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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

/* $Id: GraphicsUtil.java 1732018 2016-02-24 04:51:06Z gadams $ */

package org.apache.xmlgraphics.image;

import java.awt.Point;
import java.awt.Rectangle;
import java.awt.color.ColorSpace;
import java.awt.geom.AffineTransform;
import java.awt.image.BufferedImage;
import java.awt.image.ColorModel;
import java.awt.image.ComponentSampleModel;
import java.awt.image.DataBuffer;
import java.awt.image.DataBufferByte;
import java.awt.image.DataBufferInt;
import java.awt.image.DataBufferShort;
import java.awt.image.DataBufferUShort;
import java.awt.image.DirectColorModel;
import java.awt.image.Raster;
import java.awt.image.RenderedImage;
import java.awt.image.SampleModel;
import java.awt.image.SinglePixelPackedSampleModel;
import java.awt.image.WritableRaster;

import org.apache.xmlgraphics.image.rendered.Any2LsRGBRed;
import org.apache.xmlgraphics.image.rendered.Any2sRGBRed;
import org.apache.xmlgraphics.image.rendered.BufferedImageCachableRed;
import org.apache.xmlgraphics.image.rendered.CachableRed;
import org.apache.xmlgraphics.image.rendered.RenderedImageCachableRed;

// CSOFF: AvoidNestedBlocks
// CSOFF: ConstantName
// CSOFF: MethodName
// CSOFF: MultipleVariableDeclarations
// CSOFF: NeedBraces
// CSOFF: OneStatementPerLine
// CSOFF: OperatorWrap
// CSOFF: StaticVariableName
// CSOFF: WhitespaceAfter
// CSOFF: WhitespaceAround

/**
 * Set of utility methods for Graphics.
 * These generally bypass broken methods in Java2D or provide tweaked
 * implementations.
 *
 * @version $Id: GraphicsUtil.java 1732018 2016-02-24 04:51:06Z gadams $
 *
 * Originally authored by Thomas DeWeese.
 */
public final class GraphicsUtil {

    private GraphicsUtil() {
    }

    public static final AffineTransform IDENTITY = new AffineTransform();

    /**
     * Standard prebuilt Linear_sRGB color model with no alpha */
    public static final ColorModel Linear_sRGB =
        new DirectColorModel(ColorSpace.getInstance(
                             ColorSpace.CS_LINEAR_RGB), 24,
                             0x00FF0000, 0x0000FF00,
                             0x000000FF, 0x0, false,
                             DataBuffer.TYPE_INT);
    /**
     * Standard prebuilt Linear_sRGB color model with premultiplied alpha.
     */
    public static final ColorModel Linear_sRGB_Pre =
        new DirectColorModel(ColorSpace.getInstance(
                             ColorSpace.CS_LINEAR_RGB), 32,
                             0x00FF0000, 0x0000FF00,
                             0x000000FF, 0xFF000000, true,
                             DataBuffer.TYPE_INT);
    /**
     * Standard prebuilt Linear_sRGB color model with unpremultiplied alpha.
     */
    public static final ColorModel Linear_sRGB_Unpre =
        new DirectColorModel(ColorSpace.getInstance(
                             ColorSpace.CS_LINEAR_RGB), 32,
                             0x00FF0000, 0x0000FF00,
                             0x000000FF, 0xFF000000, false,
                             DataBuffer.TYPE_INT);

    /**
     * Standard prebuilt sRGB color model with no alpha.
     */
    public static final ColorModel sRGB =
        new DirectColorModel(ColorSpace.getInstance(
                             ColorSpace.CS_sRGB), 24,
                             0x00FF0000, 0x0000FF00,
                             0x000000FF, 0x0, false,
                             DataBuffer.TYPE_INT);
    /**
     * Standard prebuilt sRGB color model with premultiplied alpha.
     */
    public static final ColorModel sRGB_Pre =
        new DirectColorModel(ColorSpace.getInstance(
                             ColorSpace.CS_sRGB), 32,
                             0x00FF0000, 0x0000FF00,
                             0x000000FF, 0xFF000000, true,
                             DataBuffer.TYPE_INT);
    /**
     * Standard prebuilt sRGB color model with unpremultiplied alpha.
     */
    public static final ColorModel sRGB_Unpre =
        new DirectColorModel(ColorSpace.getInstance(
                             ColorSpace.CS_sRGB), 32,
                             0x00FF0000, 0x0000FF00,
                             0x000000FF, 0xFF000000, false,
                             DataBuffer.TYPE_INT);

