src/java.desktop/share/classes/java/awt/image/AffineTransformOp.java - platform/libcore - Git at Google

 /*
  * Copyright (c) 1997, 2014, 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 java.awt.image;

 import java.awt.geom.AffineTransform;
 import java.awt.geom.NoninvertibleTransformException;
 import java.awt.geom.Rectangle2D;
 import java.awt.geom.Point2D;
 import java.awt.AlphaComposite;
 import java.awt.GraphicsEnvironment;
 import java.awt.Rectangle;
 import java.awt.RenderingHints;
 import java.awt.Transparency;
 import java.lang.annotation.Native;
 import sun.awt.image.ImagingLib;

 /**
  * This class uses an affine transform to perform a linear mapping from
  * 2D coordinates in the source image or {@code Raster} to 2D coordinates
  * in the destination image or {@code Raster}.
  * The type of interpolation that is used is specified through a constructor,
  * either by a {@code RenderingHints} object or by one of the integer
  * interpolation types defined in this class.
  * <p>
  * If a {@code RenderingHints} object is specified in the constructor, the
  * interpolation hint and the rendering quality hint are used to set
  * the interpolation type for this operation.  The color rendering hint
  * and the dithering hint can be used when color conversion is required.
  * <p>
  * Note that the following constraints have to be met:
  * <ul>
  * <li>The source and destination must be different.
  * <li>For {@code Raster} objects, the number of bands in the source must
  * be equal to the number of bands in the destination.
  * </ul>
  * @see AffineTransform
  * @see BufferedImageFilter
  * @see java.awt.RenderingHints#KEY_INTERPOLATION
  * @see java.awt.RenderingHints#KEY_RENDERING
  * @see java.awt.RenderingHints#KEY_COLOR_RENDERING
  * @see java.awt.RenderingHints#KEY_DITHERING
  */
 public class AffineTransformOp implements BufferedImageOp, RasterOp {
     private AffineTransform xform;
     RenderingHints hints;

     /**
      * Nearest-neighbor interpolation type.
      */
     @Native public static final int TYPE_NEAREST_NEIGHBOR = 1;

     /**
      * Bilinear interpolation type.
      */
     @Native public static final int TYPE_BILINEAR = 2;

     /**
      * Bicubic interpolation type.
      */
     @Native public static final int TYPE_BICUBIC = 3;

     int interpolationType = TYPE_NEAREST_NEIGHBOR;

     /**
      * Constructs an {@code AffineTransformOp} given an affine transform.
      * The interpolation type is determined from the
      * {@code RenderingHints} object.  If the interpolation hint is
      * defined, it will be used. Otherwise, if the rendering quality hint is
      * defined, the interpolation type is determined from its value.  If no
      * hints are specified ({@code hints} is null),
      * the interpolation type is {@link #TYPE_NEAREST_NEIGHBOR
      * TYPE_NEAREST_NEIGHBOR}.
      *
      * @param xform The {@code AffineTransform} to use for the
      * operation.
      *
      * @param hints The {@code RenderingHints} object used to specify
      * the interpolation type for the operation.
      *
      * @throws ImagingOpException if the transform is non-invertible.
      * @see java.awt.RenderingHints#KEY_INTERPOLATION
      * @see java.awt.RenderingHints#KEY_RENDERING
      */
     public AffineTransformOp(AffineTransform xform, RenderingHints hints){
         validateTransform(xform);
         this.xform = (AffineTransform) xform.clone();
         this.hints = hints;

         if (hints != null) {
             Object value = hints.get(RenderingHints.KEY_INTERPOLATION);
             if (value == null) {
                 value = hints.get(RenderingHints.KEY_RENDERING);
                 if (value == RenderingHints.VALUE_RENDER_SPEED) {
                     interpolationType = TYPE_NEAREST_NEIGHBOR;
                 }
                 else if (value == RenderingHints.VALUE_RENDER_QUALITY) {
                     interpolationType = TYPE_BILINEAR;
                 }
             }
             else if (value == RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR) {
                 interpolationType = TYPE_NEAREST_NEIGHBOR;
             }
             else if (value == RenderingHints.VALUE_INTERPOLATION_BILINEAR) {
                 interpolationType = TYPE_BILINEAR;
             }
             else if (value == RenderingHints.VALUE_INTERPOLATION_BICUBIC) {
                 interpolationType = TYPE_BICUBIC;
             }
         }
         else {
             interpolationType = TYPE_NEAREST_NEIGHBOR;
         }
     }

