src/windows/classes/sun/awt/Win32GraphicsConfig.java - toolchain/jdk/jdk9_jdk - Git at Google

 /*
  * Copyright (c) 1997, 2009, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.  Oracle designates this
  * particular file as subject to the "Classpath" exception as provided
  * by Oracle in the LICENSE file that accompanied this code.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  */

 package sun.awt;

 import java.awt.AWTException;
 import java.awt.BufferCapabilities;
 import java.awt.Component;
 import java.awt.Graphics;
 import java.awt.GraphicsConfiguration;
 import java.awt.GraphicsDevice;
 import java.awt.GraphicsEnvironment;
 import java.awt.Image;
 import java.awt.ImageCapabilities;
 import java.awt.Rectangle;
 import java.awt.Toolkit;
 import java.awt.Transparency;
 import java.awt.Window;
 import java.awt.geom.AffineTransform;
 import java.awt.image.BufferedImage;
 import java.awt.image.ColorModel;
 import java.awt.image.DirectColorModel;
 import java.awt.image.Raster;
 import java.awt.image.VolatileImage;
 import java.awt.image.WritableRaster;

 import sun.awt.windows.WComponentPeer;
 import sun.awt.image.OffScreenImage;
 import sun.awt.image.SunVolatileImage;
 import sun.awt.image.SurfaceManager;
 import sun.java2d.SurfaceData;
 import sun.java2d.InvalidPipeException;
 import sun.java2d.loops.RenderLoops;
 import sun.java2d.loops.SurfaceType;
 import sun.java2d.loops.CompositeType;
 import sun.java2d.windows.GDIWindowSurfaceData;

 /**
  * This is an implementation of a GraphicsConfiguration object for a
  * single Win32 visual.
  *
  * @see GraphicsEnvironment
  * @see GraphicsDevice
  */
 public class Win32GraphicsConfig extends GraphicsConfiguration
     implements DisplayChangedListener, SurfaceManager.ProxiedGraphicsConfig
 {
     protected Win32GraphicsDevice screen;
     protected int visual;  //PixelFormatID
     protected RenderLoops solidloops;

     private static native void initIDs();

     static {
         initIDs();
     }

     /**
      * Returns a Win32GraphicsConfiguration object with the given device
      * and PixelFormat.  Note that this method does NOT check to ensure that
      * the returned Win32GraphicsConfig will correctly support rendering into a
      * Java window.  This method is provided so that client code can do its
      * own checking as to the appropriateness of a particular PixelFormat.
      * Safer access to Win32GraphicsConfigurations is provided by
      * Win32GraphicsDevice.getConfigurations().
      */
     public static Win32GraphicsConfig getConfig(Win32GraphicsDevice device,
                                                 int pixFormatID)
     {
         return new Win32GraphicsConfig(device, pixFormatID);
     }

     /**
      * @deprecated as of JDK version 1.3
      * replaced by <code>getConfig()</code>
      */
     @Deprecated
     public Win32GraphicsConfig(GraphicsDevice device, int visualnum) {
         this.screen = (Win32GraphicsDevice)device;
         this.visual = visualnum;
         ((Win32GraphicsDevice)device).addDisplayChangedListener(this);
     }

     /**
      * Return the graphics device associated with this configuration.
      */
     public GraphicsDevice getDevice() {
         return screen;
     }

     /**
      * Return the PixelFormatIndex this GraphicsConfig uses
      */
     public int getVisual() {
         return visual;
     }

     public Object getProxyKey() {
         return screen;
     }

     /**
      * Return the RenderLoops this type of destination uses for
      * solid fills and strokes.
      */
     private SurfaceType sTypeOrig = null;
     public synchronized RenderLoops getSolidLoops(SurfaceType stype) {
         if (solidloops == null || sTypeOrig != stype) {
             solidloops = SurfaceData.makeRenderLoops(SurfaceType.OpaqueColor,
                                                      CompositeType.SrcNoEa,
                                                      stype);
             sTypeOrig = stype;
         }
         return solidloops;
     }

     /**
      * Returns the color model associated with this configuration.
      */
     public synchronized ColorModel getColorModel() {
         return screen.getColorModel();
     }

