llvm-gcc-4.0/libjava/java/awt/image/DirectColorModel.java - llvm-archive - Git at Google

 /* DirectColorModel.java --
    Copyright (C) 1999, 2000, 2002, 2004  Free Software Foundation

 This file is part of GNU Classpath.

 GNU Classpath is free software; you can redistribute it and/or modify
 it under the terms of the GNU General Public License as published by
 the Free Software Foundation; either version 2, or (at your option)
 any later version.

 GNU Classpath 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 for more details.

 You should have received a copy of the GNU General Public License
 along with GNU Classpath; see the file COPYING.  If not, write to the
 Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
 02111-1307 USA.

 Linking this library statically or dynamically with other modules is
 making a combined work based on this library.  Thus, the terms and
 conditions of the GNU General Public License cover the whole
 combination.

 As a special exception, the copyright holders of this library give you
 permission to link this library with independent modules to produce an
 executable, regardless of the license terms of these independent
 modules, and to copy and distribute the resulting executable under
 terms of your choice, provided that you also meet, for each linked
 independent module, the terms and conditions of the license of that
 module.  An independent module is a module which is not derived from
 or based on this library.  If you modify this library, you may extend
 this exception to your version of the library, but you are not
 obligated to do so.  If you do not wish to do so, delete this
 exception statement from your version. */


 package java.awt.image;

 import gnu.java.awt.Buffers;

 import java.awt.Point;
 import java.awt.Transparency;
 import java.awt.color.ColorSpace;

 /**
  * @author Rolf W. Rasmussen (rolfwr@ii.uib.no)
  * @author C. Brian Jones (cbj@gnu.org)
  * @author Mark Benvenuto (mcb54@columbia.edu)
  */
 public class DirectColorModel extends PackedColorModel
 {
   /**
    * For the color model created with this constructor the pixels
    * will have fully opaque alpha components with a value of 255.
    * Each mask should describe a fully contiguous set of bits in the
    * most likely order of alpha, red, green, blue from the most significant
    * byte to the least significant byte.
    *
    * @param pixelBits the number of bits wide used for bit size of pixel values
    * @param rmask the bits describing the red component of a pixel
    * @param gmask the bits describing the green component of a pixel
    * @param bmask the bits describing the blue component of a pixel
    */
   public DirectColorModel(int pixelBits, int rmask, int gmask, int bmask)
   {
     this(ColorSpace.getInstance(ColorSpace.CS_sRGB), pixelBits,
 	 rmask, gmask, bmask, 0,
 	 false, // not alpha premultiplied
 	 Buffers.smallestAppropriateTransferType(pixelBits) // find type
 	 );
   }

   /**
    * For the color model created with this constructor the pixels
    * will have fully opaque alpha components with a value of 255.
    * Each mask should describe a fully contiguous set of bits in the
    * most likely order of red, green, blue from the most significant
    * byte to the least significant byte.
    *
    * @param pixelBits the number of bits wide used for bit size of pixel values
    * @param rmask the bits describing the red component of a pixel
    * @param gmask the bits describing the green component of a pixel
    * @param bmask the bits describing the blue component of a pixel
    * @param amask the bits describing the alpha component of a pixel
    */
   public DirectColorModel(int pixelBits,
 			  int rmask, int gmask, int bmask, int amask)
   {
     this(ColorSpace.getInstance(ColorSpace.CS_sRGB), pixelBits,
 	 rmask, gmask, bmask, amask,
 	 false, // not alpha premultiplied
 	 Buffers.smallestAppropriateTransferType(pixelBits) // find type
 	 );
   }

   public DirectColorModel(ColorSpace cspace, int pixelBits,
 			  int rmask, int gmask, int bmask, int amask,
 			  boolean isAlphaPremultiplied,
 			  int transferType)
   {
     super(cspace, pixelBits,
 	  rmask, gmask, bmask, amask, isAlphaPremultiplied,
 	  ((amask == 0) ? Transparency.OPAQUE : Transparency.TRANSLUCENT),
 	  transferType);
   }

   public final int getRedMask()
   {
     return getMask(0);
   }

   public final int getGreenMask()
   {
     return getMask(1);
   }

   public final int getBlueMask()
   {
     return getMask(2);
   }

   public final int getAlphaMask()
   {
     return hasAlpha() ? getMask(3) : 0;
   }