     /**
      * Constructs an {@code AffineTransformOp} given an affine transform
      * and the interpolation type.
      *
      * @param xform The {@code AffineTransform} to use for the operation.
      * @param interpolationType One of the integer
      * interpolation type constants defined by this class:
      * {@link #TYPE_NEAREST_NEIGHBOR TYPE_NEAREST_NEIGHBOR},
      * {@link #TYPE_BILINEAR TYPE_BILINEAR},
      * {@link #TYPE_BICUBIC TYPE_BICUBIC}.
      * @throws ImagingOpException if the transform is non-invertible.
      */
     public AffineTransformOp(AffineTransform xform, int interpolationType) {
         validateTransform(xform);
         this.xform = (AffineTransform)xform.clone();
         switch(interpolationType) {
             case TYPE_NEAREST_NEIGHBOR:
             case TYPE_BILINEAR:
             case TYPE_BICUBIC:
                 break;
         default:
             throw new IllegalArgumentException("Unknown interpolation type: "+
                                                interpolationType);
         }
         this.interpolationType = interpolationType;
     }

     /**
      * Returns the interpolation type used by this op.
      * @return the interpolation type.
      * @see #TYPE_NEAREST_NEIGHBOR
      * @see #TYPE_BILINEAR
      * @see #TYPE_BICUBIC
      */
     public final int getInterpolationType() {
         return interpolationType;
     }

     /**
      * Transforms the source {@code BufferedImage} and stores the results
      * in the destination {@code BufferedImage}.
      * If the color models for the two images do not match, a color
      * conversion into the destination color model is performed.
      * If the destination image is null,
      * a {@code BufferedImage} is created with the source
      * {@code ColorModel}.
      * <p>
      * The coordinates of the rectangle returned by
      * {@code getBounds2D(BufferedImage)}
      * are not necessarily the same as the coordinates of the
      * {@code BufferedImage} returned by this method.  If the
      * upper-left corner coordinates of the rectangle are
      * negative then this part of the rectangle is not drawn.  If the
      * upper-left corner coordinates of the  rectangle are positive
      * then the filtered image is drawn at that position in the
      * destination {@code BufferedImage}.
      * <p>
      * An {@code IllegalArgumentException} is thrown if the source is
      * the same as the destination.
      *
      * @param src The {@code BufferedImage} to transform.
      * @param dst The {@code BufferedImage} in which to store the results
      * of the transformation.
      *
      * @return The filtered {@code BufferedImage}.
      * @throws IllegalArgumentException if {@code src} and
      *         {@code dst} are the same
      * @throws ImagingOpException if the image cannot be transformed
      *         because of a data-processing error that might be
      *         caused by an invalid image format, tile format, or
      *         image-processing operation, or any other unsupported
      *         operation.
      */
     public final BufferedImage filter(BufferedImage src, BufferedImage dst) {

         if (src == null) {
             throw new NullPointerException("src image is null");
         }
         if (src == dst) {
             throw new IllegalArgumentException("src image cannot be the "+
                                                "same as the dst image");
         }

         boolean needToConvert = false;
         ColorModel srcCM = src.getColorModel();
         ColorModel dstCM;
         BufferedImage origDst = dst;

         if (dst == null) {
             dst = createCompatibleDestImage(src, null);
             dstCM = srcCM;
             origDst = dst;
         }
         else {
             dstCM = dst.getColorModel();
             if (srcCM.getColorSpace().getType() !=
                 dstCM.getColorSpace().getType())
             {
                 int type = xform.getType();
                 boolean needTrans = ((type&
                                       (AffineTransform.TYPE_MASK_ROTATION|
                                        AffineTransform.TYPE_GENERAL_TRANSFORM))
                                      != 0);
                 if (! needTrans &&
                     type != AffineTransform.TYPE_TRANSLATION &&
                     type != AffineTransform.TYPE_IDENTITY)
                 {
                     double[] mtx = new double[4];
                     xform.getMatrix(mtx);
                     // Check out the matrix.  A non-integral scale will force ARGB
                     // since the edge conditions can't be guaranteed.
                     needTrans = (mtx[0] != (int)mtx[0] || mtx[3] != (int)mtx[3]);
                 }

                 if (needTrans &&
                     srcCM.getTransparency() == Transparency.OPAQUE)
                 {
                     // Need to convert first
                     ColorConvertOp ccop = new ColorConvertOp(hints);
                     BufferedImage tmpSrc = null;
                     int sw = src.getWidth();
                     int sh = src.getHeight();
                     if (dstCM.getTransparency() == Transparency.OPAQUE) {
                         tmpSrc = new BufferedImage(sw, sh,
                                                   BufferedImage.TYPE_INT_ARGB);
                     }
                     else {
                         WritableRaster r =
                             dstCM.createCompatibleWritableRaster(sw, sh);
                         tmpSrc = new BufferedImage(dstCM, r,
                                                   dstCM.isAlphaPremultiplied(),
                                                   null);
                     }
                     src = ccop.filter(src, tmpSrc);
                 }
                 else {
                     needToConvert = true;
                     dst = createCompatibleDestImage(src, null);
                 }
             }

