts

Verwenden Sie schließlich die D3DImage-Klasse, um den Direct3D9-Inhalt zu hosten.

So hosten Sie den Direct3D9-Inhalt

1. Ersetzen Sie in „MainWindow.xaml“ das automatisch generierte XAML durch das folgende XAML.

       <Window x:Class="D3DHost.MainWindow"
       xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation"
       xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
       xmlns:i="clr-namespace:System.Windows.Interop;assembly=PresentationCore"
       Title="MainWindow" Height="300" Width="300" Background="PaleGoldenrod">
       <Grid>
           <Image x:Name="imgelt">
               <Image.Source>
                   <i:D3DImage x:Name="d3dimg" />
               </Image.Source>
           </Image>
       </Grid>
   </Window>
   

2. Erstellen Sie das Projekt.

3. Kopieren Sie die DLL, die den Direct3D9-Inhalt enthält, in den Ordner „bin/Debug“.

4. Drücken Sie F5, um das Projekt auszuführen.

   Der Direct3D9-Inhalt wird in der WPF-Anwendung angezeigt.

Weitere Informationen

• D3DImage
• Überlegungen zur Leistung für die Interoperabilität zwischen Direct3D9 und WPF