   /**
    * Get the red component of the given pixel.
    * <br>
    */
   public final int getRed(int pixel)
   {
     return extractAndNormalizeSample(pixel, 0);
   }

   /**
    * Get the green component of the given pixel.
    * <br>
    */
   public final int getGreen(int pixel)
   {
     return extractAndNormalizeSample(pixel, 1);
   }

   /**
    * Get the blue component of the given pixel.
    * <br>
    */
   public final int getBlue(int pixel)
   {
     return extractAndNormalizeSample(pixel, 2);
   }

   /**
    * Get the alpha component of the given pixel.
    * <br>
    */
   public final int getAlpha(int pixel)
   {
     if (!hasAlpha())
       return 0;
     return extractAndScaleSample(pixel, 3);
   }

   private int extractAndNormalizeSample(int pixel, int component)
   {
     int value = extractAndScaleSample(pixel, component);
     if (hasAlpha() && isAlphaPremultiplied())
       value = value*255/getAlpha(pixel);
     return value;
   }

   private int extractAndScaleSample(int pixel, int component)
   {
     int field = pixel & getMask(component);
     int to8BitShift =
       8 - shifts[component] - getComponentSize(component);
     return (to8BitShift>0) ?
       (field << to8BitShift) :
       (field >>> (-to8BitShift));
   }

   /**
    * Get the RGB color value of the given pixel using the default
    * RGB color model.
    * <br>
    *
    * @param pixel a pixel value
    */
   public final int getRGB(int pixel)
   {
     /* FIXME: The Sun docs show that this method is overridden, but I
        don't see any way to improve on the superclass
        implementation. */
     return super.getRGB(pixel);
   }

   public int getRed(Object inData)
   {
     return getRed(getPixelFromArray(inData));
   }

   public int getGreen(Object inData)
   {
     return getGreen(getPixelFromArray(inData));
   }

   public int getBlue(Object inData)
   {
     return getBlue(getPixelFromArray(inData));
   }

   public int getAlpha(Object inData)
   {
     return getAlpha(getPixelFromArray(inData));
   }

   public int getRGB(Object inData)
   {
     return getRGB(getPixelFromArray(inData));
   }

   /**
    * Converts a normalized pixel int value in the sRGB color
    * space to an array containing a single pixel of the color space
    * of the color model.
    *
    * <p>This method performs the inverse function of
    * <code>getRGB(Object inData)</code>.
    *
    * @param rgb pixel as a normalized sRGB, 0xAARRGGBB value.
    *
    * @param pixel to avoid needless creation of arrays, an array to
    * use to return the pixel can be given. If null, a suitable array
    * will be created.
    *
    * @return array of transferType containing a single pixel. The
    * pixel should be encoded in the natural way of the color model.
    *
    * @see #getRGB(Object)
    */
   public Object getDataElements(int rgb, Object pixel)
   {
     // FIXME: handle alpha multiply

     int pixelValue = 0;
     int a = 0;
     if (hasAlpha()) {
       a = (rgb >>> 24) & 0xff;
       pixelValue = valueToField(a, 3, 8);
     }

     if (hasAlpha() && isAlphaPremultiplied())
       {
 	int r, g, b;
 	/* if r=0xff and a=0xff, then resulting
 	   value will be (r*a)>>>8 == 0xfe... This seems wrong.
 	   We should divide by 255 rather than shifting >>>8 after
 	   multiplying.

 	   Too bad, shifting is probably less expensive.
 	   r = ((rgb >>> 16) & 0xff)*a;
 	   g = ((rgb >>>  8) & 0xff)*a;
 	   b = ((rgb >>> 0) & 0xff)*a; */
 	/* The r, g, b values we calculate are 16 bit. This allows
 	   us to avoid discarding the lower 8 bits obtained if
 	   multiplying with the alpha band. */

