/**
  * Returns the Argb representation for the specified integer value which is packed in the format
  * of the associated ColorModel.
  */
 public int rgbFor(int pixel) {
   return surfaceType.rgbFor(pixel, colorModel);
 }
Пример #2
0
/**
 * This class describes a D3D "surface", that is, a region of pixels managed via D3D. An
 * D3DSurfaceData can be tagged with one of three different SurfaceType objects for the purpose of
 * registering loops, etc. This diagram shows the hierarchy of D3D SurfaceTypes:
 *
 * <p>Any / \ D3DSurface D3DTexture | D3DSurfaceRTT
 *
 * <p>D3DSurface This kind of surface can be rendered to using D3D APIs. It is also possible to copy
 * a D3DSurface to another D3DSurface (or to itself).
 *
 * <p>D3DTexture This kind of surface cannot be rendered to using D3D (in the same sense as in
 * D3DSurface). However, it is possible to upload a region of pixels to a D3DTexture object via
 * Lock/UnlockRect(). One can also copy a surface of type D3DTexture to a D3DSurface by binding the
 * texture to a quad and then rendering it to the destination surface (this process is known as
 * "texture mapping").
 *
 * <p>D3DSurfaceRTT This kind of surface can be thought of as a sort of hybrid between D3DSurface
 * and D3DTexture, in that one can render to this kind of surface as if it were of type D3DSurface,
 * but the process of copying this kind of surface to another is more like a D3DTexture. (Note that
 * "RTT" stands for "render-to-texture".)
 *
 * <p>In addition to these SurfaceType variants, we have also defined some constants that describe
 * in more detail the type of underlying D3D surface. This table helps explain the relationships
 * between those "type" constants and their corresponding SurfaceType:
 *
 * <p>D3D Type Corresponding SurfaceType -------- ------------------------- RT_PLAIN D3DSurface
 * TEXTURE D3DTexture FLIP_BACKBUFFER D3DSurface RT_TEXTURE D3DSurfaceRTT
 */
public class D3DSurfaceData extends SurfaceData implements AccelSurface {

  /**
   * To be used with getNativeResource() only.
   *
   * @see #getNativeResource()
   */
  public static final int D3D_DEVICE_RESOURCE = 100;
  /*
   * Surface types.
   * We use these surface types when copying from a sw surface
   * to a surface or texture.
   */
  public static final int ST_INT_ARGB = 0;
  public static final int ST_INT_ARGB_PRE = 1;
  public static final int ST_INT_ARGB_BM = 2;
  public static final int ST_INT_RGB = 3;
  public static final int ST_INT_BGR = 4;
  public static final int ST_USHORT_565_RGB = 5;
  public static final int ST_USHORT_555_RGB = 6;
  public static final int ST_BYTE_INDEXED = 7;
  public static final int ST_BYTE_INDEXED_BM = 8;
  public static final int ST_3BYTE_BGR = 9;

  /** Equals to D3DSWAPEFFECT_DISCARD */
  public static final int SWAP_DISCARD = 1;
  /** Equals to D3DSWAPEFFECT_FLIP */
  public static final int SWAP_FLIP = 2;
  /** Equals to D3DSWAPEFFECT_COPY */
  public static final int SWAP_COPY = 3;
  /*
   * SurfaceTypes
   */
  private static final String DESC_D3D_SURFACE = "D3D Surface";
  private static final String DESC_D3D_SURFACE_RTT = "D3D Surface (render-to-texture)";
  private static final String DESC_D3D_TEXTURE = "D3D Texture";

