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JRE 8 rt.jar - java.* Package Source Code
JRE 8 rt.jar is the JAR file for JRE 8 RT (Runtime) libraries. JRE (Java Runtime) 8 is the runtime environment included in JDK 8. JRE 8 rt.jar libraries are divided into 6 packages:
com.* - Internal Oracle and Sun Microsystems libraries java.* - Standard Java API libraries. javax.* - Extended Java API libraries. jdk.* - JDK supporting libraries. org.* - Third party libraries. sun.* - Old libraries developed by Sun Microsystems.
JAR File Information:
Directory of C:\fyicenter\jdk-1.8.0_191\jre\lib 63,596,151 rt.jar
Here is the list of Java classes of the java.* package in JRE 1.8.0_191 rt.jar. Java source codes are also provided.
✍: FYIcenter
⏎ java/awt/image/RescaleOp.java
/* * Copyright (c) 1997, 2000, Oracle and/or its affiliates. All rights reserved. * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms. * * * * * * * * * * * * * * * * * * * * */ package java.awt.image; import java.awt.color.ColorSpace; import java.awt.geom.Rectangle2D; import java.awt.Rectangle; import java.awt.geom.Point2D; import java.awt.RenderingHints; import sun.awt.image.ImagingLib; /** * This class performs a pixel-by-pixel rescaling of the data in the * source image by multiplying the sample values for each pixel by a scale * factor and then adding an offset. The scaled sample values are clipped * to the minimum/maximum representable in the destination image. * <p> * The pseudo code for the rescaling operation is as follows: * <pre> *for each pixel from Source object { * for each band/component of the pixel { * dstElement = (srcElement*scaleFactor) + offset * } *} * </pre> * <p> * For Rasters, rescaling operates on bands. The number of * sets of scaling constants may be one, in which case the same constants * are applied to all bands, or it must equal the number of Source * Raster bands. * <p> * For BufferedImages, rescaling operates on color and alpha components. * The number of sets of scaling constants may be one, in which case the * same constants are applied to all color (but not alpha) components. * Otherwise, the number of sets of scaling constants may * equal the number of Source color components, in which case no * rescaling of the alpha component (if present) is performed. * If neither of these cases apply, the number of sets of scaling constants * must equal the number of Source color components plus alpha components, * in which case all color and alpha components are rescaled. * <p> * BufferedImage sources with premultiplied alpha data are treated in the same * manner as non-premultiplied images for purposes of rescaling. That is, * the rescaling is done per band on the raw data of the BufferedImage source * without regard to whether the data is premultiplied. If a color conversion * is required to the destination ColorModel, the premultiplied state of * both source and destination will be taken into account for this step. * <p> * Images with an IndexColorModel cannot be rescaled. * <p> * If a RenderingHints object is specified in the constructor, the * color rendering hint and the dithering hint may be used when color * conversion is required. * <p> * Note that in-place operation is allowed (i.e. the source and destination can * be the same object). * @see java.awt.RenderingHints#KEY_COLOR_RENDERING * @see java.awt.RenderingHints#KEY_DITHERING */ public class RescaleOp implements BufferedImageOp, RasterOp { float[] scaleFactors; float[] offsets; int length = 0; RenderingHints hints; private int srcNbits; private int dstNbits; /** * Constructs a new RescaleOp with the desired scale factors * and offsets. The length of the scaleFactor and offset arrays * must meet the restrictions stated in the class comments above. * The RenderingHints argument may be null. * @param scaleFactors the specified scale factors * @param offsets the specified offsets * @param hints the specified <code>RenderingHints</code>, or * <code>null</code> */ public RescaleOp (float[] scaleFactors, float[] offsets, RenderingHints hints) { length = scaleFactors.length; if (length > offsets.length) length = offsets.length; this.scaleFactors = new float[length]; this.offsets = new float[length]; for (int i=0; i < length; i++) { this.scaleFactors[i] = scaleFactors[i]; this.offsets[i] = offsets[i]; } this.hints = hints; } /** * Constructs a new RescaleOp with the desired scale factor * and offset. The scaleFactor and offset will be applied to * all bands in a source Raster and to all color (but not alpha) * components in a BufferedImage. * The RenderingHints argument may be null. * @param scaleFactor the specified scale factor * @param offset