 	// using 16 bit values
 	r = ((rgb >>> 8) & 0xff00)*a/255;
 	g = ((rgb >>> 0) & 0xff00)*a/255;
 	b = ((rgb <<  8) & 0xff00)*a/255;
 	pixelValue |=
 	  valueToField(r, 0, 16) |  // Red
 	  valueToField(g, 1, 16) |  // Green
 	  valueToField(b, 2, 16);   // Blue
       }
     else
       {
 	int r, g, b;
 	// using 8 bit values
 	r = (rgb >>> 16) & 0xff;
 	g = (rgb >>>  8) & 0xff;
 	b = (rgb >>>  0) & 0xff;

 	pixelValue |=
 	  valueToField(r, 0, 8) |  // Red
 	  valueToField(g, 1, 8) |  // Green
 	  valueToField(b, 2, 8);   // Blue
       }

     /* In this color model, the whole pixel fits in the first element
        of the array. */
     DataBuffer buffer = Buffers.createBuffer(transferType, pixel, 1);
     buffer.setElem(0, pixelValue);
     return Buffers.getData(buffer);
   }

   /**
    * Converts a value to the correct field bits based on the
    * information derived from the field masks.
    *
    * @param highBit the position of the most significant bit in the
    * val parameter.
    */
   private int valueToField(int val, int component, int highBit)
   {
     int toFieldShift =
       getComponentSize(component) + shifts[component] - highBit;
     int ret = (toFieldShift>0) ?
       (val << toFieldShift) :
       (val >>> (-toFieldShift));
     return ret & getMask(component);
   }

   /**
    * Converts a 16 bit value to the correct field bits based on the
    * information derived from the field masks.
    */
   private int value16ToField(int val, int component)
   {
     int toFieldShift = getComponentSize(component) + shifts[component] - 16;
     return (toFieldShift>0) ?
       (val << toFieldShift) :
       (val >>> (-toFieldShift));
   }

   /**
    * Fills an array with the unnormalized component samples from a
    * pixel value. I.e. decompose the pixel, but not perform any
    * color conversion.
    */
   public final int[] getComponents(int pixel, int[] components, int offset)
   {
     int numComponents = getNumComponents();
     if (components == null) components = new int[offset + numComponents];

     for (int b=0; b<numComponents; b++)
       components[offset++] = (pixel&getMask(b)) >>> shifts[b];

     return components;
   }

   public final int[] getComponents(Object pixel, int[] components,
 				   int offset)
   {
     return getComponents(getPixelFromArray(pixel), components, offset);
   }

   public final WritableRaster createCompatibleWritableRaster(int w, int h)
   {
     SampleModel sm = createCompatibleSampleModel(w, h);
     Point origin = new Point(0, 0);
     return Raster.createWritableRaster(sm, origin);
   }

   public int getDataElement(int[] components, int offset)
   {
     int numComponents = getNumComponents();
     int pixelValue = 0;

     for (int c=0; c<numComponents; c++)
       pixelValue |= (components[offset++] << shifts[c]) & getMask(c);

     return pixelValue;
   }

   public Object getDataElements(int[] components, int offset, Object obj)
   {
     /* In this color model, the whole pixel fits in the first element
        of the array. */
     int pixelValue = getDataElement(components, offset);

     DataBuffer buffer = Buffers.createBuffer(transferType, obj, 1);
     buffer.setElem(0, pixelValue);
     return Buffers.getData(buffer);
   }

   public final ColorModel coerceData (WritableRaster raster,
 				      boolean isAlphaPremultiplied)
   {
     if (this.isAlphaPremultiplied == isAlphaPremultiplied)
       return this;

     /* TODO: provide better implementation based on the
        assumptions we can make due to the specific type of the
        color model. */
     super.coerceData(raster, isAlphaPremultiplied);

     return new ComponentColorModel(cspace, bits, hasAlpha(),
 				   isAlphaPremultiplied, // argument
 				   transparency, transferType);
   }

   public boolean isCompatibleRaster(Raster raster)
   {
     /* FIXME: the Sun docs say this method is overridden here,
        but I don't see any way to improve upon the implementation
        in ColorModel. */
     return super.isCompatibleRaster(raster);
   }

   String stringParam()
   {
     return super.stringParam() +
       ", redMask=" + Integer.toHexString(getRedMask()) +
       ", greenMask=" + Integer.toHexString(getGreenMask()) +
       ", blueMask=" + Integer.toHexString(getBlueMask()) +
       ", alphaMask=" + Integer.toHexString(getAlphaMask());
   }

   public String toString()
   {
     /* FIXME: Again, docs say override, but how do we improve upon the
        superclass implementation? */
     return super.toString();
   }
 }
	/* DirectColorModel.java --
	Copyright (C) 1999, 2000, 2002, 2004 Free Software Foundation

	This file is part of GNU Classpath.