  // REMIND: regarding ArgbPre??
  static final SurfaceType D3DSurface =
      SurfaceType.Any.deriveSubType(DESC_D3D_SURFACE, PixelConverter.ArgbPre.instance);
  static final SurfaceType D3DSurfaceRTT = D3DSurface.deriveSubType(DESC_D3D_SURFACE_RTT);
  static final SurfaceType D3DTexture = SurfaceType.Any.deriveSubType(DESC_D3D_TEXTURE);

  private int type;
  private int width, height;
  // these fields are set from the native code when the surface is
  // initialized
  private int nativeWidth, nativeHeight;
  protected WComponentPeer peer;
  private Image offscreenImage;
  protected D3DGraphicsDevice graphicsDevice;

  private int swapEffect;
  private VSyncType syncType;
  private int backBuffersNum;

  private WritableRasterNative wrn;

  protected static D3DRenderer d3dRenderPipe;
  protected static PixelToParallelogramConverter d3dTxRenderPipe;
  protected static ParallelogramPipe d3dAAPgramPipe;
  protected static D3DTextRenderer d3dTextPipe;
  protected static D3DDrawImage d3dImagePipe;

  private native boolean initTexture(long pData, boolean isRTT, boolean isOpaque);

  private native boolean initFlipBackbuffer(
      long pData, long pPeerData, int numbuffers, int swapEffect, int syncType);

  private native boolean initRTSurface(long pData, boolean isOpaque);

  private native void initOps(int screen, int width, int height);

  static {
    D3DRenderQueue rq = D3DRenderQueue.getInstance();
    d3dImagePipe = new D3DDrawImage();
    d3dTextPipe = new D3DTextRenderer(rq);
    d3dRenderPipe = new D3DRenderer(rq);
    if (GraphicsPrimitive.tracingEnabled()) {
      d3dTextPipe = d3dTextPipe.traceWrap();
      d3dRenderPipe = d3dRenderPipe.traceWrap();
      // The wrapped d3dRenderPipe will wrap the AA pipe as well...
      // d3dAAPgramPipe = d3dRenderPipe.traceWrap();
    }
    d3dAAPgramPipe = d3dRenderPipe.getAAParallelogramPipe();
    d3dTxRenderPipe =
        new PixelToParallelogramConverter(d3dRenderPipe, d3dRenderPipe, 1.0, 0.25, true);

    D3DBlitLoops.register();
    D3DMaskFill.register();
    D3DMaskBlit.register();
  }

  protected D3DSurfaceData(
      WComponentPeer peer,
      D3DGraphicsConfig gc,
      int width,
      int height,
      Image image,
      ColorModel cm,
      int numBackBuffers,
      int swapEffect,
      VSyncType vSyncType,
      int type) {
    super(getCustomSurfaceType(type), cm);
    this.graphicsDevice = gc.getD3DDevice();
    this.peer = peer;
    this.type = type;
    this.width = width;
    this.height = height;
    this.offscreenImage = image;
    this.backBuffersNum = numBackBuffers;
    this.swapEffect = swapEffect;
    this.syncType = vSyncType;

    initOps(graphicsDevice.getScreen(), width, height);
    if (type == WINDOW) {
      // we put the surface into the "lost"
      // state; it will be restored by the D3DScreenUpdateManager
      // prior to rendering to it for the first time. This is done
      // so that vram is not wasted for surfaces never rendered to
      setSurfaceLost(true);
    } else {
      initSurface();
    }
    setBlitProxyKey(gc.getProxyKey());
  }

  @Override
  public SurfaceDataProxy makeProxyFor(SurfaceData srcData) {
    return D3DSurfaceDataProxy.createProxy(
        srcData, (D3DGraphicsConfig) graphicsDevice.getDefaultConfiguration());
  }

  /**
   * Creates a SurfaceData object representing the back buffer of a double-buffered on-screen
   * Window.
   */
  public static D3DSurfaceData createData(WComponentPeer peer, Image image) {
    D3DGraphicsConfig gc = getGC(peer);
    if (gc == null || !peer.isAccelCapable()) {
      return null;
    }
    BufferCapabilities caps = peer.getBackBufferCaps();
    VSyncType vSyncType = VSYNC_DEFAULT;
    if (caps instanceof ExtendedBufferCapabilities) {
      vSyncType = ((ExtendedBufferCapabilities) caps).getVSync();
    }
    Rectangle r = peer.getBounds();
    BufferCapabilities.FlipContents flip = caps.getFlipContents();
    int swapEffect;
    if (flip == FlipContents.COPIED) {
      swapEffect = SWAP_COPY;
    } else if (flip == FlipContents.PRIOR) {
      swapEffect = SWAP_FLIP;
    } else { // flip == FlipContents.UNDEFINED || .BACKGROUND
      swapEffect = SWAP_DISCARD;
    }
    return new D3DSurfaceData(
        peer,
        gc,
        r.width,
        r.height,
        image,
        peer.getColorModel(),
        peer.getBackBuffersNum(),
        swapEffect,
        vSyncType,
        FLIP_BACKBUFFER);
  }