    /**
     * Method that returns either Linear_sRGB_Pre or Linear_sRGB_UnPre
     * based on premult flag.
     * @param premult True if the ColorModel should have premultiplied alpha.
     * @return        a ColorMdoel with Linear sRGB colorSpace and
     *                the alpha channel set in accordance with
     *                premult
     */
    public static ColorModel makeLinear_sRGBCM(boolean premult) {
         return premult ? Linear_sRGB_Pre : Linear_sRGB_Unpre;
    }

    /**
     * Constructs a BufferedImage with a linear sRGB colorModel, and alpha.
     * @param width   The desired width of the BufferedImage
     * @param height  The desired height of the BufferedImage
     * @param premult The desired state of alpha premultiplied
     * @return        The requested BufferedImage.
     */
    public static BufferedImage makeLinearBufferedImage(int width,
                                                        int height,
                                                        boolean premult) {
        ColorModel cm = makeLinear_sRGBCM(premult);
        WritableRaster wr = cm.createCompatibleWritableRaster(width, height);
        return new BufferedImage(cm, wr, premult, null);
    }

    /**
     * This method will return a CacheableRed that has it's data in
     * the linear sRGB colorspace. If src is already in
     * linear sRGB then this method does nothing and returns src.
     * Otherwise it creates a transform that will convert
     * src's output to linear sRGB and returns that CacheableRed.
     *
     * @param src The image to convert to linear sRGB.
     * @return    An equivilant image to src who's data is in
     *            linear sRGB.
     */
    public static CachableRed convertToLsRGB(CachableRed src) {
        ColorModel cm = src.getColorModel();
        ColorSpace cs = cm.getColorSpace();
        if (cs == ColorSpace.getInstance(ColorSpace.CS_LINEAR_RGB)) {
            return src;
        }

        return new Any2LsRGBRed(src);
    }

    /**
     * This method will return a CacheableRed that has it's data in
     * the sRGB colorspace. If src is already in
     * sRGB then this method does nothing and returns src.
     * Otherwise it creates a transform that will convert
     * src's output to sRGB and returns that CacheableRed.
     *
     * @param src The image to convert to sRGB.
     * @return    An equivilant image to src who's data is in sRGB.
     */
    public static CachableRed convertTosRGB(CachableRed src) {
        ColorModel cm = src.getColorModel();
        ColorSpace cs = cm.getColorSpace();
        if (cs == ColorSpace.getInstance(ColorSpace.CS_sRGB)) {
            return src;
        }

        return new Any2sRGBRed(src);
    }

    /**
     * Convertes any RenderedImage to a CacheableRed.  

* If ri is already a CacheableRed it casts it down and * returns it.