     /**
      * Returns a new color model for this configuration.  This call
      * is only used internally, by images and components that are
      * associated with the graphics device.  When attributes of that
      * device change (for example, when the device palette is updated),
      * then this device-based color model will be updated internally
      * to reflect the new situation.
      */
     public ColorModel getDeviceColorModel() {
         return screen.getDynamicColorModel();
     }

     /**
      * Returns the color model associated with this configuration that
      * supports the specified transparency.
      */
     public ColorModel getColorModel(int transparency) {
         switch (transparency) {
         case Transparency.OPAQUE:
             return getColorModel();
         case Transparency.BITMASK:
             return new DirectColorModel(25, 0xff0000, 0xff00, 0xff, 0x1000000);
         case Transparency.TRANSLUCENT:
             return ColorModel.getRGBdefault();
         default:
             return null;
         }
     }

     /**
      * Returns the default Transform for this configuration.  This
      * Transform is typically the Identity transform for most normal
      * screens.  Device coordinates for screen and printer devices will
      * have the origin in the upper left-hand corner of the target region of
      * the device, with X coordinates
      * increasing to the right and Y coordinates increasing downwards.
      * For image buffers, this Transform will be the Identity transform.
      */
     public AffineTransform getDefaultTransform() {
         return new AffineTransform();
     }

     /**
      *
      * Returns a Transform that can be composed with the default Transform
      * of a Graphics2D so that 72 units in user space will equal 1 inch
      * in device space.
      * Given a Graphics2D, g, one can reset the transformation to create
      * such a mapping by using the following pseudocode:
      * <pre>
      *      GraphicsConfiguration gc = g.getGraphicsConfiguration();
      *
      *      g.setTransform(gc.getDefaultTransform());
      *      g.transform(gc.getNormalizingTransform());
      * </pre>
      * Note that sometimes this Transform will be identity (e.g. for
      * printers or metafile output) and that this Transform is only
      * as accurate as the information supplied by the underlying system.
      * For image buffers, this Transform will be the Identity transform,
      * since there is no valid distance measurement.
      */
     public AffineTransform getNormalizingTransform() {
         Win32GraphicsEnvironment ge = (Win32GraphicsEnvironment)
             GraphicsEnvironment.getLocalGraphicsEnvironment();
         double xscale = ge.getXResolution() / 72.0;
         double yscale = ge.getYResolution() / 72.0;
         return new AffineTransform(xscale, 0.0, 0.0, yscale, 0.0, 0.0);
     }

     public String toString() {
         return (super.toString()+"[dev="+screen+",pixfmt="+visual+"]");
     }

     private native Rectangle getBounds(int screen);

     public Rectangle getBounds() {
         return getBounds(screen.getScreen());
     }

     public synchronized void displayChanged() {
         solidloops = null;
     }

     public void paletteChanged() {}

     /**
      * The following methods are invoked from WComponentPeer.java rather
      * than having the Win32-dependent implementations hardcoded in that
      * class.  This way the appropriate actions are taken based on the peer's
      * GraphicsConfig, whether it is a Win32GraphicsConfig or a
      * WGLGraphicsConfig.
      */

     /**
      * Creates a new SurfaceData that will be associated with the given
      * WComponentPeer.
      */
     public SurfaceData createSurfaceData(WComponentPeer peer,
                                          int numBackBuffers)
     {
         return GDIWindowSurfaceData.createData(peer);
     }

     /**
      * Creates a new managed image of the given width and height
      * that is associated with the target Component.
      */
     public Image createAcceleratedImage(Component target,
                                         int width, int height)
     {
         ColorModel model = getColorModel(Transparency.OPAQUE);
         WritableRaster wr =
             model.createCompatibleWritableRaster(width, height);
         return new OffScreenImage(target, model, wr,
                                   model.isAlphaPremultiplied());
     }

     /**
      * The following methods correspond to the multibuffering methods in
      * WComponentPeer.java...
      */

     /**
      * Checks that the requested configuration is natively supported; if not,
      * an AWTException is thrown.
      */
     public void assertOperationSupported(Component target,
                                          int numBuffers,
                                          BufferCapabilities caps)
         throws AWTException
     {
         // the default pipeline doesn't support flip buffer strategy
         throw new AWTException(
             "The operation requested is not supported");
     }