	GNU Classpath is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 2, or (at your option)
	any later version.

	GNU Classpath 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 for more details.

	You should have received a copy of the GNU General Public License
	along with GNU Classpath; see the file COPYING. If not, write to the
	Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
	02111-1307 USA.

	Linking this library statically or dynamically with other modules is
	making a combined work based on this library. Thus, the terms and
	conditions of the GNU General Public License cover the whole
	combination.

	As a special exception, the copyright holders of this library give you
	permission to link this library with independent modules to produce an
	executable, regardless of the license terms of these independent
	modules, and to copy and distribute the resulting executable under
	terms of your choice, provided that you also meet, for each linked
	independent module, the terms and conditions of the license of that
	module. An independent module is a module which is not derived from
	or based on this library. If you modify this library, you may extend
	this exception to your version of the library, but you are not
	obligated to do so. If you do not wish to do so, delete this
	exception statement from your version. */


	package java.awt.image;

	import gnu.java.awt.Buffers;

	import java.awt.Point;
	import java.awt.Transparency;
	import java.awt.color.ColorSpace;

	/**
	* @author Rolf W. Rasmussen (rolfwr@ii.uib.no)
	* @author C. Brian Jones (cbj@gnu.org)
	* @author Mark Benvenuto (mcb54@columbia.edu)
	*/
	public class DirectColorModel extends PackedColorModel
	{
	/**
	* For the color model created with this constructor the pixels
	* will have fully opaque alpha components with a value of 255.
	* Each mask should describe a fully contiguous set of bits in the
	* most likely order of alpha, red, green, blue from the most significant
	* byte to the least significant byte.
	*
	* @param pixelBits the number of bits wide used for bit size of pixel values
	* @param rmask the bits describing the red component of a pixel
	* @param gmask the bits describing the green component of a pixel
	* @param bmask the bits describing the blue component of a pixel
	*/
	public DirectColorModel(int pixelBits, int rmask, int gmask, int bmask)
	{
	this(ColorSpace.getInstance(ColorSpace.CS_sRGB), pixelBits,
	rmask, gmask, bmask, 0,
	false, // not alpha premultiplied
	Buffers.smallestAppropriateTransferType(pixelBits) // find type
	);
	}

	/**
	* For the color model created with this constructor the pixels
	* will have fully opaque alpha components with a value of 255.
	* Each mask should describe a fully contiguous set of bits in the
	* most likely order of red, green, blue from the most significant
	* byte to the least significant byte.
	*
	* @param pixelBits the number of bits wide used for bit size of pixel values
	* @param rmask the bits describing the red component of a pixel
	* @param gmask the bits describing the green component of a pixel
	* @param bmask the bits describing the blue component of a pixel
	* @param amask the bits describing the alpha component of a pixel
	*/
	public DirectColorModel(int pixelBits,
	int rmask, int gmask, int bmask, int amask)
	{
	this(ColorSpace.getInstance(ColorSpace.CS_sRGB), pixelBits,
	rmask, gmask, bmask, amask,
	false, // not alpha premultiplied
	Buffers.smallestAppropriateTransferType(pixelBits) // find type
	);
	}

	public DirectColorModel(ColorSpace cspace, int pixelBits,
	int rmask, int gmask, int bmask, int amask,
	boolean isAlphaPremultiplied,
	int transferType)
	{
	super(cspace, pixelBits,
	rmask, gmask, bmask, amask, isAlphaPremultiplied,
	((amask == 0) ? Transparency.OPAQUE : Transparency.TRANSLUCENT),
	transferType);
	}

	public final int getRedMask()
	{
	return getMask(0);
	}

	public final int getGreenMask()
	{
	return getMask(1);
	}

	public final int getBlueMask()
	{
	return getMask(2);
	}

	public final int getAlphaMask()
	{
	return hasAlpha() ? getMask(3) : 0;
	}

	/**
	* Get the red component of the given pixel.
	* <br>
	*/
	public final int getRed(int pixel)
	{
	return extractAndNormalizeSample(pixel, 0);
	}