         }

         if (interpolationType != TYPE_NEAREST_NEIGHBOR &&
             dst.getColorModel() instanceof IndexColorModel) {
             dst = new BufferedImage(dst.getWidth(), dst.getHeight(),
                                     BufferedImage.TYPE_INT_ARGB);
         }
         if (ImagingLib.filter(this, src, dst) == null) {
             throw new ImagingOpException ("Unable to transform src image");
         }

         if (needToConvert) {
             ColorConvertOp ccop = new ColorConvertOp(hints);
             ccop.filter(dst, origDst);
         }
         else if (origDst != dst) {
             java.awt.Graphics2D g = origDst.createGraphics();
             try {
                 g.setComposite(AlphaComposite.Src);
                 g.drawImage(dst, 0, 0, null);
             } finally {
                 g.dispose();
             }
         }

         return origDst;
     }

     /**
      * Transforms the source {@code Raster} and stores the results in
      * the destination {@code Raster}.  This operation performs the
      * transform band by band.
      * <p>
      * If the destination {@code Raster} is null, a new
      * {@code Raster} is created.
      * An {@code IllegalArgumentException} may be thrown if the source is
      * the same as the destination or if the number of bands in
      * the source is not equal to the number of bands in the
      * destination.
      * <p>
      * The coordinates of the rectangle returned by
      * {@code getBounds2D(Raster)}
      * are not necessarily the same as the coordinates of the
      * {@code WritableRaster} returned by this method.  If the
      * upper-left corner coordinates of rectangle are negative then
      * this part of the rectangle is not drawn.  If the coordinates
      * of the rectangle are positive then the filtered image is drawn at
      * that position in the destination {@code Raster}.
      *
      * @param src The {@code Raster} to transform.
      * @param dst The {@code Raster} in which to store the results of the
      * transformation.
      *
      * @return The transformed {@code Raster}.
      *
      * @throws ImagingOpException if the raster cannot be transformed
      *         because of a data-processing error that might be
      *         caused by an invalid image format, tile format, or
      *         image-processing operation, or any other unsupported
      *         operation.
      */
     public final WritableRaster filter(Raster src, WritableRaster dst) {
         if (src == null) {
             throw new NullPointerException("src image is null");
         }
         if (dst == null) {
             dst = createCompatibleDestRaster(src);
         }
         if (src == dst) {
             throw new IllegalArgumentException("src image cannot be the "+
                                                "same as the dst image");
         }
         if (src.getNumBands() != dst.getNumBands()) {
             throw new IllegalArgumentException("Number of src bands ("+
                                                src.getNumBands()+
                                                ") does not match number of "+
                                                " dst bands ("+
                                                dst.getNumBands()+")");
         }

         if (ImagingLib.filter(this, src, dst) == null) {
             throw new ImagingOpException ("Unable to transform src image");
         }
         return dst;
     }

     /**
      * Returns the bounding box of the transformed destination.  The
      * rectangle returned is the actual bounding box of the
      * transformed points.  The coordinates of the upper-left corner
      * of the returned rectangle might not be (0,&nbsp;0).
      *
      * @param src The {@code BufferedImage} to be transformed.
      *
      * @return The {@code Rectangle2D} representing the destination's
      * bounding box.
      */
     public final Rectangle2D getBounds2D (BufferedImage src) {
         return getBounds2D(src.getRaster());
     }

     /**
      * Returns the bounding box of the transformed destination.  The
      * rectangle returned will be the actual bounding box of the
      * transformed points.  The coordinates of the upper-left corner
      * of the returned rectangle might not be (0,&nbsp;0).
      *
      * @param src The {@code Raster} to be transformed.
      *
      * @return The {@code Rectangle2D} representing the destination's
      * bounding box.
      */
     public final Rectangle2D getBounds2D (Raster src) {
         int w = src.getWidth();
         int h = src.getHeight();

         // Get the bounding box of the src and transform the corners
         float[] pts = {0, 0, w, 0, w, h, 0, h};
         xform.transform(pts, 0, pts, 0, 4);