     /**
      * This method is called from WComponentPeer when a surface data is replaced
      * REMIND: while the default pipeline doesn't support flipping, it may
      * happen that the accelerated device may have this graphics config
      * (like if the device restoration failed when one device exits fs mode
      * while others remain).
      */
     public VolatileImage createBackBuffer(WComponentPeer peer) {
         Component target = (Component)peer.getTarget();
         return new SunVolatileImage(target,
                                     target.getWidth(), target.getHeight(),
                                     Boolean.TRUE);
     }

     /**
      * Performs the native flip operation for the given target Component.
      *
      * REMIND: we should really not get here because that would mean that
      * a FLIP BufferStrategy has been created, and one could only be created
      * if accelerated pipeline is present but in some rare (and transitional)
      * cases it may happen that the accelerated graphics device may have a
      * default graphics configuraiton, so this is just a precaution.
      */
     public void flip(WComponentPeer peer,
                      Component target, VolatileImage backBuffer,
                      int x1, int y1, int x2, int y2,
                      BufferCapabilities.FlipContents flipAction)
     {
         if (flipAction == BufferCapabilities.FlipContents.COPIED ||
             flipAction == BufferCapabilities.FlipContents.UNDEFINED) {
             Graphics g = peer.getGraphics();
             try {
                 g.drawImage(backBuffer,
                             x1, y1, x2, y2,
                             x1, y1, x2, y2,
                             null);
             } finally {
                 g.dispose();
             }
         } else if (flipAction == BufferCapabilities.FlipContents.BACKGROUND) {
             Graphics g = backBuffer.getGraphics();
             try {
                 g.setColor(target.getBackground());
                 g.fillRect(0, 0,
                            backBuffer.getWidth(),
                            backBuffer.getHeight());
             } finally {
                 g.dispose();
             }
         }
         // the rest of the flip actions are not supported
     }

     @Override
     public boolean isTranslucencyCapable() {
         //XXX: worth checking if 8-bit? Anyway, it doesn't hurt.
         return true;
     }
 }
	/*
	* Copyright (c) 1997, 2009, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation. Oracle designates this
	* particular file as subject to the "Classpath" exception as provided
	* by Oracle in the LICENSE file that accompanied this code.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	package sun.awt;

	import java.awt.AWTException;
	import java.awt.BufferCapabilities;
	import java.awt.Component;
	import java.awt.Graphics;
	import java.awt.GraphicsConfiguration;
	import java.awt.GraphicsDevice;
	import java.awt.GraphicsEnvironment;
	import java.awt.Image;
	import java.awt.ImageCapabilities;
	import java.awt.Rectangle;
	import java.awt.Toolkit;
	import java.awt.Transparency;
	import java.awt.Window;
	import java.awt.geom.AffineTransform;
	import java.awt.image.BufferedImage;
	import java.awt.image.ColorModel;
	import java.awt.image.DirectColorModel;
	import java.awt.image.Raster;
	import java.awt.image.VolatileImage;
	import java.awt.image.WritableRaster;

	import sun.awt.windows.WComponentPeer;
	import sun.awt.image.OffScreenImage;
	import sun.awt.image.SunVolatileImage;
	import sun.awt.image.SurfaceManager;
	import sun.java2d.SurfaceData;
	import sun.java2d.InvalidPipeException;
	import sun.java2d.loops.RenderLoops;
	import sun.java2d.loops.SurfaceType;
	import sun.java2d.loops.CompositeType;
	import sun.java2d.windows.GDIWindowSurfaceData;

