path: root/libjava/java/awt/image/ColorModel.java

/* Copyright © 2000  Free Software Foundation

   This file is part of libgcj.

This software is copyrighted work licensed under the terms of the
Libgcj License.  Please consult the file "LIBGCJ_LICENSE" for
details.  */

package java.awt.image;

import java.awt.Point;
import java.awt.Transparency;
import java.awt.color.ColorSpace;
import gnu.gcj.awt.Buffers;

/**
 * A color model operates with colors in several formats:
 *
 * <ul>
 * <li>normalized: component samples are in range [0.0, 1.0].</li>
 *
 * <li>color model pixel value: all the color component samples for a
 * sigle pixel packed/encoded in a way natural for the color
 * model.</li>
 *
 * <li>color model pixel int value: only makes sense if the natural
 * encoding of a single pixel can fit in a single int value.</li>
 *
 * <li>array of transferType containing a single pixel: the pixel is
 * encoded in the natural way of the color model, taking up as many
 * array elements as needed.</li>
 *
 * <li>sRGB pixel int value: a pixel in sRGB color space, encoded in
 * default 0xAARRGGBB format, assumed not alpha premultiplied.</li>
 * 
 * <li>single [0, 255] scaled int samples from default sRGB color
 * space. These are always assumed to be alpha non-premultiplied.</li>
 *
 * <li>arrays of unnormalized component samples of single pixel: these
 * samples are scaled and multiplied according to the color model, but
 * is otherwise not packed or encoded. Each element of the array is one
 * seperate component sample. The color model only operate on the
 * components from one pixel at a time, but using offsets, allows
 * manipulation of arrays that contain the components of more than one
 * pixel.</li>
 *
 * </ul>
 *
 * @author Rolf W. Rasmussen <rolfwr@ii.uib.no>
 */

public abstract class ColorModel implements Transparency
{
  protected int pixel_bits;
  protected int transferType;

  int[] bits;
  ColorSpace cspace;
  int transparency;
  boolean hasAlpha;
  boolean isAlphaPremultiplied;
    
  static int[] nArray(int value, int times)
  {
    int[] array = new int[times];
    java.util.Arrays.fill(array, value);
    return array;
  }

  static byte[] nArray(byte value, int times)
  {
    byte[] array = new byte[times];
    java.util.Arrays.fill(array, value);
    return array;
  } 

  public ColorModel(int bits)
  {
    this(bits * 4, // total bits, sRGB, four channels
	 nArray(bits, 4), // bits for each channel
	 null, // FIXME: should be sRGB
	 true, // has alpha
	 false, // not premultiplied
	 TRANSLUCENT,
	 Buffers.smallestAppropriateTransferType(bits * 4));
  }

  protected ColorModel(int pixel_bits, int[] bits, ColorSpace cspace,
		       boolean hasAlpha, boolean isAlphaPremultiplied,
		       int transparency, int transferType)
  {
    this.pixel_bits = pixel_bits;
    this.bits = bits;
    this.cspace = cspace;
    this.hasAlpha = hasAlpha;
    this.isAlphaPremultiplied = isAlphaPremultiplied;
    this.transparency = transparency;
    this.transferType = transferType;
  }

  public static ColorModel getRGBdefault()
  {
    return new DirectColorModel(8, 0xff0000, 0xff00, 0xff, 0xff000000);
  }

  public final boolean hasAlpha()
  {
    return hasAlpha;
  }

  public final boolean isAlphaPremultiplied()
  {
    return isAlphaPremultiplied;
  }

  public int getPixelSize()
  {
    return pixel_bits;
  }
    
  public int getComponentSize(int componentIdx)
  {
    return bits[componentIdx];
  }
    
  public int[] getComponentSize()
  {
    return bits;
  }

  public int getTransparency()
  {
    return transparency;
  }

  public int getNumComponents()
  {
    return getNumColorComponents() + (hasAlpha ? 1 : 0);
  }

  public int getNumColorComponents()
  {
    return cspace.getNumComponents();
  }

  /**
   * Converts pixel value to sRGB and extract red int sample scaled
   * to range [0, 255].
   *
   * @param pixel pixel value that will be interpreted according to
   * the color model, (assumed alpha premultiplied if color model says
   * so.)
   *
   * @return red sample scaled to range [0, 255], from default color
   * space sRGB, alpha non-premultiplied.
   */
  public abstract int getRed(int pixel);