         // Get the min, max of the dst
         float fmaxX = pts[0];
         float fmaxY = pts[1];
         float fminX = pts[0];
         float fminY = pts[1];
         for (int i=2; i < 8; i+=2) {
             if (pts[i] > fmaxX) {
                 fmaxX = pts[i];
             }
             else if (pts[i] < fminX) {
                 fminX = pts[i];
             }
             if (pts[i+1] > fmaxY) {
                 fmaxY = pts[i+1];
             }
             else if (pts[i+1] < fminY) {
                 fminY = pts[i+1];
             }
         }

         return new Rectangle2D.Float(fminX, fminY, fmaxX-fminX, fmaxY-fminY);
     }

     /**
      * Creates a zeroed destination image with the correct size and number of
      * bands.  A {@code RasterFormatException} may be thrown if the
      * transformed width or height is equal to 0.
      * <p>
      * If {@code destCM} is null,
      * an appropriate {@code ColorModel} is used; this
      * {@code ColorModel} may have
      * an alpha channel even if the source {@code ColorModel} is opaque.
      *
      * @param src  The {@code BufferedImage} to be transformed.
      * @param destCM  {@code ColorModel} of the destination.  If null,
      * an appropriate {@code ColorModel} is used.
      *
      * @return The zeroed destination image.
      */
     public BufferedImage createCompatibleDestImage (BufferedImage src,
                                                     ColorModel destCM) {
         BufferedImage image;
         Rectangle r = getBounds2D(src).getBounds();

         // If r.x (or r.y) is < 0, then we want to only create an image
         // that is in the positive range.
         // If r.x (or r.y) is > 0, then we need to create an image that
         // includes the translation.
         int w = r.x + r.width;
         int h = r.y + r.height;
         if (w <= 0) {
             throw new RasterFormatException("Transformed width ("+w+
                                             ") is less than or equal to 0.");
         }
         if (h <= 0) {
             throw new RasterFormatException("Transformed height ("+h+
                                             ") is less than or equal to 0.");
         }

         if (destCM == null) {
             ColorModel cm = src.getColorModel();
             if (interpolationType != TYPE_NEAREST_NEIGHBOR &&
                 (cm instanceof IndexColorModel ||
                  cm.getTransparency() == Transparency.OPAQUE))
             {
                 image = new BufferedImage(w, h,
                                           BufferedImage.TYPE_INT_ARGB);
             }
             else {
                 image = new BufferedImage(cm,
                           src.getRaster().createCompatibleWritableRaster(w,h),
                           cm.isAlphaPremultiplied(), null);
             }
         }
         else {
             image = new BufferedImage(destCM,
                                     destCM.createCompatibleWritableRaster(w,h),
                                     destCM.isAlphaPremultiplied(), null);
         }

         return image;
     }

     /**
      * Creates a zeroed destination {@code Raster} with the correct size
      * and number of bands.  A {@code RasterFormatException} may be thrown
      * if the transformed width or height is equal to 0.
      *
      * @param src The {@code Raster} to be transformed.
      *
      * @return The zeroed destination {@code Raster}.
      */
     public WritableRaster createCompatibleDestRaster (Raster src) {
         Rectangle2D r = getBounds2D(src);

         return src.createCompatibleWritableRaster((int)r.getX(),
                                                   (int)r.getY(),
                                                   (int)r.getWidth(),
                                                   (int)r.getHeight());
     }

     /**
      * Returns the location of the corresponding destination point given a
      * point in the source.  If {@code dstPt} is specified, it
      * is used to hold the return value.
      *
      * @param srcPt The {@code Point2D} that represents the source
      *              point.
      * @param dstPt The {@code Point2D} in which to store the result.
      *
      * @return The {@code Point2D} in the destination that corresponds to
      * the specified point in the source.
      */
     public final Point2D getPoint2D (Point2D srcPt, Point2D dstPt) {
         return xform.transform (srcPt, dstPt);
     }

     /**
      * Returns the affine transform used by this transform operation.
      *
      * @return The {@code AffineTransform} associated with this op.
      */
     public final AffineTransform getTransform() {
         return (AffineTransform) xform.clone();
     }

     /**
      * Returns the rendering hints used by this transform operation.
      *
      * @return The {@code RenderingHints} object associated with this op.
      */
     public final RenderingHints getRenderingHints() {
         if (hints == null) {
             Object val;
             switch(interpolationType) {
             case TYPE_NEAREST_NEIGHBOR:
                 val = RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR;
                 break;
             case TYPE_BILINEAR:
                 val = RenderingHints.VALUE_INTERPOLATION_BILINEAR;
                 break;
             case TYPE_BICUBIC:
                 val = RenderingHints.VALUE_INTERPOLATION_BICUBIC;
                 break;
             default:
                 // Should never get here
                 throw new InternalError("Unknown interpolation type "+
                                          interpolationType);