the specified offset * @param hints the specified <code>RenderingHints</code>, or * <code>null</code> */ public RescaleOp (float scaleFactor, float offset, RenderingHints hints) { length = 1; this.scaleFactors = new float[1]; this.offsets = new float[1]; this.scaleFactors[0] = scaleFactor; this.offsets[0] = offset; this.hints = hints; } /** * Returns the scale factors in the given array. The array is also * returned for convenience. If scaleFactors is null, a new array * will be allocated. * @param scaleFactors the array to contain the scale factors of * this <code>RescaleOp</code> * @return the scale factors of this <code>RescaleOp</code>. */ final public float[] getScaleFactors (float scaleFactors[]) { if (scaleFactors == null) { return (float[]) this.scaleFactors.clone(); } System.arraycopy (this.scaleFactors, 0, scaleFactors, 0, Math.min(this.scaleFactors.length, scaleFactors.length)); return scaleFactors; } /** * Returns the offsets in the given array. The array is also returned * for convenience. If offsets is null, a new array * will be allocated. * @param offsets the array to contain the offsets of * this <code>RescaleOp</code> * @return the offsets of this <code>RescaleOp</code>. */ final public float[] getOffsets(float offsets[]) { if (offsets == null) { return (float[]) this.offsets.clone(); } System.arraycopy (this.offsets, 0, offsets, 0, Math.min(this.offsets.length, offsets.length)); return offsets; } /** * Returns the number of scaling factors and offsets used in this * RescaleOp. * @return the number of scaling factors and offsets of this * <code>RescaleOp</code>. */ final public int getNumFactors() { return length; } /** * Creates a ByteLookupTable to implement the rescale. * The table may have either a SHORT or BYTE input. * @param nElems Number of elements the table is to have. * This will generally be 256 for byte and * 65536 for short. */ private ByteLookupTable createByteLut(float scale[], float off[], int nBands, int nElems) { byte[][] lutData = new byte[scale.length][nElems]; for (int band=0; band<scale.length; band++) { float bandScale = scale[band]; float bandOff = off[band]; byte[] bandLutData = lutData[band]; for (int i=0; i<nElems; i++) { int val = (int)(i*bandScale + bandOff); if ((val & 0xffffff00) != 0) { if (val < 0) { val = 0; } else { val = 255; } } bandLutData[i] = (byte)val; } } return new ByteLookupTable(0, lutData); } /** * Creates a ShortLookupTable to implement the rescale. * The table may have either a SHORT or BYTE input. * @param nElems Number of elements the table is to have. * This will generally be 256 for byte and * 65536 for short. */ private ShortLookupTable createShortLut(float scale[], float off[], int nBands, int nElems) { short[][] lutData = new short[scale.length][nElems]; for (int band=0; band<scale.length; band++) { float bandScale = scale[band]; float bandOff = off[band]; short[] bandLutData = lutData[band]; for (int i=0; i<nElems; i++) { int val = (int)(i*bandScale + bandOff); if ((val & 0xffff0000) != 0) { if (val < 0) { val = 0; } else { val = 65535; } } bandLutData[i] = (short)val; } } return new ShortLookupTable(0, lutData); } /** * Determines if the rescale can be performed as a lookup. * The dst must be a byte or short type. * The src must be less than 16 bits. * All source band sizes must be the same and all dst band sizes * must be the same. */ private boolean canUseLookup(Raster src, Raster dst) { // // Check that the src datatype is either a BYTE or SHORT // int datatype = src.getDataBuffer().getDataType(); if(datatype != DataBuffer.TYPE_BYTE && datatype != DataBuffer.TYPE_USHORT) { return false; } // // Check dst sample sizes. All must be 8 or 16 bits. // SampleModel dstSM = dst.getSampleModel(); dstNbits = dstSM.getSampleSize(0); if (!(dstNbits == 8 || dstNbits == 16)) { return false; } for (int i=1; i<src.getNumBands(); i++) { int bandSize = dstSM.getSampleSize(i); if (bandSize != dstNbits) { return false; } } // // Check src sample sizes. All must be the same size // SampleModel srcSM = src.getSampleModel(); srcNbits = srcSM.getSampleSize(0); if (srcNbits > 16) { return false; } for (int i=1; i<src.getNumBands(); i++) { int bandSize = srcSM.getSampleSize(i); if (bandSize != srcNbits) { return false; } } return true; } /** * Rescales the source BufferedImage. * If the color model in the source image is not the same as that * in the destination image, the pixels will be converted * in the destination. If the destination image is null, * a BufferedImage will be created with the source ColorModel. * An IllegalArgumentException may be thrown if the number of * scaling factors/offsets in this object does not meet the * restrictions stated in the class comments above, or if the * source image has an IndexColorModel. * @param src the <code>BufferedImage</code> to be filtered * @param dst the destination for the filtering operation * or <code>null</code> * @return the filtered <code>BufferedImage</code>. * @throws IllegalArgumentException if the <code>ColorModel</code> * of <code>src</code> is an <code>IndexColorModel</code>, * or if the number of scaling factors and offsets in this * <code>RescaleOp</code> do not meet the requirements * stated in the class comments. */ public final BufferedImage filter (BufferedImage src, BufferedImage dst) { ColorModel srcCM = src.getColorModel(); ColorModel dstCM; int numBands = srcCM.getNumColorComponents(); if (srcCM instanceof IndexColorModel) { throw new IllegalArgumentException("Rescaling cannot be "+ "performed on an indexed image"); } if (length != 1 && length != numBands && length != srcCM.getNumComponents()) { throw new IllegalArgumentException("Number of scaling constants "+ "does not equal the number of"+ " of color or color/alpha "+ " components"); } boolean needToConvert = false; // Include alpha if (length > numBands && srcCM.hasAlpha()) { length = numBands+1; } int width = src.getWidth(); int height = src.getHeight(); if (dst == null) { dst = createCompatibleDestImage(src, null); dstCM = srcCM; } else { if (width != dst.getWidth()) { throw new IllegalArgumentException("Src width ("+width+ ") not equal to dst width ("+ dst.getWidth()+")"); } if (height != dst.getHeight()) { throw new IllegalArgumentException("Src height ("+height+ ") not equal to dst height ("+ dst.getHeight()+")"); } dstCM = dst.getColorModel(); if(srcCM.getColorSpace().getType() != dstCM.getColorSpace().getType()) { needToConvert = true; dst = createCompatibleDestImage(src, null); } } BufferedImage origDst = dst; // // Try to use a native BI rescale operation first // if (ImagingLib.filter(this, src, dst) == null) { // // Native BI rescale failed - convert to rasters // WritableRaster srcRaster = src.getRaster(); WritableRaster dstRaster = dst.getRaster(); if (srcCM.hasAlpha()) { if (numBands-1 == length || length == 1) { int minx = srcRaster.getMinX(); int miny = srcRaster.getMinY(); int[] bands = new int[numBands-1]; for (int i=0; i < numBands-1; i++) { bands[i] = i; } srcRaster = srcRaster.createWritableChild(minx, miny, srcRaster.getWidth(), srcRaster.getHeight(), minx, miny, bands); } } if (dstCM.hasAlpha()) { int dstNumBands = dstRaster.getNumBands(); if (dstNumBands-1 == length || length == 1) { int minx = dstRaster.getMinX(); int miny = dstRaster.getMinY(); int[] bands = new int[numBands-1]; for (int i=0; i < numBands-1; i++) { bands[i] = i; } dstRaster = dstRaster.createWritableChild(minx, miny, dstRaster.getWidth(), dstRaster.getHeight(), minx, miny, bands); } } // // Call the raster filter method // filter(srcRaster, dstRaster); } if (needToConvert) { // ColorModels are not the same ColorConvertOp ccop = new ColorConvertOp(hints); ccop.filter(dst, origDst); } return origDst; } /** * Rescales the pixel data in the source Raster. * If the destination Raster is null, a new Raster will be created. * The source and destination must have the same number of bands. * Otherwise, an IllegalArgumentException is thrown. * Note that the number of scaling factors/offsets in this object must * meet the restrictions stated in the class comments above. * Otherwise, an IllegalArgumentException is thrown. * @param src the <code>Raster</code> to be filtered * @param dst the destination for the filtering operation * or <code>null</code> * @return the filtered <code>WritableRaster</code>. * @throws IllegalArgumentException if <code>src</code> and * <code>dst</code> do not have the same number of bands, * or if the number of scaling factors and offsets in this * <code>RescaleOp</code> do not meet the requirements * stated in the class comments. */ public final WritableRaster filter (Raster src, WritableRaster dst) { int numBands = src.getNumBands(); int width = src.getWidth(); int height = src.getHeight(); int[] srcPix = null; int step = 0; int tidx = 0; // Create a new destination Raster, if needed if (dst == null) { dst = createCompatibleDestRaster(src); } else if (height != dst.getHeight() || width != dst.getWidth()) { throw new IllegalArgumentException("Width or height of Rasters do not "+ "match"); } else if (numBands != dst.getNumBands()) { // Make sure that the number of bands are equal throw new IllegalArgumentException("Number of bands in src " + numBands + " does not equal number of bands in dest " + dst.getNumBands()); } // Make sure that the arrays match // Make sure that the low/high/constant