* * In cases where ri is not already a CacheableRed it * wraps ri with a helper class. The wrapped * CacheableRed "Pretends" that it has no sources since it has no * way of inteligently handling the dependency/dirty region calls * if it exposed the source. * @param ri The RenderedImage to convert. * @return a CacheableRed that contains the same data as ri. */ public static CachableRed wrap(RenderedImage ri) { if (ri instanceof CachableRed) { return (CachableRed) ri; } if (ri instanceof BufferedImage) { return new BufferedImageCachableRed((BufferedImage)ri); } return new RenderedImageCachableRed(ri); } /** * An internal optimized version of copyData designed to work on * Integer packed data with a SinglePixelPackedSampleModel. Only * the region of overlap between src and dst is copied. * * Calls to this should be preflighted with is_INT_PACK_Data * on both src and dest (requireAlpha can be false). * * @param src The source of the data * @param dst The destination for the data. */ public static void copyData_INT_PACK(Raster src, WritableRaster dst) { // System.out.println("Fast copyData"); int x0 = dst.getMinX(); if (x0 < src.getMinX()) { x0 = src.getMinX(); } int y0 = dst.getMinY(); if (y0 < src.getMinY()) { y0 = src.getMinY(); } int x1 = dst.getMinX() + dst.getWidth() - 1; if (x1 > src.getMinX() + src.getWidth() - 1) { x1 = src.getMinX() + src.getWidth() - 1; } int y1 = dst.getMinY() + dst.getHeight() - 1; if (y1 > src.getMinY() + src.getHeight() - 1) { y1 = src.getMinY() + src.getHeight() - 1; } int width = x1 - x0 + 1; int height = y1 - y0 + 1; SinglePixelPackedSampleModel srcSPPSM; srcSPPSM = (SinglePixelPackedSampleModel)src.getSampleModel(); final int srcScanStride = srcSPPSM.getScanlineStride(); DataBufferInt srcDB = (DataBufferInt)src.getDataBuffer(); final int [] srcPixels = srcDB.getBankData()[0]; final int srcBase = (srcDB.getOffset() + srcSPPSM.getOffset(x0 - src.getSampleModelTranslateX(), y0 - src.getSampleModelTranslateY())); SinglePixelPackedSampleModel dstSPPSM; dstSPPSM = (SinglePixelPackedSampleModel)dst.getSampleModel(); final int dstScanStride = dstSPPSM.getScanlineStride(); DataBufferInt dstDB = (DataBufferInt)dst.getDataBuffer(); final int [] dstPixels = dstDB.getBankData()[0]; final int dstBase = (dstDB.getOffset() + dstSPPSM.getOffset(x0 - dst.getSampleModelTranslateX(), y0 - dst.getSampleModelTranslateY())); if ((srcScanStride == dstScanStride) && (srcScanStride == width)) { // System.out.println("VERY Fast copyData"); System.arraycopy(srcPixels, srcBase, dstPixels, dstBase, width * height); } else if (width > 128) { int srcSP = srcBase; int dstSP = dstBase; for (int y = 0; y < height; y++) { System.arraycopy(srcPixels, srcSP, dstPixels, dstSP, width); srcSP += srcScanStride; dstSP += dstScanStride; } } else { for (int y = 0; y < height; y++) { int srcSP = srcBase + y * srcScanStride; int dstSP = dstBase + y * dstScanStride; for (int x = 0; x < width; x++) { dstPixels[dstSP++] = srcPixels[srcSP++]; } } } } public static void copyData_FALLBACK(Raster src, WritableRaster dst) { // System.out.println("Fallback copyData"); int x0 = dst.getMinX(); if (x0 < src.getMinX()) { x0 = src.getMinX(); } int y0 = dst.getMinY(); if (y0 < src.getMinY()) { y0 = src.getMinY(); } int x1 = dst.getMinX() + dst.getWidth() - 1; if (x1 > src.getMinX() + src.getWidth() - 1) { x1 = src.getMinX() + src.getWidth() - 1; } int y1 = dst.getMinY() + dst.getHeight() - 1; if (y1 > src.getMinY() + src.getHeight() - 1) { y1 = src.getMinY() + src.getHeight() - 1; } int width = x1 - x0 + 1; int [] data = null; for (int y = y0; y <= y1; y++) { data = src.getPixels(x0, y, width, 1, data); dst.setPixels(x0, y, width, 1, data); } } /** * Copies data from one raster to another. Only the region of * overlap between src and dst is copied. Src and * Dst must have compatible SampleModels. * * @param src The source of the data * @param dst The destination for the data. */ public static void copyData(Raster src, WritableRaster dst) { if (is_INT_PACK_Data(src.getSampleModel(), false) && is_INT_PACK_Data(dst.getSampleModel(), false)) { copyData_INT_PACK(src, dst); return; } copyData_FALLBACK(src, dst); } /** * Creates a new raster that has a copy of the data in * ras. This is highly optimized for speed. There is * no provision for changing any aspect of the SampleModel. * * This method should be used when you need to change the contents * of a Raster that you do not "own" (ie the result of a * getData call). * @param ras The Raster to copy. * @return A writable copy of ras */ public static WritableRaster copyRaster(Raster ras) { return copyRaster(ras, ras.getMinX(), ras.getMinY()); } /** * Creates a new raster that has a copy of the data in * ras. This is highly optimized for speed. There is * no provision for changing any aspect of the SampleModel. * However you can specify a new location for the returned raster. * * This method should be used when you need to change the contents * of a Raster that you do not "own" (ie the result of a * getData call). * * @param ras The Raster to copy. * * @param minX The x location for the upper left corner of the * returned WritableRaster. * * @param minY The y location for the upper left corner of the * returned WritableRaster. * * @return A writable copy of ras */ public static WritableRaster copyRaster(Raster ras, int minX, int minY) { WritableRaster ret = Raster.createWritableRaster( ras.getSampleModel(), new Point(0, 0)); ret = ret.createWritableChild( ras.getMinX() - ras.getSampleModelTranslateX(), ras.getMinY() - ras.getSampleModelTranslateY(), ras.getWidth(), ras.getHeight(), minX, minY, null); // Use System.arraycopy to copy the data between the two... DataBuffer srcDB = ras.getDataBuffer(); DataBuffer retDB = ret.getDataBuffer(); if (srcDB.getDataType() != retDB.getDataType()) { throw new IllegalArgumentException( "New DataBuffer doesn't match original"); } int len = srcDB.getSize(); int banks = srcDB.getNumBanks(); int [] offsets = srcDB.getOffsets(); for (int b = 0; b < banks; b++) { switch (srcDB.getDataType()) { case DataBuffer.TYPE_BYTE: { DataBufferByte srcDBT = (DataBufferByte)srcDB; DataBufferByte retDBT = (DataBufferByte)retDB; System.arraycopy(srcDBT.getData(b), offsets[b], retDBT.getData(b), offsets[b], len); break; } case DataBuffer.TYPE_INT: { DataBufferInt srcDBT = (DataBufferInt)srcDB; DataBufferInt retDBT = (DataBufferInt)retDB; System.arraycopy(srcDBT.getData(b), offsets[b], retDBT.getData(b), offsets[b], len); break; } case DataBuffer.TYPE_SHORT: { DataBufferShort srcDBT = (DataBufferShort)srcDB; DataBufferShort retDBT = (DataBufferShort)retDB; System.arraycopy(srcDBT.getData(b), offsets[b], retDBT.getData(b), offsets[b], len); break; } case DataBuffer.TYPE_USHORT: { DataBufferUShort srcDBT = (DataBufferUShort)srcDB; DataBufferUShort retDBT = (DataBufferUShort)retDB; System.arraycopy(srcDBT.getData(b), offsets[b], retDBT.getData(b), offsets[b], len); break; } default: throw new UnsupportedOperationException("unsupported data type: " + srcDB.getDataType()); } } return ret; } /** * Coerces ras to be writable. The returned Raster continues to * reference the DataBuffer from ras, so modifications to the returned * WritableRaster will be seen in ras.