	/**
	* This is an implementation of a GraphicsConfiguration object for a
	* single Win32 visual.
	*
	* @see GraphicsEnvironment
	* @see GraphicsDevice
	*/
	public class Win32GraphicsConfig extends GraphicsConfiguration
	implements DisplayChangedListener, SurfaceManager.ProxiedGraphicsConfig
	{
	protected Win32GraphicsDevice screen;
	protected int visual; //PixelFormatID
	protected RenderLoops solidloops;

	private static native void initIDs();

	static {
	initIDs();
	}

	/**
	* Returns a Win32GraphicsConfiguration object with the given device
	* and PixelFormat. Note that this method does NOT check to ensure that
	* the returned Win32GraphicsConfig will correctly support rendering into a
	* Java window. This method is provided so that client code can do its
	* own checking as to the appropriateness of a particular PixelFormat.
	* Safer access to Win32GraphicsConfigurations is provided by
	* Win32GraphicsDevice.getConfigurations().
	*/
	public static Win32GraphicsConfig getConfig(Win32GraphicsDevice device,
	int pixFormatID)
	{
	return new Win32GraphicsConfig(device, pixFormatID);
	}

	/**
	* @deprecated as of JDK version 1.3
	* replaced by <code>getConfig()</code>
	*/
	@Deprecated
	public Win32GraphicsConfig(GraphicsDevice device, int visualnum) {
	this.screen = (Win32GraphicsDevice)device;
	this.visual = visualnum;
	((Win32GraphicsDevice)device).addDisplayChangedListener(this);
	}

	/**
	* Return the graphics device associated with this configuration.
	*/
	public GraphicsDevice getDevice() {
	return screen;
	}

	/**
	* Return the PixelFormatIndex this GraphicsConfig uses
	*/
	public int getVisual() {
	return visual;
	}

	public Object getProxyKey() {
	return screen;
	}

	/**
	* Return the RenderLoops this type of destination uses for
	* solid fills and strokes.
	*/
	private SurfaceType sTypeOrig = null;
	public synchronized RenderLoops getSolidLoops(SurfaceType stype) {
	if (solidloops == null \|\| sTypeOrig != stype) {
	solidloops = SurfaceData.makeRenderLoops(SurfaceType.OpaqueColor,
	CompositeType.SrcNoEa,
	stype);
	sTypeOrig = stype;
	}
	return solidloops;
	}

	/**
	* Returns the color model associated with this configuration.
	*/
	public synchronized ColorModel getColorModel() {
	return screen.getColorModel();
	}

	/**
	* Returns a new color model for this configuration. This call
	* is only used internally, by images and components that are
	* associated with the graphics device. When attributes of that
	* device change (for example, when the device palette is updated),
	* then this device-based color model will be updated internally
	* to reflect the new situation.
	*/
	public ColorModel getDeviceColorModel() {
	return screen.getDynamicColorModel();
	}

	/**
	* Returns the color model associated with this configuration that
	* supports the specified transparency.
	*/
	public ColorModel getColorModel(int transparency) {
	switch (transparency) {
	case Transparency.OPAQUE:
	return getColorModel();
	case Transparency.BITMASK:
	return new DirectColorModel(25, 0xff0000, 0xff00, 0xff, 0x1000000);
	case Transparency.TRANSLUCENT:
	return ColorModel.getRGBdefault();
	default:
	return null;
	}
	}

	/**
	* Returns the default Transform for this configuration. This
	* Transform is typically the Identity transform for most normal
	* screens. Device coordinates for screen and printer devices will
	* have the origin in the upper left-hand corner of the target region of
	* the device, with X coordinates
	* increasing to the right and Y coordinates increasing downwards.
	* For image buffers, this Transform will be the Identity transform.
	*/
	public AffineTransform getDefaultTransform() {
	return new AffineTransform();
	}

	/**
	*
	* Returns a Transform that can be composed with the default Transform
	* of a Graphics2D so that 72 units in user space will equal 1 inch
	* in device space.
	* Given a Graphics2D, g, one can reset the transformation to create
	* such a mapping by using the following pseudocode:
	* <pre>
	* GraphicsConfiguration gc = g.getGraphicsConfiguration();
	*
	* g.setTransform(gc.getDefaultTransform());
	* g.transform(gc.getNormalizingTransform());
	* </pre>
	* Note that sometimes this Transform will be identity (e.g. for
	* printers or metafile output) and that this Transform is only
	* as accurate as the information supplied by the underlying system.
	* For image buffers, this Transform will be the Identity transform,
	* since there is no valid distance measurement.
	*/
	public AffineTransform getNormalizingTransform() {
	Win32GraphicsEnvironment ge = (Win32GraphicsEnvironment)
	GraphicsEnvironment.getLocalGraphicsEnvironment();
	double xscale = ge.getXResolution() / 72.0;
	double yscale = ge.getYResolution() / 72.0;
	return new AffineTransform(xscale, 0.0, 0.0, yscale, 0.0, 0.0);
	}