  /**
   * Returns a WINDOW type of surface - a swap chain which serves as an on-screen surface, handled
   * by the D3DScreenUpdateManager.
   *
   * <p>Note that the native surface is not initialized when the surface is created to avoid using
   * excessive resources, and the surface is placed into the lost state. It will be restored prior
   * to any rendering to it.
   *
   * @param peer peer for which the onscreen surface is to be created
   * @return a D3DWindowSurfaceData (flip chain) surface
   */
  public static D3DSurfaceData createData(WComponentPeer peer) {
    D3DGraphicsConfig gc = getGC(peer);
    if (gc == null || !peer.isAccelCapable()) {
      return null;
    }
    return new D3DWindowSurfaceData(peer, gc);
  }

  /**
   * Creates a SurfaceData object representing an off-screen buffer (either a plain surface or
   * Texture).
   */
  public static D3DSurfaceData createData(
      D3DGraphicsConfig gc, int width, int height, ColorModel cm, Image image, int type) {
    if (type == RT_TEXTURE) {
      boolean isOpaque = cm.getTransparency() == Transparency.OPAQUE;
      int cap = isOpaque ? CAPS_RT_TEXTURE_OPAQUE : CAPS_RT_TEXTURE_ALPHA;
      if (!gc.getD3DDevice().isCapPresent(cap)) {
        type = RT_PLAIN;
      }
    }
    D3DSurfaceData ret = null;
    try {
      ret =
          new D3DSurfaceData(
              null, gc, width, height, image, cm, 0, SWAP_DISCARD, VSYNC_DEFAULT, type);
    } catch (InvalidPipeException ipe) {
      // try again - we might have ran out of vram, and rt textures
      // could take up more than a plain surface, so it might succeed
      if (type == RT_TEXTURE) {
        // If a RT_TEXTURE was requested do not attempt to create a
        // plain surface. (note that RT_TEXTURE can only be requested
        // from a VI so the cast is safe)
        if (((SunVolatileImage) image).getForcedAccelSurfaceType() != RT_TEXTURE) {
          type = RT_PLAIN;
          ret =
              new D3DSurfaceData(
                  null, gc, width, height, image, cm, 0, SWAP_DISCARD, VSYNC_DEFAULT, type);
        }
      }
    }
    return ret;
  }

  /**
   * Returns the appropriate SurfaceType corresponding to the given D3D surface type constant (e.g.
   * TEXTURE -> D3DTexture).
   */
  private static SurfaceType getCustomSurfaceType(int d3dType) {
    switch (d3dType) {
      case TEXTURE:
        return D3DTexture;
      case RT_TEXTURE:
        return D3DSurfaceRTT;
      default:
        return D3DSurface;
    }
  }

  private boolean initSurfaceNow() {
    boolean isOpaque = (getTransparency() == Transparency.OPAQUE);
    switch (type) {
      case RT_PLAIN:
        return initRTSurface(getNativeOps(), isOpaque);
      case TEXTURE:
        return initTexture(getNativeOps(), false /*isRTT*/, isOpaque);
      case RT_TEXTURE:
        return initTexture(getNativeOps(), true /*isRTT*/, isOpaque);
        // REMIND: we may want to pass the exact type to the native
        // level here so that we could choose the right presentation
        // interval for the frontbuffer (immediate vs v-synced)
      case WINDOW:
      case FLIP_BACKBUFFER:
        return initFlipBackbuffer(
            getNativeOps(), peer.getData(), backBuffersNum, swapEffect, syncType.id());
      default:
        return false;
    }
  }