  /**
   * Converts pixel value to sRGB and extract green int sample
   * scaled to range [0, 255].
   *
   * @see #getRed(int)
   */
    public abstract int getGreen(int pixel);
    
  /**
   * Converts pixel value to sRGB and extract blue int sample
   * scaled to range [0, 255].
   *
   * @see #getRed(int)
   */
  public abstract int getBlue(int pixel);

  /**
   * Extract alpha int sample from pixel value, scaled to [0, 255].
   *
   * @param pixel pixel value that will be interpreted according to
   * the color model.
   *
   * @return alpha sample, scaled to range [0, 255].
   */
  public abstract int getAlpha(int pixel);

  /**
   * Converts a pixel int value of the color space of the color
   * model to a sRGB pixel int value.
   *
   * This method is typically overriden in subclasses to provide a
   * more efficient implementation.
   * 
   * @param pixel pixel value that will be interpreted according to
   * the color model.
   *
   * @return a pixel in sRGB color space, encoded in default
   * 0xAARRGGBB format.  */
  public int getRGB(int pixel)
  {
    return 
      ((getAlpha(pixel) & 0xff) << 24) |
      ((  getRed(pixel) & 0xff) << 16) |
      ((getGreen(pixel) & 0xff) <<  8) |
      (( getBlue(pixel) & 0xff) <<  0);
  }
  

  /**
   * In this color model we know that the whole pixel value will
   * always be contained within the first element of the pixel
   * array.
   */
  final int getPixelFromArray(Object inData) {
    DataBuffer data =
      Buffers.createBufferFromData(transferType, inData, 1);
    Object da = Buffers.getData(data);

    return data.getElem(0);
  }

  /** 
   * Converts pixel in the given array to sRGB and extract blue int
   * sample scaled to range [0-255].
   *
   * This method is typically overriden in subclasses to provide a
   * more efficient implementation.
   * 
   * @param array of transferType containing a single pixel.  The
   * pixel should be encoded in the natural way of the color model.
   */
  public int getRed(Object inData)
  {
    return getRed(getPixelFromArray(inData));
  }

  /**
   * @see #getRed(Object)
   */
  public int getGreen(Object inData)
  {
    return getGreen(getPixelFromArray(inData));
  }

  /**
   * @see #getRed(Object)
   */
  public int getBlue(Object inData) {
    return getBlue(getPixelFromArray(inData));
  }

  /**
   * @see #getRed(Object)
   */
  public int getAlpha(Object inData) {
    return getBlue(getPixelFromArray(inData));
  }

  /**
   * Converts a pixel in the given array of the color space of the
   * color model to an sRGB pixel int value.
   *
   * <p>This method performs the inverse function of
   * <code>getDataElements(int rgb, Object pixel)</code>.
   * I.e. <code>(rgb == cm.getRGB(cm.getDataElements(rgb,
   * null)))</code>.
   *
   * @param inData array of transferType containing a single pixel. The
   * pixel should be encoded in the natural way of the color model.
   *
   * @return a pixel in sRGB color space, encoded in default
   * 0xAARRGGBB format.
   *
   * @see #getDataElements(int, Object)
   */
  public int getRGB(Object inData)
  {
    return 
      ((getAlpha(inData) & 0xff) << 24) |
      ((  getRed(inData) & 0xff) << 16) |
      ((getGreen(inData) & 0xff) <<  8) |
      (( getBlue(inData) & 0xff) <<  0);
  }