             }
             hints = new RenderingHints(RenderingHints.KEY_INTERPOLATION, val);
         }

         return hints;
     }

     // We need to be able to invert the transform if we want to
     // transform the image.  If the determinant of the matrix is 0,
     // then we can't invert the transform.
     void validateTransform(AffineTransform xform) {
         if (Math.abs(xform.getDeterminant()) <= Double.MIN_VALUE) {
             throw new ImagingOpException("Unable to invert transform "+xform);
         }
     }
 }
	/*
	* Copyright (c) 1997, 2014, 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 java.awt.image;

	import java.awt.geom.AffineTransform;
	import java.awt.geom.NoninvertibleTransformException;
	import java.awt.geom.Rectangle2D;
	import java.awt.geom.Point2D;
	import java.awt.AlphaComposite;
	import java.awt.GraphicsEnvironment;
	import java.awt.Rectangle;
	import java.awt.RenderingHints;
	import java.awt.Transparency;
	import java.lang.annotation.Native;
	import sun.awt.image.ImagingLib;

	/**
	* This class uses an affine transform to perform a linear mapping from
	* 2D coordinates in the source image or {@code Raster} to 2D coordinates
	* in the destination image or {@code Raster}.
	* The type of interpolation that is used is specified through a constructor,
	* either by a {@code RenderingHints} object or by one of the integer
	* interpolation types defined in this class.
	* <p>
	* If a {@code RenderingHints} object is specified in the constructor, the
	* interpolation hint and the rendering quality hint are used to set
	* the interpolation type for this operation. The color rendering hint
	* and the dithering hint can be used when color conversion is required.
	* <p>
	* Note that the following constraints have to be met:
	* <ul>
	* <li>The source and destination must be different.
	* <li>For {@code Raster} objects, the number of bands in the source must
	* be equal to the number of bands in the destination.
	* </ul>
	* @see AffineTransform
	* @see BufferedImageFilter
	* @see java.awt.RenderingHints#KEY_INTERPOLATION
	* @see java.awt.RenderingHints#KEY_RENDERING
	* @see java.awt.RenderingHints#KEY_COLOR_RENDERING
	* @see java.awt.RenderingHints#KEY_DITHERING
	*/
	public class AffineTransformOp implements BufferedImageOp, RasterOp {
	private AffineTransform xform;
	RenderingHints hints;

	/**
	* Nearest-neighbor interpolation type.
	*/
	@Native public static final int TYPE_NEAREST_NEIGHBOR = 1;

	/**
	* Bilinear interpolation type.
	*/
	@Native public static final int TYPE_BILINEAR = 2;

	/**
	* Bicubic interpolation type.
	*/
	@Native public static final int TYPE_BICUBIC = 3;

	int interpolationType = TYPE_NEAREST_NEIGHBOR;

	/**
	* Constructs an {@code AffineTransformOp} given an affine transform.
	* The interpolation type is determined from the
	* {@code RenderingHints} object. If the interpolation hint is
	* defined, it will be used. Otherwise, if the rendering quality hint is
	* defined, the interpolation type is determined from its value. If no
	* hints are specified ({@code hints} is null),
	* the interpolation type is {@link #TYPE_NEAREST_NEIGHBOR
	* TYPE_NEAREST_NEIGHBOR}.
	*
	* @param xform The {@code AffineTransform} to use for the
	* operation.
	*
	* @param hints The {@code RenderingHints} object used to specify
	* the interpolation type for the operation.
	*
	* @throws ImagingOpException if the transform is non-invertible.
	* @see java.awt.RenderingHints#KEY_INTERPOLATION
	* @see java.awt.RenderingHints#KEY_RENDERING
	*/
	public AffineTransformOp(AffineTransform xform, RenderingHints hints){
	validateTransform(xform);
	this.xform = (AffineTransform) xform.clone();
	this.hints = hints;

	if (hints != null) {
	Object value = hints.get(RenderingHints.KEY_INTERPOLATION);
	if (value == null) {
	value = hints.get(RenderingHints.KEY_RENDERING);
	if (value == RenderingHints.VALUE_RENDER_SPEED) {
	interpolationType = TYPE_NEAREST_NEIGHBOR;
	}
	else if (value == RenderingHints.VALUE_RENDER_QUALITY) {
	interpolationType = TYPE_BILINEAR;
	}
	}
	else if (value == RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR) {
	interpolationType = TYPE_NEAREST_NEIGHBOR;
	}
	else if (value == RenderingHints.VALUE_INTERPOLATION_BILINEAR) {
	interpolationType = TYPE_BILINEAR;
	}
	else if (value == RenderingHints.VALUE_INTERPOLATION_BICUBIC) {
	interpolationType = TYPE_BICUBIC;
	}
	}
	else {
	interpolationType = TYPE_NEAREST_NEIGHBOR;
	}
	}