  /**
   * Initializes the appropriate D3D offscreen surface based on the value of the type parameter. If
   * the surface creation fails for any reason, an OutOfMemoryError will be thrown.
   */
  protected void initSurface() {
    // any time we create or restore the surface, recreate the raster
    synchronized (this) {
      wrn = null;
    }
    // REMIND: somewhere a puppy died
    class Status {
      boolean success = false;
    };
    final Status status = new Status();
    D3DRenderQueue rq = D3DRenderQueue.getInstance();
    rq.lock();
    try {
      rq.flushAndInvokeNow(
          new Runnable() {
            public void run() {
              status.success = initSurfaceNow();
            }
          });
      if (!status.success) {
        throw new InvalidPipeException("Error creating D3DSurface");
      }
    } finally {
      rq.unlock();
    }
  }

  /** Returns the D3DContext for the GraphicsConfig associated with this surface. */
  public final D3DContext getContext() {
    return graphicsDevice.getContext();
  }

  /** Returns one of the surface type constants defined above. */
  public final int getType() {
    return type;
  }

  private static native int dbGetPixelNative(long pData, int x, int y);

  private static native void dbSetPixelNative(long pData, int x, int y, int pixel);

  static class D3DDataBufferNative extends DataBufferNative {
    int pixel;

    protected D3DDataBufferNative(SurfaceData sData, int type, int w, int h) {
      super(sData, type, w, h);
    }

    protected int getElem(final int x, final int y, final SurfaceData sData) {
      if (sData.isSurfaceLost()) {
        return 0;
      }

      int retPixel;
      D3DRenderQueue rq = D3DRenderQueue.getInstance();
      rq.lock();
      try {
        rq.flushAndInvokeNow(
            new Runnable() {
              public void run() {
                pixel = dbGetPixelNative(sData.getNativeOps(), x, y);
              }
            });
      } finally {
        retPixel = pixel;
        rq.unlock();
      }
      return retPixel;
    }

    protected void setElem(final int x, final int y, final int pixel, final SurfaceData sData) {
      if (sData.isSurfaceLost()) {
        return;
      }

      D3DRenderQueue rq = D3DRenderQueue.getInstance();
      rq.lock();
      try {
        rq.flushAndInvokeNow(
            new Runnable() {
              public void run() {
                dbSetPixelNative(sData.getNativeOps(), x, y, pixel);
              }
            });
        sData.markDirty();
      } finally {
        rq.unlock();
      }
    }
  }

  public synchronized Raster getRaster(int x, int y, int w, int h) {
    if (wrn == null) {
      DirectColorModel dcm = (DirectColorModel) getColorModel();
      SampleModel smHw;
      int dataType = 0;
      int scanStride = width;

      if (dcm.getPixelSize() == 24 || dcm.getPixelSize() == 32) {
        dataType = DataBuffer.TYPE_INT;
      } else {
        // 15, 16
        dataType = DataBuffer.TYPE_USHORT;
      }

      // note that we have to use the surface width and height here,
      // not the passed w,h
      smHw = new SinglePixelPackedSampleModel(dataType, width, height, scanStride, dcm.getMasks());
      DataBuffer dbn =
          new D3DDataBufferNative(
              this, dataType,
              width, height);
      wrn = WritableRasterNative.createNativeRaster(smHw, dbn);
    }

    return wrn;
  }

  /**
   * For now, we can only render LCD text if: - the pixel shaders are available, and - blending is
   * disabled, and - the source color is opaque - and the destination is opaque
   */
  public boolean canRenderLCDText(SunGraphics2D sg2d) {
    return graphicsDevice.isCapPresent(CAPS_LCD_SHADER)
        && sg2d.compositeState <= SunGraphics2D.COMP_ISCOPY
        && sg2d.paintState <= SunGraphics2D.PAINT_OPAQUECOLOR
        && sg2d.surfaceData.getTransparency() == Transparency.OPAQUE;
  }