  /**
   * Converts an sRGB pixel int value 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>.
   *
   * Outline of conversion process:
   *
   * <ol>
   *
   * <li>Convert rgb to normalized [0.0, 1.0] sRGB values.</li>
   *
   * <li>Convert to color space components using fromRGB in
   * ColorSpace.</li>
   *
   * <li>If color model has alpha and should be premultiplied,
   * multiply color space components with alpha value</li>
   *
   * <li>Scale the components to the correct number of bits.</li>
   *
   * <li>Arrange the components in the output array</li>
   * 
   * </ol>
   *
   * @param rgb The color to be converted to dataElements.  A pixel
   * in sRGB color space, encoded in default 0xAARRGGBB format,
   * assumed not alpha premultiplied.
   *
   * @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 An array of transferType values representing the color,
   * in the color model format. The color model defines whether the
   *  
   * @see #getRGB(Object)
   */
  public Object getDataElements(int rgb, Object pixel)
  {
    // FIXME: implement
    throw new UnsupportedOperationException();
  }

  /**
   * Fills an array with the unnormalized component samples from a
   * pixel value. I.e. decompose the pixel, but not perform any
   * color conversion. 
   *
   * This method is typically overriden in subclasses to provide a
   * more efficient implementation.
   * 
   * @param pixel pixel value encoded according to the color model.
   *
   * @return arrays of unnormalized component samples of single
   * pixel.  The scale and multiplication state of the samples are
   * according to the color model. Each component sample is stored
   * as a seperate element in the array.
   */
  public int[] getComponents(int pixel, int[] components, int offset) {
    // FIXME: implement
    throw new UnsupportedOperationException();
  }
  
  /**
   * Fills an array with the unnormalized component samples from an
   * array of transferType containing a single pixel. I.e. decompose
   * the pixel, but not perform any color conversion.
   *
   * This method is typically overriden in subclasses to provide a
   * more efficient implementation.
   *
   * @param array of transferType containing a single pixel.  The
   * pixel should be encoded in the natural way of the color model.
   * 
   * @return arrays of unnormalized component samples of single
   * pixel.  The scale and multiplication state of the samples are
   * according to the color model. Each component sample is stored
   * as a seperate element in the array.
   */
  public int[] getComponents(Object pixel, int[] components, int offset)
  {
    throw new UnsupportedOperationException();
  }

  /**
   * Convert normalized components to unnormalized components.
   */
  public int[] getUnnormalizedComponents(float[] normComponents,
					 int normOffset,
					 int[] components,
					 int offset)
  {
    int numComponents = getNumComponents();
    if (components == null)
    {
      components = new int[offset + numComponents];
    }
    
    for (int i=0; i<numComponents; i++)
    {
      float in = normComponents[normOffset++];
      int out = (int) (in * ((2<<getComponentSize(i)) - 1));
      components[offset++] = out;
    }
    return components;
  }

  /**
   * Convert unnormalized components to normalized components.
   */
  public float[] getNormalizedComponents(int[] components,
					 int offset,
					 float[] normComponents,
					 int normOffset)
  {
    int numComponents = getNumComponents();
    if (normComponents == null)
    {
      normComponents = new float[normOffset + numComponents];
    }

    for (int i=0; i<numComponents; i++)
    {
      float in = components[offset++];
      float out = in / ((2<<getComponentSize(i)) - 1);
      normComponents[normOffset++] = out;
    }
    return normComponents;
  }

  /**
   * Converts the unnormalized component samples from an array to a
   * pixel value. I.e. composes the pixel from component samples, but
   * does not perform any color conversion or scaling of the samples.
   * 
   * This method performs the inverse function of
   * <code>getComponents(int pixel, int[] components,
   *			       int offset)</code>. I.e.
   *
   * <code>(pixel == cm.getDataElement(cm.getComponents(pixel, null,
   * 0), 0))</code>.
   *
   * This method is typically overriden in subclasses to provide a
   * more efficient implementation.
   *
   * @param arrays of unnormalized component samples of single
   * pixel.  The scale and multiplication state of the samples are
   * according to the color model. Each component sample is stored
   * as a seperate element in the array.
   *
   * @return pixel value encoded according to the color model.
   */
  public int getDataElement(int[] components, int offset)
  {
    throw new UnsupportedOperationException();
  }

  public Object getDataElements(int[] components, int offset, Object obj)
  {
    throw new UnsupportedOperationException();
  }

  public boolean equals(Object obj)
  {
    if (!(obj instanceof ColorModel)) return false;