arrays match if (length != 1 && length != src.getNumBands()) { throw new IllegalArgumentException("Number of scaling constants "+ "does not equal the number of"+ " of bands in the src raster"); } // // Try for a native raster rescale first // if (ImagingLib.filter(this, src, dst) != null) { return dst; } // // Native raster rescale failed. // Try to see if a lookup operation can be used // if (canUseLookup(src, dst)) { int srcNgray = (1 << srcNbits); int dstNgray = (1 << dstNbits); if (dstNgray == 256) { ByteLookupTable lut = createByteLut(scaleFactors, offsets, numBands, srcNgray); LookupOp op = new LookupOp(lut, hints); op.filter(src, dst); } else { ShortLookupTable lut = createShortLut(scaleFactors, offsets, numBands, srcNgray); LookupOp op = new LookupOp(lut, hints); op.filter(src, dst); } } else { // // Fall back to the slow code // if (length > 1) { step = 1; } int sminX = src.getMinX(); int sY = src.getMinY(); int dminX = dst.getMinX(); int dY = dst.getMinY(); int sX; int dX; // // Determine bits per band to determine maxval for clamps. // The min is assumed to be zero. // REMIND: This must change if we ever support signed data types. // int nbits; int dstMax[] = new int[numBands]; int dstMask[] = new int[numBands]; SampleModel dstSM = dst.getSampleModel(); for (int z=0; z<numBands; z++) { nbits = dstSM.getSampleSize(z); dstMax[z] = (1 << nbits) - 1; dstMask[z] = ~(dstMax[z]); } int val; for (int y=0; y < height; y++, sY++, dY++) { dX = dminX; sX = sminX; for (int x = 0; x < width; x++, sX++, dX++) { // Get data for all bands at this x,y position srcPix = src.getPixel(sX, sY, srcPix); tidx = 0; for (int z=0; z<numBands; z++, tidx += step) { val = (int)(srcPix[z]*scaleFactors[tidx] + offsets[tidx]); // Clamp if ((val & dstMask[z]) != 0) { if (val < 0) { val = 0; } else { val = dstMax[z]; } } srcPix[z] = val; } // Put it back for all bands dst.setPixel(dX, dY, srcPix); } } } return dst; } /** * Returns the bounding box of the rescaled destination image. Since * this is not a geometric operation, the bounding box does not * change. */ public final Rectangle2D getBounds2D (BufferedImage src) { return getBounds2D(src.getRaster()); } /** * Returns the bounding box of the rescaled destination Raster. Since * this is not a geometric operation, the bounding box does not * change. * @param src the rescaled destination <code>Raster</code> * @return the bounds of the specified <code>Raster</code>. */ public final Rectangle2D getBounds2D (Raster src) { return src.getBounds(); } /** * Creates a zeroed destination image with the correct size and number of * bands. * @param src Source image for the filter operation. * @param destCM ColorModel of the destination. If null, the * ColorModel of the source will be used. * @return the zeroed-destination image. */ public BufferedImage createCompatibleDestImage (BufferedImage src, ColorModel destCM) { BufferedImage image; if (destCM == null) { ColorModel cm = src.getColorModel(); image = new BufferedImage(cm, src.getRaster().createCompatibleWritableRaster(), cm.isAlphaPremultiplied(), null); } else { int w = src.getWidth(); int h = src.getHeight(); image = new BufferedImage (destCM, destCM.createCompatibleWritableRaster(w, h), destCM.isAlphaPremultiplied(), null); } return image; } /** * Creates a zeroed-destination <code>Raster</code> with the correct * size and number of bands, given this source. * @param src the source <code>Raster</code> * @return the zeroed-destination <code>Raster</code>. */ public WritableRaster createCompatibleDestRaster (Raster src) { return src.createCompatibleWritableRaster(src.getWidth(), src.getHeight()); } /** * Returns the location of the destination point given a * point in the source. If dstPt is non-null, it will * be used to hold the return value. Since this is not a geometric * operation, the srcPt will equal the dstPt. * @param srcPt a point in the source image * @param dstPt the destination point or <code>null</code> * @return the location of the destination point. */ public final Point2D getPoint2D (Point2D srcPt, Point2D dstPt) { if (dstPt == null) { dstPt = new Point2D.Float(); } dstPt.setLocation(srcPt.getX(), srcPt.getY()); return dstPt; } /** * Returns the rendering hints for this op. * @return the rendering hints of this <code>RescaleOp</code>. */ public final RenderingHints getRenderingHints() { return hints; } }
⏎ java/awt/image/RescaleOp.java
Or download all of them as a single archive file:
File name: jre-rt-java-1.8.0_191-src.zip File size: 6664831 bytes Release date: 2018-10-28 Download
⇒ JRE 8 rt.jar - javax.* Package Source Code
2023-08-23, 290035👍, 4💬
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