* * This method should only be used if you need a WritableRaster due to * an interface (such as to construct a BufferedImage), but have no * intention of modifying the contents of the returned Raster. If * you have any doubt about other users of the data in ras, * use copyRaster (above). * @param ras The raster to make writable. * @return A Writable version of ras (shares DataBuffer with * ras). */ public static WritableRaster makeRasterWritable(Raster ras) { return makeRasterWritable(ras, ras.getMinX(), ras.getMinY()); } /** * Coerces ras to be writable. The returned Raster continues to * reference the DataBuffer from ras, so modifications to the returned * WritableRaster will be seen in ras.

* * You can specify a new location for the returned WritableRaster, this * is especially useful for constructing BufferedImages which require * the Raster to be at (0,0). * * This method should only be used if you need a WritableRaster due to * an interface (such as to construct a BufferedImage), but have no * intention of modifying the contents of the returned Raster. If * you have any doubt about other users of the data in ras, * use copyRaster (above). * * @param ras The raster to make writable. * * @param minX The x location for the upper left corner of the * returned WritableRaster. * * @param minY The y location for the upper left corner of the * returned WritableRaster. * * @return A Writable version of ras with it's upper left * hand coordinate set to minX, minY (shares it's DataBuffer * with ras). */ public static WritableRaster makeRasterWritable(Raster ras, int minX, int minY) { WritableRaster ret = Raster.createWritableRaster( ras.getSampleModel(), ras.getDataBuffer(), new Point(0, 0)); ret = ret.createWritableChild( ras.getMinX() - ras.getSampleModelTranslateX(), ras.getMinY() - ras.getSampleModelTranslateY(), ras.getWidth(), ras.getHeight(), minX, minY, null); return ret; } /** * Create a new ColorModel with it's alpha premultiplied state matching * newAlphaPreMult. * @param cm The ColorModel to change the alpha premult state of. * @param newAlphaPreMult The new state of alpha premult. * @return A new colorModel that has isAlphaPremultiplied() * equal to newAlphaPreMult. */ public static ColorModel coerceColorModel(ColorModel cm, boolean newAlphaPreMult) { if (cm.isAlphaPremultiplied() == newAlphaPreMult) { return cm; } // Easiest way to build proper colormodel for new Alpha state... // Eventually this should switch on known ColorModel types and // only fall back on this hack when the CM type is unknown. WritableRaster wr = cm.createCompatibleWritableRaster(1, 1); return cm.coerceData(wr, newAlphaPreMult); } /** * Coerces data within a bufferedImage to match newAlphaPreMult, * Note that this can not change the colormodel of bi so you * * @param wr The raster to change the state of. * @param cm The colormodel currently associated with data in wr. * @param newAlphaPreMult The desired state of alpha Premult for raster. * @return A new colormodel that matches newAlphaPreMult. */ public static ColorModel coerceData(WritableRaster wr, ColorModel cm, boolean newAlphaPreMult) { // System.out.println("CoerceData: " + cm.isAlphaPremultiplied() + // " Out: " + newAlphaPreMult); if (!cm.hasAlpha()) { // Nothing to do no alpha channel return cm; } if (cm.isAlphaPremultiplied() == newAlphaPreMult) { // nothing to do alpha state matches... return cm; } // System.out.println("CoerceData: " + wr.getSampleModel()); if (newAlphaPreMult) { multiplyAlpha(wr); } else { divideAlpha(wr); } return coerceColorModel(cm, newAlphaPreMult); } public static void multiplyAlpha(WritableRaster wr) { if (is_BYTE_COMP_Data(wr.getSampleModel())) { mult_BYTE_COMP_Data(wr); } else if (is_INT_PACK_Data(wr.getSampleModel(), true)) { mult_INT_PACK_Data(wr); } else { int [] pixel = null; int bands = wr.getNumBands(); float norm = 1f / 255f; int x0; int x1; int y0; int y1; int a; int b; float alpha; x0 = wr.getMinX(); x1 = x0 + wr.getWidth(); y0 = wr.getMinY(); y1 = y0 + wr.getHeight(); for (int y = y0; y < y1; y++) { for (int x = x0; x < x1; x++) { pixel = wr.getPixel(x, y, pixel); a = pixel[bands - 1]; if ((a >= 0) && (a < 255)) { alpha = a * norm; for (b = 0; b < bands - 1; b++) { pixel[b] = (int)(pixel[b] * alpha + 0.5f); } wr.setPixel(x, y, pixel); } } } } } public static void divideAlpha(WritableRaster wr) { if (is_BYTE_COMP_Data(wr.getSampleModel())) { divide_BYTE_COMP_Data(wr); } else if (is_INT_PACK_Data(wr.getSampleModel(), true)) { divide_INT_PACK_Data(wr); } else { int x0; int x1; int y0; int y1; int a; int b; float ialpha; int bands = wr.getNumBands(); int [] pixel = null; x0 = wr.getMinX(); x1 = x0 + wr.getWidth(); y0 = wr.getMinY(); y1 = y0 + wr.getHeight(); for (int y = y0; y < y1; y++) { for (int x = x0; x < x1; x++) { pixel = wr.getPixel(x, y, pixel); a = pixel[bands - 1]; if ((a > 0) && (a < 255)) { ialpha = 255 / (float)a; for (b = 0; b < bands - 1; b++) { pixel[b] = (int)(pixel[b] * ialpha + 0.5f); } wr.setPixel(x, y, pixel); } } } } } /** * Copies data from one bufferedImage to another paying attention * to the state of AlphaPreMultiplied. * * @param src The source * @param dst The destination */ public static void copyData(BufferedImage src, BufferedImage dst) { Rectangle srcRect = new Rectangle(0, 0, src.getWidth(), src.getHeight()); copyData(src, srcRect, dst, new Point(0, 0)); } /** * Copies data from one bufferedImage to another paying attention * to the state of AlphaPreMultiplied. * * @param src The source * @param srcRect The Rectangle of source data to be copied * @param dst The destination * @param destP The Place for the upper left corner of srcRect in dst. */ public static void copyData(BufferedImage src, Rectangle srcRect, BufferedImage dst, Point destP) { /* if (srcCS != dstCS) throw new IllegalArgumentException ("Images must be in the same ColorSpace in order "+ "to copy Data between them"); */ boolean srcAlpha = src.getColorModel().hasAlpha(); boolean dstAlpha = dst.getColorModel().hasAlpha(); // System.out.println("Src has: " + srcAlpha + // " is: " + src.isAlphaPremultiplied()); // // System.out.println("Dst has: " + dstAlpha + // " is: " + dst.isAlphaPremultiplied()); if (srcAlpha == dstAlpha) { if (!srcAlpha || src.isAlphaPremultiplied() == dst.isAlphaPremultiplied()) { // They match one another so just copy everything... copyData(src.getRaster(), dst.getRaster()); return; } } // System.out.println("Using Slow CopyData"); int [] pixel = null; Raster srcR = src.getRaster(); WritableRaster dstR = dst.getRaster(); int bands = dstR.getNumBands(); int dx = destP.x - srcRect.x; int dy = destP.y - srcRect.y; int w = srcRect.width; int x0 = srcRect.x; int y0 = srcRect.y; int y1 = y0 + srcRect.height - 1; if (!srcAlpha) { // Src has no alpha dest does so set alpha to 1.0 everywhere. // System.out.println("Add Alpha"); int [] oPix = new int[bands * w]; int out = (w * bands) - 1; // The 2 skips alpha channel while (out >= 0) { // Fill alpha channel with 255's oPix[out] = 255; out -= bands; } int b; int in; for (int y = y0; y <= y1; y++) { pixel = srcR.getPixels(x0, y, w, 1, pixel); in = w * (bands - 1) - 1; out = (w * bands) - 2; // The 2 skips alpha channel on last pix switch (bands) { case 4: while (in >= 0) { oPix[out--] = pixel[in--]; oPix[out--] = pixel[in--]; oPix[out--] = pixel[in--]; out--; } break; default: while (in >= 0) { for (b = 0; b < bands - 1; b++) { oPix[out--] = pixel[in--]; } out--; } } dstR.setPixels(x0 + dx, y + dy, w, 1, oPix); } } else if (dstAlpha && dst.isAlphaPremultiplied()) { // Src and dest have Alpha but we need to multiply it for dst. // System.out.println("Mult Case"); int a; int b; int alpha; int in; int fpNorm = (1 << 24) / 255; int pt5 = 1 << 23; for (int y = y0; y <= y1; y++) { pixel = srcR.getPixels(x0, y, w, 1, pixel); in = bands * w - 1; switch (bands) { case 4: while (in >= 0) { a = pixel[in]; if (a == 255) { in -= 4; } else { in--; alpha = fpNorm * a; pixel[in] = (pixel[in] * alpha + pt5) >>> 24; in--; pixel[in] = (pixel[in] * alpha + pt5) >>> 24; in--; pixel[in] = (pixel[in] * alpha + pt5) >>> 24; in--; } } break; default: while (in >= 0) { a = pixel[in]; if (a == 255) { in -= bands; } else { in--; alpha = fpNorm * a; for (b = 0; b < bands - 1; b++) { pixel[in] = (pixel[in] * alpha + pt5) >>> 24; in--; } } } } dstR.setPixels(x0 + dx, y + dy, w, 1, pixel); } } else if (dstAlpha && !dst.isAlphaPremultiplied()) { // Src and dest have Alpha but we need to divide it out for dst. // System.out.println("Div Case"); int a; int b; int ialpha; int in; int fpNorm = 0x00FF0000; int pt5 = 1 << 15; for (int y = y0; y <= y1; y++) { pixel = srcR.getPixels(x0, y, w, 1, pixel); in = (bands * w) - 1; switch(bands) { case 4: while (in >= 0) { a = pixel[in]; if ((a <= 0) || (a >= 255)) { in -= 4; } else { in--; ialpha = fpNorm / a; pixel[in] = (pixel[in] * ialpha + pt5) >>> 16; in--; pixel[in] = (pixel[in] * ialpha + pt5) >>> 16; in--; pixel[in] = (pixel[in] * ialpha + pt5) >>> 16; in--; } } break; default: while (in >= 0) { a = pixel[in]; if ((a <= 0) || (a >= 255)) { in -= bands; } else { in--; ialpha = fpNorm / a; for (b = 0; b < bands - 1; b++) { pixel[in] = (pixel[in] * ialpha + pt5) >>> 16; in--; } } } } dstR.setPixels(x0 + dx, y + dy, w, 1, pixel); } } else if (src.isAlphaPremultiplied()) { int [] oPix = new int[bands * w]; // Src has alpha dest does not so unpremult and store... // System.out.println("Remove Alpha, Div Case"); int a; int b; int ialpha; int in; int out; int fpNorm = 0x00FF0000; int pt5 = 1 << 15; for (int y = y0; y <= y1; y++) { pixel = srcR.getPixels(x0, y, w, 1, pixel); in = (bands + 1) * w - 1; out = (bands * w) - 1; while (in >= 0) { a = pixel[in]; in--; if (a > 0) { if (a < 255) { ialpha = fpNorm / a; for (b = 0; b < bands; b++) { oPix[out--] = (pixel[in--] * ialpha + pt5) >>> 16; } } else { for (b = 0; b < bands; b++) { oPix[out--] = pixel[in--]; } } } else { in -= bands; for (b = 0; b < bands; b++) { oPix[out--] = 255; } } } dstR.setPixels(x0 + dx, y + dy, w, 1, oPix); } } else { // Src has unpremult alpha, dest does not have alpha, // just copy the color channels over. Rectangle dstRect = new Rectangle(destP.x, destP.y, srcRect.width, srcRect.height); for (int b = 0; b < bands; b++) { copyBand(srcR, srcRect, b, dstR, dstRect, b); } } } public static void copyBand(Raster src, int srcBand, WritableRaster dst, int dstBand) { Rectangle sR = src.getBounds(); Rectangle dR = dst.getBounds(); Rectangle cpR = sR.intersection(dR); copyBand(src, cpR, srcBand, dst, cpR, dstBand); } public static void copyBand(Raster src, Rectangle sR, int sBand, WritableRaster dst, Rectangle dR, int dBand) { int dy = dR.y - sR.y; int dx = dR.x - sR.x; sR = sR.intersection(src.getBounds()); dR = dR.intersection(dst.getBounds()); int width; int height; if (dR.width < sR.width) { width = dR.width; } else { width = sR.width; } if (dR.height < sR.height) { height = dR.height; } else { height = sR.height; } int x = sR.x + dx; int [] samples = null; for (int y = sR.y; y < sR.y + height; y++) { samples = src.getSamples(sR.x, y, width, 1, sBand, samples); dst.setSamples(x, y + dy, width, 1, dBand, samples); } } public static boolean is_INT_PACK_Data(SampleModel sm, boolean requireAlpha) { // Check ColorModel is of type DirectColorModel if (!