    ColorModel o = (ColorModel) obj;
    return 
      (pixel_bits == o.pixel_bits) &&
      (transferType == o.transferType) &&
      (transparency == o.transparency) &&
      (hasAlpha == o.hasAlpha) &&
      (isAlphaPremultiplied == isAlphaPremultiplied) &&
      (bits.equals(o.bits)) &&
      (cspace.equals(o.cspace));
  }

  public final ColorSpace getColorSpace()
  {
    return cspace;
  }

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

    int w = raster.getWidth();
    int h = raster.getHeight();
    int x = raster.getMinX();
    int y = raster.getMinY();
    int size = w*h;
    int numColors = getNumColorComponents();
    int numComponents = getNumComponents();
    int alphaScale = (1<<getComponentSize(numColors)) - 1;
    double[] pixels = raster.getPixels(x, y, w, h, (double[]) null);

    for (int i=0; i<size; i++)
      {
	double alpha = pixels[i*numComponents+numColors]*alphaScale;
	for (int c=0; c<numColors; c++)
	  {
	    int offset = i*numComponents+c;
	    if (isAlphaPremultiplied)
		pixels[offset] = pixels[offset]/alpha;
	    else
	      pixels[offset] = pixels[offset]*alpha;
	  }
      }
    
    raster.setPixels(0, 0, w, h, pixels);

    // FIXME: what can we return?
    return null;
  }
    
  // Typically overridden
  public boolean isCompatibleRaster(Raster raster)
  {
    SampleModel sampleModel = raster.getSampleModel();
    return isCompatibleSampleModel(sampleModel);
  }

  // Typically overridden
  public WritableRaster createCompatibleWritableRaster(int w, int h)
  {
    return new WritableRaster(createCompatibleSampleModel(w, h),
			      new Point(0, 0));
  }

  // Typically overridden
  public SampleModel createCompatibleSampleModel(int w, int h)
  {
    throw new UnsupportedOperationException();
  }

  // Typically overridden
  public boolean isCompatibleSampleModel(SampleModel sm)
  {
    return sm.getTransferType() == transferType;
  }

  public void finalize() {
  }

  /**
   * Subclasses must override this method if it is possible for the
   * color model to have an alpha channel.
   *
   * @return null, as per JDK 1.3 doc. Subclasses will only return
   * null if no alpha raster exists.
   */
  public WritableRaster getAlphaRaster(WritableRaster raster)
  {
    return null;
    
    /* It is a mystery to me why we couldn't use the following code...
       
       
       if (!hasAlpha()) return null;
       
       SampleModel sm = raster.getSampleModel();
       int[] alphaBand = { sm.getNumBands() - 1 };
       SampleModel alphaModel = sm.createSubsetSampleModel(alphaBand);
       DataBuffer buffer = raster.getDataBuffer();
       Point origin = new Point(0, 0);
       return Raster.createWritableRaster(alphaModel, buffer, origin);
       

       ...here, and avoided overriding the method in subclasses,
       but the Sun docs state that this method always will return
       null, and that overriding is required. Oh, well.
    */
  }

  String stringParam()
  {
    return "pixel_bits=" + pixel_bits +
      ", cspace=" + cspace +
      ", transferType=" + transferType +
      ", transparency=" + transparency +
      ", hasAlpha=" + hasAlpha +
      ", isAlphaPremultiplied=" + isAlphaPremultiplied;
  }

  public String toString()
  {
    return getClass().getName() + "[" + stringParam() + "]";
  }
}