  /**
   * If acceleration should no longer be used for this surface. This implementation flags to the
   * manager that it should no longer attempt to re-create a D3DSurface.
   */
  void disableAccelerationForSurface() {
    if (offscreenImage != null) {
      SurfaceManager sm = SurfaceManager.getManager(offscreenImage);
      if (sm instanceof D3DVolatileSurfaceManager) {
        setSurfaceLost(true);
        ((D3DVolatileSurfaceManager) sm).setAccelerationEnabled(false);
      }
    }
  }

  public void validatePipe(SunGraphics2D sg2d) {
    TextPipe textpipe;
    boolean validated = false;

    // REMIND: the D3D pipeline doesn't support XOR!, more
    // fixes will be needed below. For now we disable D3D rendering
    // for the surface which had any XOR rendering done to.
    if (sg2d.compositeState >= sg2d.COMP_XOR) {
      super.validatePipe(sg2d);
      sg2d.imagepipe = d3dImagePipe;
      disableAccelerationForSurface();
      return;
    }

    // D3DTextRenderer handles both AA and non-AA text, but
    // only works with the following modes:
    // (Note: For LCD text we only enter this code path if
    // canRenderLCDText() has already validated that the mode is
    // CompositeType.SrcNoEa (opaque color), which will be subsumed
    // by the CompositeType.SrcNoEa (any color) test below.)

    if (
    /* CompositeType.SrcNoEa (any color) */
    (sg2d.compositeState <= sg2d.COMP_ISCOPY && sg2d.paintState <= sg2d.PAINT_ALPHACOLOR)
        ||

        /* CompositeType.SrcOver (any color) */
        (sg2d.compositeState == sg2d.COMP_ALPHA
            && sg2d.paintState <= sg2d.PAINT_ALPHACOLOR
            && (((AlphaComposite) sg2d.composite).getRule() == AlphaComposite.SRC_OVER))
        ||

        /* CompositeType.Xor (any color) */
        (sg2d.compositeState == sg2d.COMP_XOR && sg2d.paintState <= sg2d.PAINT_ALPHACOLOR)) {
      textpipe = d3dTextPipe;
    } else {
      // do this to initialize textpipe correctly; we will attempt
      // to override the non-text pipes below
      super.validatePipe(sg2d);
      textpipe = sg2d.textpipe;
      validated = true;
    }

    PixelToParallelogramConverter txPipe = null;
    D3DRenderer nonTxPipe = null;

    if (sg2d.antialiasHint != SunHints.INTVAL_ANTIALIAS_ON) {
      if (sg2d.paintState <= sg2d.PAINT_ALPHACOLOR) {
        if (sg2d.compositeState <= sg2d.COMP_XOR) {
          txPipe = d3dTxRenderPipe;
          nonTxPipe = d3dRenderPipe;
        }
      } else if (sg2d.compositeState <= sg2d.COMP_ALPHA) {
        if (D3DPaints.isValid(sg2d)) {
          txPipe = d3dTxRenderPipe;
          nonTxPipe = d3dRenderPipe;
        }
        // custom paints handled by super.validatePipe() below
      }
    } else {
      if (sg2d.paintState <= sg2d.PAINT_ALPHACOLOR) {
        if (graphicsDevice.isCapPresent(CAPS_AA_SHADER)
            && (sg2d.imageComp == CompositeType.SrcOverNoEa
                || sg2d.imageComp == CompositeType.SrcOver)) {
          if (!validated) {
            super.validatePipe(sg2d);
            validated = true;
          }
          PixelToParallelogramConverter aaConverter =
              new PixelToParallelogramConverter(
                  sg2d.shapepipe, d3dAAPgramPipe, 1.0 / 8.0, 0.499, false);
          sg2d.drawpipe = aaConverter;
          sg2d.fillpipe = aaConverter;
          sg2d.shapepipe = aaConverter;
        } else if (sg2d.compositeState == sg2d.COMP_XOR) {
          // install the solid pipes when AA and XOR are both enabled
          txPipe = d3dTxRenderPipe;
          nonTxPipe = d3dRenderPipe;
        }
      }
      // other cases handled by super.validatePipe() below
    }