	/**
	* Constructs an {@code AffineTransformOp} given an affine transform
	* and the interpolation type.
	*
	* @param xform The {@code AffineTransform} to use for the operation.
	* @param interpolationType One of the integer
	* interpolation type constants defined by this class:
	* {@link #TYPE_NEAREST_NEIGHBOR TYPE_NEAREST_NEIGHBOR},
	* {@link #TYPE_BILINEAR TYPE_BILINEAR},
	* {@link #TYPE_BICUBIC TYPE_BICUBIC}.
	* @throws ImagingOpException if the transform is non-invertible.
	*/
	public AffineTransformOp(AffineTransform xform, int interpolationType) {
	validateTransform(xform);
	this.xform = (AffineTransform)xform.clone();
	switch(interpolationType) {
	case TYPE_NEAREST_NEIGHBOR:
	case TYPE_BILINEAR:
	case TYPE_BICUBIC:
	break;
	default:
	throw new IllegalArgumentException("Unknown interpolation type: "+
	interpolationType);
	}
	this.interpolationType = interpolationType;
	}

	/**
	* Returns the interpolation type used by this op.
	* @return the interpolation type.
	* @see #TYPE_NEAREST_NEIGHBOR
	* @see #TYPE_BILINEAR
	* @see #TYPE_BICUBIC
	*/
	public final int getInterpolationType() {
	return interpolationType;
	}

	/**
	* Transforms the source {@code BufferedImage} and stores the results
	* in the destination {@code BufferedImage}.
	* If the color models for the two images do not match, a color
	* conversion into the destination color model is performed.
	* If the destination image is null,
	* a {@code BufferedImage} is created with the source
	* {@code ColorModel}.
	* <p>
	* The coordinates of the rectangle returned by
	* {@code getBounds2D(BufferedImage)}
	* are not necessarily the same as the coordinates of the
	* {@code BufferedImage} returned by this method. If the
	* upper-left corner coordinates of the rectangle are
	* negative then this part of the rectangle is not drawn. If the
	* upper-left corner coordinates of the rectangle are positive
	* then the filtered image is drawn at that position in the
	* destination {@code BufferedImage}.
	* <p>
	* An {@code IllegalArgumentException} is thrown if the source is
	* the same as the destination.
	*
	* @param src The {@code BufferedImage} to transform.
	* @param dst The {@code BufferedImage} in which to store the results
	* of the transformation.
	*
	* @return The filtered {@code BufferedImage}.
	* @throws IllegalArgumentException if {@code src} and
	* {@code dst} are the same
	* @throws ImagingOpException if the image cannot be transformed
	* because of a data-processing error that might be
	* caused by an invalid image format, tile format, or
	* image-processing operation, or any other unsupported
	* operation.
	*/
	public final BufferedImage filter(BufferedImage src, BufferedImage dst) {

	if (src == null) {
	throw new NullPointerException("src image is null");
	}
	if (src == dst) {
	throw new IllegalArgumentException("src image cannot be the "+
	"same as the dst image");
	}

	boolean needToConvert = false;
	ColorModel srcCM = src.getColorModel();
	ColorModel dstCM;
	BufferedImage origDst = dst;

	if (dst == null) {
	dst = createCompatibleDestImage(src, null);
	dstCM = srcCM;
	origDst = dst;
	}
	else {
	dstCM = dst.getColorModel();
	if (srcCM.getColorSpace().getType() !=
	dstCM.getColorSpace().getType())
	{
	int type = xform.getType();
	boolean needTrans = ((type&
	(AffineTransform.TYPE_MASK_ROTATION\|
	AffineTransform.TYPE_GENERAL_TRANSFORM))
	!= 0);
	if (! needTrans &&
	type != AffineTransform.TYPE_TRANSLATION &&
	type != AffineTransform.TYPE_IDENTITY)
	{
	double[] mtx = new double[4];
	xform.getMatrix(mtx);
	// Check out the matrix. A non-integral scale will force ARGB
	// since the edge conditions can't be guaranteed.
	needTrans = (mtx[0] != (int)mtx[0] \|\| mtx[3] != (int)mtx[3]);
	}

	if (needTrans &&
	srcCM.getTransparency() == Transparency.OPAQUE)
	{
	// Need to convert first
	ColorConvertOp ccop = new ColorConvertOp(hints);
	BufferedImage tmpSrc = null;
	int sw = src.getWidth();
	int sh = src.getHeight();
	if (dstCM.getTransparency() == Transparency.OPAQUE) {
	tmpSrc = new BufferedImage(sw, sh,
	BufferedImage.TYPE_INT_ARGB);
	}
	else {
	WritableRaster r =
	dstCM.createCompatibleWritableRaster(sw, sh);
	tmpSrc = new BufferedImage(dstCM, r,
	dstCM.isAlphaPremultiplied(),
	null);
	}
	src = ccop.filter(src, tmpSrc);
	}
	else {
	needToConvert = true;
	dst = createCompatibleDestImage(src, null);
	}
	}