	/**
	* Get the green component of the given pixel.
	* <br>
	*/
	public final int getGreen(int pixel)
	{
	return extractAndNormalizeSample(pixel, 1);
	}

	/**
	* Get the blue component of the given pixel.
	* <br>
	*/
	public final int getBlue(int pixel)
	{
	return extractAndNormalizeSample(pixel, 2);
	}

	/**
	* Get the alpha component of the given pixel.
	* <br>
	*/
	public final int getAlpha(int pixel)
	{
	if (!hasAlpha())
	return 0;
	return extractAndScaleSample(pixel, 3);
	}

	private int extractAndNormalizeSample(int pixel, int component)
	{
	int value = extractAndScaleSample(pixel, component);
	if (hasAlpha() && isAlphaPremultiplied())
	value = value*255/getAlpha(pixel);
	return value;
	}

	private int extractAndScaleSample(int pixel, int component)
	{
	int field = pixel & getMask(component);
	int to8BitShift =
	8 - shifts[component] - getComponentSize(component);
	return (to8BitShift>0) ?
	(field << to8BitShift) :
	(field >>> (-to8BitShift));
	}

	/**
	* Get the RGB color value of the given pixel using the default
	* RGB color model.
	* <br>
	*
	* @param pixel a pixel value
	*/
	public final int getRGB(int pixel)
	{
	/* FIXME: The Sun docs show that this method is overridden, but I
	don't see any way to improve on the superclass
	implementation. */
	return super.getRGB(pixel);
	}

	public int getRed(Object inData)
	{
	return getRed(getPixelFromArray(inData));
	}

	public int getGreen(Object inData)
	{
	return getGreen(getPixelFromArray(inData));
	}

	public int getBlue(Object inData)
	{
	return getBlue(getPixelFromArray(inData));
	}

	public int getAlpha(Object inData)
	{
	return getAlpha(getPixelFromArray(inData));
	}

	public int getRGB(Object inData)
	{
	return getRGB(getPixelFromArray(inData));
	}

	/**
	* Converts a normalized pixel int value in the sRGB color
	* space to an array containing a single pixel of the color space
	* of the color model.
	*
	* <p>This method performs the inverse function of
	* <code>getRGB(Object inData)</code>.
	*
	* @param rgb pixel as a normalized sRGB, 0xAARRGGBB value.
	*
	* @param pixel to avoid needless creation of arrays, an array to
	* use to return the pixel can be given. If null, a suitable array
	* will be created.
	*
	* @return array of transferType containing a single pixel. The
	* pixel should be encoded in the natural way of the color model.
	*
	* @see #getRGB(Object)
	*/
	public Object getDataElements(int rgb, Object pixel)
	{
	// FIXME: handle alpha multiply

	int pixelValue = 0;
	int a = 0;
	if (hasAlpha()) {
	a = (rgb >>> 24) & 0xff;
	pixelValue = valueToField(a, 3, 8);
	}

	if (hasAlpha() && isAlphaPremultiplied())
	{
	int r, g, b;
	/* if r=0xff and a=0xff, then resulting
	value will be (r*a)>>>8 == 0xfe... This seems wrong.
	We should divide by 255 rather than shifting >>>8 after
	multiplying.

	Too bad, shifting is probably less expensive.
	r = ((rgb >>> 16) & 0xff)*a;
	g = ((rgb >>> 8) & 0xff)*a;
	b = ((rgb >>> 0) & 0xff)a; /
	/* The r, g, b values we calculate are 16 bit. This allows
	us to avoid discarding the lower 8 bits obtained if
	multiplying with the alpha band. */

	// using 16 bit values
	r = ((rgb >>> 8) & 0xff00)*a/255;
	g = ((rgb >>> 0) & 0xff00)*a/255;
	b = ((rgb << 8) & 0xff00)*a/255;
	pixelValue \|=
	valueToField(r, 0, 16) \| // Red
	valueToField(g, 1, 16) \| // Green
	valueToField(b, 2, 16); // Blue
	}
	else
	{
	int r, g, b;
	// using 8 bit values
	r = (rgb >>> 16) & 0xff;
	g = (rgb >>> 8) & 0xff;
	b = (rgb >>> 0) & 0xff;

	pixelValue \|=
	valueToField(r, 0, 8) \| // Red
	valueToField(g, 1, 8) \| // Green
	valueToField(b, 2, 8); // Blue
	}