    if (txPipe != null) {
      if (sg2d.transformState >= sg2d.TRANSFORM_TRANSLATESCALE) {
        sg2d.drawpipe = txPipe;
        sg2d.fillpipe = txPipe;
      } else if (sg2d.strokeState != sg2d.STROKE_THIN) {
        sg2d.drawpipe = txPipe;
        sg2d.fillpipe = nonTxPipe;
      } else {
        sg2d.drawpipe = nonTxPipe;
        sg2d.fillpipe = nonTxPipe;
      }
      // Note that we use the transforming pipe here because it
      // will examine the shape and possibly perform an optimized
      // operation if it can be simplified.  The simplifications
      // will be valid for all STROKE and TRANSFORM types.
      sg2d.shapepipe = txPipe;
    } else {
      if (!validated) {
        super.validatePipe(sg2d);
      }
    }

    // install the text pipe based on our earlier decision
    sg2d.textpipe = textpipe;

    // always override the image pipe with the specialized D3D pipe
    sg2d.imagepipe = d3dImagePipe;
  }

  @Override
  protected MaskFill getMaskFill(SunGraphics2D sg2d) {
    if (sg2d.paintState > sg2d.PAINT_ALPHACOLOR) {
      /*
       * We can only accelerate non-Color MaskFill operations if
       * all of the following conditions hold true:
       *   - there is an implementation for the given paintState
       *   - the current Paint can be accelerated for this destination
       *   - multitexturing is available (since we need to modulate
       *     the alpha mask texture with the paint texture)
       *
       * In all other cases, we return null, in which case the
       * validation code will choose a more general software-based loop.
       */
      if (!D3DPaints.isValid(sg2d) || !graphicsDevice.isCapPresent(CAPS_MULTITEXTURE)) {
        return null;
      }
    }
    return super.getMaskFill(sg2d);
  }

  @Override
  public boolean copyArea(SunGraphics2D sg2d, int x, int y, int w, int h, int dx, int dy) {
    if (sg2d.transformState < sg2d.TRANSFORM_TRANSLATESCALE
        && sg2d.compositeState < sg2d.COMP_XOR) {
      x += sg2d.transX;
      y += sg2d.transY;

      d3dRenderPipe.copyArea(sg2d, x, y, w, h, dx, dy);

      return true;
    }
    return false;
  }

  @Override
  public void flush() {
    D3DRenderQueue rq = D3DRenderQueue.getInstance();
    rq.lock();
    try {
      RenderBuffer buf = rq.getBuffer();
      rq.ensureCapacityAndAlignment(12, 4);
      buf.putInt(FLUSH_SURFACE);
      buf.putLong(getNativeOps());

      // this call is expected to complete synchronously, so flush now
      rq.flushNow();
    } finally {
      rq.unlock();
    }
  }

  /**
   * Disposes the native resources associated with the given D3DSurfaceData (referenced by the pData
   * parameter). This method is invoked from the native Dispose() method from the Disposer thread
   * when the Java-level D3DSurfaceData object is about to go away.
   */
  static void dispose(long pData) {
    D3DRenderQueue rq = D3DRenderQueue.getInstance();
    rq.lock();
    try {
      RenderBuffer buf = rq.getBuffer();
      rq.ensureCapacityAndAlignment(12, 4);
      buf.putInt(DISPOSE_SURFACE);
      buf.putLong(pData);