	}

	if (interpolationType != TYPE_NEAREST_NEIGHBOR &&
	dst.getColorModel() instanceof IndexColorModel) {
	dst = new BufferedImage(dst.getWidth(), dst.getHeight(),
	BufferedImage.TYPE_INT_ARGB);
	}
	if (ImagingLib.filter(this, src, dst) == null) {
	throw new ImagingOpException ("Unable to transform src image");
	}

	if (needToConvert) {
	ColorConvertOp ccop = new ColorConvertOp(hints);
	ccop.filter(dst, origDst);
	}
	else if (origDst != dst) {
	java.awt.Graphics2D g = origDst.createGraphics();
	try {
	g.setComposite(AlphaComposite.Src);
	g.drawImage(dst, 0, 0, null);
	} finally {
	g.dispose();
	}
	}

	return origDst;
	}

	/**
	* Transforms the source {@code Raster} and stores the results in
	* the destination {@code Raster}. This operation performs the
	* transform band by band.
	* <p>
	* If the destination {@code Raster} is null, a new
	* {@code Raster} is created.
	* An {@code IllegalArgumentException} may be thrown if the source is
	* the same as the destination or if the number of bands in
	* the source is not equal to the number of bands in the
	* destination.
	* <p>
	* The coordinates of the rectangle returned by
	* {@code getBounds2D(Raster)}
	* are not necessarily the same as the coordinates of the
	* {@code WritableRaster} returned by this method. If the
	* upper-left corner coordinates of rectangle are negative then
	* this part of the rectangle is not drawn. If the coordinates
	* of the rectangle are positive then the filtered image is drawn at
	* that position in the destination {@code Raster}.
	*
	* @param src The {@code Raster} to transform.
	* @param dst The {@code Raster} in which to store the results of the
	* transformation.
	*
	* @return The transformed {@code Raster}.
	*
	* @throws ImagingOpException if the raster cannot be transformed
	* because of a data-processing error that might be
	* caused by an invalid image format, tile format, or
	* image-processing operation, or any other unsupported
	* operation.
	*/
	public final WritableRaster filter(Raster src, WritableRaster dst) {
	if (src == null) {
	throw new NullPointerException("src image is null");
	}
	if (dst == null) {
	dst = createCompatibleDestRaster(src);
	}
	if (src == dst) {
	throw new IllegalArgumentException("src image cannot be the "+
	"same as the dst image");
	}
	if (src.getNumBands() != dst.getNumBands()) {
	throw new IllegalArgumentException("Number of src bands ("+
	src.getNumBands()+
	") does not match number of "+
	" dst bands ("+
	dst.getNumBands()+")");
	}

	if (ImagingLib.filter(this, src, dst) == null) {
	throw new ImagingOpException ("Unable to transform src image");
	}
	return dst;
	}

	/**
	* Returns the bounding box of the transformed destination. The
	* rectangle returned is the actual bounding box of the
	* transformed points. The coordinates of the upper-left corner
	* of the returned rectangle might not be (0, 0).
	*
	* @param src The {@code BufferedImage} to be transformed.
	*
	* @return The {@code Rectangle2D} representing the destination's
	* bounding box.
	*/
	public final Rectangle2D getBounds2D (BufferedImage src) {
	return getBounds2D(src.getRaster());
	}

	/**
	* Returns the bounding box of the transformed destination. The
	* rectangle returned will be the actual bounding box of the
	* transformed points. The coordinates of the upper-left corner
	* of the returned rectangle might not be (0, 0).
	*
	* @param src The {@code Raster} to be transformed.
	*
	* @return The {@code Rectangle2D} representing the destination's
	* bounding box.
	*/
	public final Rectangle2D getBounds2D (Raster src) {
	int w = src.getWidth();
	int h = src.getHeight();

	// Get the bounding box of the src and transform the corners
	float[] pts = {0, 0, w, 0, w, h, 0, h};
	xform.transform(pts, 0, pts, 0, 4);