(sm instanceof SinglePixelPackedSampleModel)) { return false; } // Check transfer type if (sm.getDataType() != DataBuffer.TYPE_INT) { return false; } SinglePixelPackedSampleModel sppsm; sppsm = (SinglePixelPackedSampleModel)sm; int [] masks = sppsm.getBitMasks(); if (masks.length == 3) { if (requireAlpha) { return false; } } else if (masks.length != 4) { return false; } if (masks[0] != 0x00ff0000) { return false; } if (masks[1] != 0x0000ff00) { return false; } if (masks[2] != 0x000000ff) { return false; } if ((masks.length == 4) && (masks[3] != 0xff000000)) { return false; } return true; } public static boolean is_BYTE_COMP_Data(SampleModel sm) { // Check ColorModel is of type DirectColorModel if (!(sm instanceof ComponentSampleModel)) { return false; } // Check transfer type if (sm.getDataType() != DataBuffer.TYPE_BYTE) { return false; } return true; } protected static void divide_INT_PACK_Data(WritableRaster wr) { // System.out.println("Divide Int"); SinglePixelPackedSampleModel sppsm; sppsm = (SinglePixelPackedSampleModel)wr.getSampleModel(); final int width = wr.getWidth(); final int scanStride = sppsm.getScanlineStride(); DataBufferInt db = (DataBufferInt)wr.getDataBuffer(); final int base = (db.getOffset() + sppsm.getOffset(wr.getMinX() - wr.getSampleModelTranslateX(), wr.getMinY() - wr.getSampleModelTranslateY())); // Access the pixel data array final int[] pixels = db.getBankData()[0]; for (int y = 0; y < wr.getHeight(); y++) { int sp = base + y * scanStride; final int end = sp + width; while (sp < end) { int pixel = pixels[sp]; int a = pixel >>> 24; if (a <= 0) { pixels[sp] = 0x00FFFFFF; } else if (a < 255) { int aFP = (0x00FF0000 / a); pixels[sp] = ((a << 24) | (((((pixel & 0xFF0000) >> 16) * aFP) & 0xFF0000)) | (((((pixel & 0x00FF00) >> 8) * aFP) & 0xFF0000) >> 8) | (((((pixel & 0x0000FF)) * aFP) & 0xFF0000) >> 16)); } sp++; } } } protected static void mult_INT_PACK_Data(WritableRaster wr) { // System.out.println("Multiply Int: " + wr); SinglePixelPackedSampleModel sppsm; sppsm = (SinglePixelPackedSampleModel)wr.getSampleModel(); final int width = wr.getWidth(); final int scanStride = sppsm.getScanlineStride(); DataBufferInt db = (DataBufferInt)wr.getDataBuffer(); final int base = (db.getOffset() + sppsm.getOffset(wr.getMinX() - wr.getSampleModelTranslateX(), wr.getMinY() - wr.getSampleModelTranslateY())); // Access the pixel data array final int[] pixels = db.getBankData()[0]; for (int y = 0; y < wr.getHeight(); y++) { int sp = base + y * scanStride; final int end = sp + width; while (sp < end) { int pixel = pixels[sp]; int a = pixel >>> 24; if ((a >= 0) && (a < 255)) { // this does NOT include a == 255 (0xff) ! pixels[sp] = ((a << 24) | ((((pixel & 0xFF0000) * a) >> 8) & 0xFF0000) | ((((pixel & 0x00FF00) * a) >> 8) & 0x00FF00) | ((((pixel & 0x0000FF) * a) >> 8) & 0x0000FF)); } sp++; } } } protected static void divide_BYTE_COMP_Data(WritableRaster wr) { // System.out.println("Multiply Int: " + wr); ComponentSampleModel csm; csm = (ComponentSampleModel)wr.getSampleModel(); final int width = wr.getWidth(); final int scanStride = csm.getScanlineStride(); final int pixStride = csm.getPixelStride(); final int [] bandOff = csm.getBandOffsets(); DataBufferByte db = (DataBufferByte)wr.getDataBuffer(); final int base = (db.getOffset() + csm.getOffset(wr.getMinX() - wr.getSampleModelTranslateX(), wr.getMinY() - wr.getSampleModelTranslateY())); int aOff = bandOff[bandOff.length - 1]; int bands = bandOff.length - 1; // Access the pixel data array final byte[] pixels = db.getBankData()[0]; for (int y = 0; y < wr.getHeight(); y++) { int sp = base + y * scanStride; final int end = sp + width * pixStride; while (sp < end) { int a = pixels[sp + aOff] & 0xFF; if (a == 0) { for (int b = 0; b < bands; b++) { pixels[sp + bandOff[b]] = (byte)0xFF; } } else if (a < 255) { // this does NOT include a == 255 (0xff) ! int aFP = (0x00FF0000 / a); for (int b = 0; b < bands; b++) { int i = sp + bandOff[b]; pixels[i] = (byte)(((pixels[i] & 0xFF) * aFP) >>> 16); } } sp += pixStride; } } } protected static void mult_BYTE_COMP_Data(WritableRaster