      // this call is expected to complete synchronously, so flush now
      rq.flushNow();
    } finally {
      rq.unlock();
    }
  }

  static void swapBuffers(
      D3DSurfaceData sd, final int x1, final int y1, final int x2, final int y2) {
    long pData = sd.getNativeOps();
    D3DRenderQueue rq = D3DRenderQueue.getInstance();
    // swapBuffers can be called from the toolkit thread by swing, we
    // should detect this and prevent the deadlocks
    if (rq.isRenderQueueThread()) {
      if (!rq.tryLock()) {
        // if we could not obtain the lock, repaint the area
        // that was supposed to be swapped, and no-op this swap
        final Component target = (Component) sd.getPeer().getTarget();
        SunToolkit.executeOnEventHandlerThread(
            target,
            new Runnable() {
              public void run() {
                target.repaint(x1, y1, x2, y2);
              }
            });
        return;
      }
    } else {
      rq.lock();
    }
    try {
      RenderBuffer buf = rq.getBuffer();
      rq.ensureCapacityAndAlignment(28, 4);
      buf.putInt(SWAP_BUFFERS);
      buf.putLong(pData);
      buf.putInt(x1);
      buf.putInt(y1);
      buf.putInt(x2);
      buf.putInt(y2);
      rq.flushNow();
    } finally {
      rq.unlock();
    }
  }

  /** Returns destination Image associated with this SurfaceData. */
  public Object getDestination() {
    return offscreenImage;
  }

  public Rectangle getBounds() {
    if (type == FLIP_BACKBUFFER || type == WINDOW) {
      Rectangle r = peer.getBounds();
      r.x = r.y = 0;
      return r;
    } else {
      return new Rectangle(width, height);
    }
  }

  public Rectangle getNativeBounds() {
    D3DRenderQueue rq = D3DRenderQueue.getInstance();
    // need to lock to make sure nativeWidth and Height are consistent
    // since they are set from the render thread from the native
    // level
    rq.lock();
    try {
      // REMIND: use xyoffsets?
      return new Rectangle(nativeWidth, nativeHeight);
    } finally {
      rq.unlock();
    }
  }

  public GraphicsConfiguration getDeviceConfiguration() {
    return graphicsDevice.getDefaultConfiguration();
  }

  public SurfaceData getReplacement() {
    return restoreContents(offscreenImage);
  }

  private static D3DGraphicsConfig getGC(WComponentPeer peer) {
    GraphicsConfiguration gc;
    if (peer != null) {
      gc = peer.getGraphicsConfiguration();
    } else {
      GraphicsEnvironment env = GraphicsEnvironment.getLocalGraphicsEnvironment();
      GraphicsDevice gd = env.getDefaultScreenDevice();
      gc = gd.getDefaultConfiguration();
    }
    return (gc instanceof D3DGraphicsConfig) ? (D3DGraphicsConfig) gc : null;
  }

  /** Attempts to restore the surface by initializing the native data */
  void restoreSurface() {
    initSurface();
  }

  WComponentPeer getPeer() {
    return peer;
  }

  /**
   * We need to let the surface manager know that the surface is lost so that for example
   * BufferStrategy.contentsLost() returns correct result. Normally the status of contentsLost is
   * set in validate(), but in some cases (like Swing's buffer per window) we intentionally don't
   * call validate from the toolkit thread but only check for the BS status.
   */
  @Override
  public void setSurfaceLost(boolean lost) {
    super.setSurfaceLost(lost);
    if (lost && offscreenImage != null) {
      SurfaceManager sm = SurfaceManager.getManager(offscreenImage);
      sm.acceleratedSurfaceLost();
    }
  }

  private static native long getNativeResourceNative(long sdops, int resType);
  /**
   * Returns a pointer to the native resource of specified {@code resType} associated with this
   * surface.
   *
   * <p>Specifically, for {@code D3DSurfaceData} this method returns pointers of the following:
   *
   * <pre>
   * TEXTURE              - (IDirect3DTexture9*)
   * RT_TEXTURE, RT_PLAIN - (IDirect3DSurface9*)
   * FLIP_BACKBUFFER      - (IDirect3DSwapChain9*)
   * D3D_DEVICE_RESOURCE  - (IDirect3DDevice9*)
   * </pre>
   *
   * Multiple resources may be available for some types (i.e. for render to texture one could
   * retrieve both a destination surface by specifying RT_TEXTURE, and a texture by using TEXTURE).
   *
   * <p>Note: the pointer returned by this method is only valid on the rendering thread.
   *
   * @return pointer to the native resource of specified type or 0L if such resource doesn't exist
   *     or can not be retrieved.
   * @see sun.java2d.pipe.hw.AccelSurface#getNativeResource
   */
  public long getNativeResource(int resType) {
    return getNativeResourceNative(getNativeOps(), resType);
  }