	// Get the min, max of the dst
	float fmaxX = pts[0];
	float fmaxY = pts[1];
	float fminX = pts[0];
	float fminY = pts[1];
	for (int i=2; i < 8; i+=2) {
	if (pts[i] > fmaxX) {
	fmaxX = pts[i];
	}
	else if (pts[i] < fminX) {
	fminX = pts[i];
	}
	if (pts[i+1] > fmaxY) {
	fmaxY = pts[i+1];
	}
	else if (pts[i+1] < fminY) {
	fminY = pts[i+1];
	}
	}

	return new Rectangle2D.Float(fminX, fminY, fmaxX-fminX, fmaxY-fminY);
	}

	/**
	* Creates a zeroed destination image with the correct size and number of
	* bands. A {@code RasterFormatException} may be thrown if the
	* transformed width or height is equal to 0.
	* <p>
	* If {@code destCM} is null,
	* an appropriate {@code ColorModel} is used; this
	* {@code ColorModel} may have
	* an alpha channel even if the source {@code ColorModel} is opaque.
	*
	* @param src The {@code BufferedImage} to be transformed.
	* @param destCM {@code ColorModel} of the destination. If null,
	* an appropriate {@code ColorModel} is used.
	*
	* @return The zeroed destination image.
	*/
	public BufferedImage createCompatibleDestImage (BufferedImage src,
	ColorModel destCM) {
	BufferedImage image;
	Rectangle r = getBounds2D(src).getBounds();

	// If r.x (or r.y) is < 0, then we want to only create an image
	// that is in the positive range.
	// If r.x (or r.y) is > 0, then we need to create an image that
	// includes the translation.
	int w = r.x + r.width;
	int h = r.y + r.height;
	if (w <= 0) {
	throw new RasterFormatException("Transformed width ("+w+
	") is less than or equal to 0.");
	}
	if (h <= 0) {
	throw new RasterFormatException("Transformed height ("+h+
	") is less than or equal to 0.");
	}

	if (destCM == null) {
	ColorModel cm = src.getColorModel();
	if (interpolationType != TYPE_NEAREST_NEIGHBOR &&
	(cm instanceof IndexColorModel \|\|
	cm.getTransparency() == Transparency.OPAQUE))
	{
	image = new BufferedImage(w, h,
	BufferedImage.TYPE_INT_ARGB);
	}
	else {
	image = new BufferedImage(cm,
	src.getRaster().createCompatibleWritableRaster(w,h),
	cm.isAlphaPremultiplied(), null);
	}
	}
	else {
	image = new BufferedImage(destCM,
	destCM.createCompatibleWritableRaster(w,h),
	destCM.isAlphaPremultiplied(), null);
	}

	return image;
	}

	/**
	* Creates a zeroed destination {@code Raster} with the correct size
	* and number of bands. A {@code RasterFormatException} may be thrown
	* if the transformed width or height is equal to 0.
	*
	* @param src The {@code Raster} to be transformed.
	*
	* @return The zeroed destination {@code Raster}.
	*/
	public WritableRaster createCompatibleDestRaster (Raster src) {
	Rectangle2D r = getBounds2D(src);

	return src.createCompatibleWritableRaster((int)r.getX(),
	(int)r.getY(),
	(int)r.getWidth(),
	(int)r.getHeight());
	}

	/**
	* Returns the location of the corresponding destination point given a
	* point in the source. If {@code dstPt} is specified, it
	* is used to hold the return value.
	*
	* @param srcPt The {@code Point2D} that represents the source
	* point.
	* @param dstPt The {@code Point2D} in which to store the result.
	*
	* @return The {@code Point2D} in the destination that corresponds to
	* the specified point in the source.
	*/
	public final Point2D getPoint2D (Point2D srcPt, Point2D dstPt) {
	return xform.transform (srcPt, dstPt);
	}

	/**
	* Returns the affine transform used by this transform operation.
	*
	* @return The {@code AffineTransform} associated with this op.
	*/
	public final AffineTransform getTransform() {
	return (AffineTransform) xform.clone();
	}

	/**
	* Returns the rendering hints used by this transform operation.
	*
	* @return The {@code RenderingHints} object associated with this op.
	*/
	public final RenderingHints getRenderingHints() {
	if (hints == null) {
	Object val;
	switch(interpolationType) {
	case TYPE_NEAREST_NEIGHBOR:
	val = RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR;
	break;
	case TYPE_BILINEAR:
	val = RenderingHints.VALUE_INTERPOLATION_BILINEAR;
	break;
	case TYPE_BICUBIC:
	val = RenderingHints.VALUE_INTERPOLATION_BICUBIC;
	break;
	default:
	// Should never get here
	throw new InternalError("Unknown interpolation type "+
	interpolationType);

	}
	hints = new RenderingHints(RenderingHints.KEY_INTERPOLATION, val);
	}

	return hints;
	}

	// We need to be able to invert the transform if we want to
	// transform the image. If the determinant of the matrix is 0,
	// then we can't invert the transform.
	void validateTransform(AffineTransform xform) {
	if (Math.abs(xform.getDeterminant()) <= Double.MIN_VALUE) {
	throw new ImagingOpException("Unable to invert transform "+xform);
	}
	}
	}