	public String toString() {
	return (super.toString()+"[dev="+screen+",pixfmt="+visual+"]");
	}

	private native Rectangle getBounds(int screen);

	public Rectangle getBounds() {
	return getBounds(screen.getScreen());
	}

	public synchronized void displayChanged() {
	solidloops = null;
	}

	public void paletteChanged() {}

	/**
	* The following methods are invoked from WComponentPeer.java rather
	* than having the Win32-dependent implementations hardcoded in that
	* class. This way the appropriate actions are taken based on the peer's
	* GraphicsConfig, whether it is a Win32GraphicsConfig or a
	* WGLGraphicsConfig.
	*/

	/**
	* Creates a new SurfaceData that will be associated with the given
	* WComponentPeer.
	*/
	public SurfaceData createSurfaceData(WComponentPeer peer,
	int numBackBuffers)
	{
	return GDIWindowSurfaceData.createData(peer);
	}

	/**
	* Creates a new managed image of the given width and height
	* that is associated with the target Component.
	*/
	public Image createAcceleratedImage(Component target,
	int width, int height)
	{
	ColorModel model = getColorModel(Transparency.OPAQUE);
	WritableRaster wr =
	model.createCompatibleWritableRaster(width, height);
	return new OffScreenImage(target, model, wr,
	model.isAlphaPremultiplied());
	}

	/**
	* The following methods correspond to the multibuffering methods in
	* WComponentPeer.java...
	*/

	/**
	* Checks that the requested configuration is natively supported; if not,
	* an AWTException is thrown.
	*/
	public void assertOperationSupported(Component target,
	int numBuffers,
	BufferCapabilities caps)
	throws AWTException
	{
	// the default pipeline doesn't support flip buffer strategy
	throw new AWTException(
	"The operation requested is not supported");
	}

	/**
	* This method is called from WComponentPeer when a surface data is replaced
	* REMIND: while the default pipeline doesn't support flipping, it may
	* happen that the accelerated device may have this graphics config
	* (like if the device restoration failed when one device exits fs mode
	* while others remain).
	*/
	public VolatileImage createBackBuffer(WComponentPeer peer) {
	Component target = (Component)peer.getTarget();
	return new SunVolatileImage(target,
	target.getWidth(), target.getHeight(),
	Boolean.TRUE);
	}

	/**
	* Performs the native flip operation for the given target Component.
	*
	* REMIND: we should really not get here because that would mean that
	* a FLIP BufferStrategy has been created, and one could only be created
	* if accelerated pipeline is present but in some rare (and transitional)
	* cases it may happen that the accelerated graphics device may have a
	* default graphics configuraiton, so this is just a precaution.
	*/
	public void flip(WComponentPeer peer,
	Component target, VolatileImage backBuffer,
	int x1, int y1, int x2, int y2,
	BufferCapabilities.FlipContents flipAction)
	{
	if (flipAction == BufferCapabilities.FlipContents.COPIED \|\|
	flipAction == BufferCapabilities.FlipContents.UNDEFINED) {
	Graphics g = peer.getGraphics();
	try {
	g.drawImage(backBuffer,
	x1, y1, x2, y2,
	x1, y1, x2, y2,
	null);
	} finally {
	g.dispose();
	}
	} else if (flipAction == BufferCapabilities.FlipContents.BACKGROUND) {
	Graphics g = backBuffer.getGraphics();
	try {
	g.setColor(target.getBackground());
	g.fillRect(0, 0,
	backBuffer.getWidth(),
	backBuffer.getHeight());
	} finally {
	g.dispose();
	}
	}
	// the rest of the flip actions are not supported
	}

	@Override
	public boolean isTranslucencyCapable() {
	//XXX: worth checking if 8-bit? Anyway, it doesn't hurt.
	return true;
	}
	}