  /**
   * Class representing an on-screen d3d surface. Since d3d can't render to the screen directly, it
   * is implemented as a swap chain, controlled by D3DScreenUpdateManager.
   *
   * @see D3DScreenUpdateManager
   */
  public static class D3DWindowSurfaceData extends D3DSurfaceData {
    StateTracker dirtyTracker;

    public D3DWindowSurfaceData(WComponentPeer peer, D3DGraphicsConfig gc) {
      super(
          peer,
          gc,
          peer.getBounds().width,
          peer.getBounds().height,
          null,
          peer.getColorModel(),
          1,
          SWAP_COPY,
          VSYNC_DEFAULT,
          WINDOW);
      dirtyTracker = getStateTracker();
    }

    /**
     * {@inheritDoc}
     *
     * <p>Overridden to use ScreenUpdateManager to obtain the replacement surface.
     *
     * @see sun.java2d.ScreenUpdateManager#getReplacementScreenSurface
     */
    @Override
    public SurfaceData getReplacement() {
      ScreenUpdateManager mgr = ScreenUpdateManager.getInstance();
      return mgr.getReplacementScreenSurface(peer, this);
    }

    /** Returns destination Component associated with this SurfaceData. */
    @Override
    public Object getDestination() {
      return peer.getTarget();
    }

    @Override
    void disableAccelerationForSurface() {
      // for on-screen surfaces we need to make sure a backup GDI surface is
      // is used until a new one is set (which may happen during a resize). We
      // don't want the screen update maanger to replace the surface right way
      // because it causes repainting issues in Swing, so we invalidate it,
      // this will prevent SUM from issuing a replaceSurfaceData call.
      setSurfaceLost(true);
      invalidate();
      flush();
      peer.disableAcceleration();
      ScreenUpdateManager.getInstance().dropScreenSurface(this);
    }

    @Override
    void restoreSurface() {
      if (!peer.isAccelCapable()) {
        throw new InvalidPipeException("Onscreen acceleration " + "disabled for this surface");
      }
      Window fsw = graphicsDevice.getFullScreenWindow();
      if (fsw != null && fsw != peer.getTarget()) {
        throw new InvalidPipeException(
            "Can't restore onscreen surface" + " when in full-screen mode");
      }
      super.restoreSurface();
      // if initialization was unsuccessful, an IPE will be thrown
      // and the surface will remain lost
      setSurfaceLost(false);

      // This is to make sure the render target is reset after this
      // surface is restored. The reason for this is that sometimes this
      // surface can be restored from multiple threads (the screen update
      // manager's thread and app's rendering thread) at the same time,
      // and when that happens the second restoration will create the
      // native resource which will not be set as render target because
      // the BufferedContext's validate method will think that since the
      // surface data object didn't change then the current render target
      // is correct and no rendering will appear on the screen.
      D3DRenderQueue rq = D3DRenderQueue.getInstance();
      rq.lock();
      try {
        getContext().invalidateContext();
      } finally {
        rq.unlock();
      }
    }

    public boolean isDirty() {
      return !dirtyTracker.isCurrent();
    }

    public void markClean() {
      dirtyTracker = getStateTracker();
    }
  }

  /**
   * Updates the layered window with the contents of the surface.
   *
   * @param pd3dsd pointer to the D3DSDOps structure
   * @param pData pointer to the AwtWindow peer data
   * @param w width of the window
   * @param h height of the window
   * @see sun.awt.windows.TranslucentWindowPainter
   */
  public static native boolean updateWindowAccelImpl(long pd3dsd, long pData, int w, int h);
}
 /**
  * Returns the pixel data for the specified Argb value packed into an integer for easy storage and
  * conveyance.
  */
 public int pixelFor(int rgb) {
   return surfaceType.pixelFor(rgb, colorModel);
 }