wr) { // System.out.println("Multiply Int: " + wr); ComponentSampleModel csm; csm = (ComponentSampleModel)wr.getSampleModel(); final int width = wr.getWidth(); final int scanStride = csm.getScanlineStride(); final int pixStride = csm.getPixelStride(); final int [] bandOff = csm.getBandOffsets(); DataBufferByte db = (DataBufferByte)wr.getDataBuffer(); final int base = (db.getOffset() + csm.getOffset(wr.getMinX() - wr.getSampleModelTranslateX(), wr.getMinY() - wr.getSampleModelTranslateY())); int aOff = bandOff[bandOff.length - 1]; int bands = bandOff.length - 1; // Access the pixel data array final byte[] pixels = db.getBankData()[0]; for (int y = 0; y < wr.getHeight(); y++) { int sp = base + y * scanStride; final int end = sp + width * pixStride; while (sp < end) { int a = pixels[sp + aOff] & 0xFF; if (a != 0xFF) { for (int b = 0; b < bands; b++) { int i = sp + bandOff[b]; pixels[i] = (byte)(((pixels[i] & 0xFF) * a) >> 8); } } sp += pixStride; } } } /* This is skanky debugging code that might be useful in the future: if (count == 33) { String label = "sub [" + x + ", " + y + "]: "; org.ImageDisplay.showImage (label, subBI); org.ImageDisplay.printImage (label, subBI, new Rectangle(75-iR.x, 90-iR.y, 32, 32)); } // if ((count++ % 50) == 10) // org.ImageDisplay.showImage("foo: ", subBI); Graphics2D realG2D = g2d; while (realG2D instanceof sun.java2d.ProxyGraphics2D) { realG2D = ((sun.java2d.ProxyGraphics2D)realG2D).getDelegate(); } if (realG2D instanceof sun.awt.image.BufferedImageGraphics2D) { count++; if (count == 34) { RenderedImage ri; ri = ((sun.awt.image.BufferedImageGraphics2D)realG2D).bufImg; // g2d.setComposite(SVGComposite.OVER); // org.ImageDisplay.showImage("Bar: " + count, cr); org.ImageDisplay.printImage("Bar: " + count, cr, new Rectangle(75, 90, 32, 32)); org.ImageDisplay.showImage ("Foo: " + count, ri); org.ImageDisplay.printImage("Foo: " + count, ri, new Rectangle(75, 90, 32, 32)); System.out.println("BI: " + ri); System.out.println("BISM: " + ri.getSampleModel()); System.out.println("BICM: " + ri.getColorModel()); System.out.println("BICM class: " + ri.getColorModel().getClass()); System.out.println("BICS: " + ri.getColorModel().getColorSpace()); System.out.println ("sRGB CS: " + ColorSpace.getInstance(ColorSpace.CS_sRGB)); System.out.println("G2D info"); System.out.println("\tComposite: " + g2d.getComposite()); System.out.println("\tTransform" + g2d.getTransform()); java.awt.RenderingHints rh = g2d.getRenderingHints(); java.util.Set keys = rh.keySet(); java.util.Iterator iter = keys.iterator(); while (iter.hasNext()) { Object o = iter.next(); System.out.println("\t" + o.toString() + " -> " + rh.get(o).toString()); } ri = cr; System.out.println("RI: " + ri); System.out.println("RISM: " + ri.getSampleModel()); System.out.println("RICM: " + ri.getColorModel()); System.out.println("RICM class: " + ri.getColorModel().getClass()); System.out.println("RICS: " + ri.getColorModel().getColorSpace()); } } */ /** * Extracts an alpha raster from a RenderedImage. The method tries to avoid copying data * unnecessarily by checking if the RenderedImage is a BufferedImage which offers suitable * direct methods. * @param image the image * @return the alpha raster */ public static Raster getAlphaRaster(RenderedImage image) { ColorModel cm = image.getColorModel(); if (!cm.hasAlpha() || cm.getTransparency() != ColorModel.TRANSLUCENT) { throw new IllegalStateException("Image doesn't have an alpha channel"); } Raster alpha; if (image instanceof BufferedImage) { //Optimization possible with BufferedImage (No copying) alpha = ((BufferedImage)image).getAlphaRaster(); } else { WritableRaster wraster = GraphicsUtil.makeRasterWritable(image.getData()); alpha = image.getColorModel().getAlphaRaster(wraster); } return alpha; } }





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