	/* In this color model, the whole pixel fits in the first element
	of the array. */
	DataBuffer buffer = Buffers.createBuffer(transferType, pixel, 1);
	buffer.setElem(0, pixelValue);
	return Buffers.getData(buffer);
	}

	/**
	* Converts a value to the correct field bits based on the
	* information derived from the field masks.
	*
	* @param highBit the position of the most significant bit in the
	* val parameter.
	*/
	private int valueToField(int val, int component, int highBit)
	{
	int toFieldShift =
	getComponentSize(component) + shifts[component] - highBit;
	int ret = (toFieldShift>0) ?
	(val << toFieldShift) :
	(val >>> (-toFieldShift));
	return ret & getMask(component);
	}

	/**
	* Converts a 16 bit value to the correct field bits based on the
	* information derived from the field masks.
	*/
	private int value16ToField(int val, int component)
	{
	int toFieldShift = getComponentSize(component) + shifts[component] - 16;
	return (toFieldShift>0) ?
	(val << toFieldShift) :
	(val >>> (-toFieldShift));
	}

	/**
	* Fills an array with the unnormalized component samples from a
	* pixel value. I.e. decompose the pixel, but not perform any
	* color conversion.
	*/
	public final int[] getComponents(int pixel, int[] components, int offset)
	{
	int numComponents = getNumComponents();
	if (components == null) components = new int[offset + numComponents];

	for (int b=0; b<numComponents; b++)
	components[offset++] = (pixel&getMask(b)) >>> shifts[b];

	return components;
	}

	public final int[] getComponents(Object pixel, int[] components,
	int offset)
	{
	return getComponents(getPixelFromArray(pixel), components, offset);
	}

	public final WritableRaster createCompatibleWritableRaster(int w, int h)
	{
	SampleModel sm = createCompatibleSampleModel(w, h);
	Point origin = new Point(0, 0);
	return Raster.createWritableRaster(sm, origin);
	}

	public int getDataElement(int[] components, int offset)
	{
	int numComponents = getNumComponents();
	int pixelValue = 0;

	for (int c=0; c<numComponents; c++)
	pixelValue \|= (components[offset++] << shifts[c]) & getMask(c);

	return pixelValue;
	}

	public Object getDataElements(int[] components, int offset, Object obj)
	{
	/* In this color model, the whole pixel fits in the first element
	of the array. */
	int pixelValue = getDataElement(components, offset);

	DataBuffer buffer = Buffers.createBuffer(transferType, obj, 1);
	buffer.setElem(0, pixelValue);
	return Buffers.getData(buffer);
	}

	public final ColorModel coerceData (WritableRaster raster,
	boolean isAlphaPremultiplied)
	{
	if (this.isAlphaPremultiplied == isAlphaPremultiplied)
	return this;

	/* TODO: provide better implementation based on the
	assumptions we can make due to the specific type of the
	color model. */
	super.coerceData(raster, isAlphaPremultiplied);

	return new ComponentColorModel(cspace, bits, hasAlpha(),
	isAlphaPremultiplied, // argument
	transparency, transferType);
	}

	public boolean isCompatibleRaster(Raster raster)
	{
	/* FIXME: the Sun docs say this method is overridden here,
	but I don't see any way to improve upon the implementation
	in ColorModel. */
	return super.isCompatibleRaster(raster);
	}

	String stringParam()
	{
	return super.stringParam() +
	", redMask=" + Integer.toHexString(getRedMask()) +
	", greenMask=" + Integer.toHexString(getGreenMask()) +
	", blueMask=" + Integer.toHexString(getBlueMask()) +
	", alphaMask=" + Integer.toHexString(getAlphaMask());
	}

	public String toString()
	{
	/* FIXME: Again, docs say override, but how do we improve upon the
	superclass implementation? */
	return super.toString();
	}
	}