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/TexturePaintContext.java
/*
* Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
* ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
*
*
*
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*
*
*
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*
*
*
*/
package java.awt;
import java.awt.image.BufferedImage;
import java.awt.image.Raster;
import java.awt.image.WritableRaster;
import java.awt.image.ColorModel;
import java.awt.image.DirectColorModel;
import java.awt.image.IndexColorModel;
import java.awt.geom.AffineTransform;
import java.awt.geom.NoninvertibleTransformException;
import java.lang.ref.WeakReference;
import sun.awt.image.SunWritableRaster;
import sun.awt.image.IntegerInterleavedRaster;
import sun.awt.image.ByteInterleavedRaster;
abstract class TexturePaintContext implements PaintContext {
public static ColorModel xrgbmodel =
new DirectColorModel(24, 0xff0000, 0xff00, 0xff);
public static ColorModel argbmodel = ColorModel.getRGBdefault();
ColorModel colorModel;
int bWidth;
int bHeight;
int maxWidth;
WritableRaster outRas;
double xOrg;
double yOrg;
double incXAcross;
double incYAcross;
double incXDown;
double incYDown;
int colincx;
int colincy;
int colincxerr;
int colincyerr;
int rowincx;
int rowincy;
int rowincxerr;
int rowincyerr;
public static PaintContext getContext(BufferedImage bufImg,
AffineTransform xform,
RenderingHints hints,
Rectangle devBounds) {
WritableRaster raster = bufImg.getRaster();
ColorModel cm = bufImg.getColorModel();
int maxw = devBounds.width;
Object val = hints.get(RenderingHints.KEY_INTERPOLATION);
boolean filter =
(val == null
? (hints.get(RenderingHints.KEY_RENDERING) == RenderingHints.VALUE_RENDER_QUALITY)
: (val != RenderingHints.VALUE_INTERPOLATION_NEAREST_NEIGHBOR));
if (raster instanceof IntegerInterleavedRaster &&
(!filter || isFilterableDCM(cm)))
{
IntegerInterleavedRaster iir = (IntegerInterleavedRaster) raster;
if (iir.getNumDataElements() == 1 && iir.getPixelStride() == 1) {
return new Int(iir, cm, xform, maxw, filter);
}
} else if (raster instanceof ByteInterleavedRaster) {
ByteInterleavedRaster bir = (ByteInterleavedRaster) raster;
if (bir.getNumDataElements() == 1 && bir.getPixelStride() == 1) {
if (filter) {
if (isFilterableICM(cm)) {
return new ByteFilter(bir, cm, xform, maxw);
}
} else {
return new Byte(bir, cm, xform, maxw);
}
}
}
return new Any(raster, cm, xform, maxw, filter);
}
public static boolean isFilterableICM(ColorModel cm) {
if (cm instanceof IndexColorModel) {
IndexColorModel icm = (IndexColorModel) cm;
if (icm.getMapSize() <= 256) {
return true;
}
}
return false;
}
public static boolean isFilterableDCM(ColorModel cm) {
if (cm instanceof DirectColorModel) {
DirectColorModel dcm = (DirectColorModel) cm;
return (isMaskOK(dcm.getAlphaMask(), true) &&
isMaskOK(dcm.getRedMask(), false) &&
isMaskOK(dcm.getGreenMask(), false) &&
isMaskOK(dcm.getBlueMask(), false));
}
return false;
}
public static boolean isMaskOK(int mask, boolean canbezero) {
if (canbezero && mask == 0) {
return true;
}
return (mask == 0xff ||
mask == 0xff00 ||
mask == 0xff0000 ||
mask == 0xff000000);
}
public static ColorModel getInternedColorModel(ColorModel cm) {
if (xrgbmodel == cm || xrgbmodel.equals(cm)) {
return xrgbmodel;
}
if (argbmodel == cm || argbmodel.equals(cm)) {
return argbmodel;
}
return cm;
}
TexturePaintContext(ColorModel cm, AffineTransform xform,
int bWidth, int bHeight, int maxw) {
this.colorModel = getInternedColorModel(cm);
this.bWidth = bWidth;
this.bHeight = bHeight;
this.maxWidth = maxw;
try {
xform = xform.createInverse();
} catch (NoninvertibleTransformException e) {
xform.setToScale(0, 0);
}
this.incXAcross = mod(xform.getScaleX(), bWidth);
this.incYAcross = mod(xform.getShearY(), bHeight);
this.incXDown = mod(xform.getShearX(), bWidth);
this.incYDown = mod(xform.getScaleY(), bHeight);
this.xOrg = xform.getTranslateX();
this.yOrg = xform.getTranslateY();
this.colincx = (int) incXAcross;
this.colincy = (int) incYAcross;
this.colincxerr = fractAsInt(incXAcross);
this.colincyerr = fractAsInt(incYAcross);
this.rowincx = (int) incXDown;
this.rowincy = (int) incYDown;
this.rowincxerr = fractAsInt(incXDown);
this.rowincyerr = fractAsInt(incYDown);
}
static int fractAsInt(double d) {
return (int) ((d % 1.0) * Integer.MAX_VALUE);
}
static double mod(double num, double den) {
num = num % den;
if (num < 0) {
num += den;
if (num >= den) {
// For very small negative numerators, the answer might
// be such a tiny bit less than den that the difference
// is smaller than the mantissa of a double allows and
// the result would then be rounded to den. If that is
// the case then we map that number to 0 as the nearest
// modulus representation.
num = 0;
}
}
return num;
}
/**
* Release the resources allocated for the operation.
*/
public void dispose() {
dropRaster(colorModel, outRas);
}
/**
* Return the ColorModel of the output.
*/
public ColorModel getColorModel() {
return colorModel;
}
/**
* Return a Raster containing the colors generated for the graphics
* operation.
* @param x,y,w,h The area in device space for which colors are
* generated.
*/
public Raster getRaster(int x, int y, int w, int h) {
if (outRas == null ||
outRas.getWidth() < w ||
outRas.getHeight() < h)
{
// If h==1, we will probably get lots of "scanline" rects
outRas = makeRaster((h == 1 ? Math.max(w, maxWidth) : w), h);
}
double X = mod(xOrg + x * incXAcross + y * incXDown, bWidth);
double Y = mod(yOrg + x * incYAcross + y * incYDown, bHeight);
setRaster((int) X, (int) Y, fractAsInt(X), fractAsInt(Y),
w, h, bWidth, bHeight,
colincx, colincxerr,
colincy, colincyerr,
rowincx, rowincxerr,
rowincy, rowincyerr);
SunWritableRaster.markDirty(outRas);
return outRas;
}
private static WeakReference<Raster> xrgbRasRef;
private static WeakReference<Raster> argbRasRef;
synchronized static WritableRaster makeRaster(ColorModel cm,
Raster srcRas,
int w, int h)
{
if (xrgbmodel == cm) {
if (xrgbRasRef != null) {
WritableRaster wr = (WritableRaster) xrgbRasRef.get();
if (wr != null && wr.getWidth() >= w && wr.getHeight() >= h) {
xrgbRasRef = null;
return wr;
}
}
// If we are going to cache this Raster, make it non-tiny
if (w <= 32 && h <= 32) {
w = h = 32;
}
} else if (argbmodel == cm) {
if (argbRasRef != null) {
WritableRaster wr = (WritableRaster) argbRasRef.get();
if (wr != null && wr.getWidth() >= w && wr.getHeight() >= h) {
argbRasRef = null;
return wr;
}
}
// If we are going to cache this Raster, make it non-tiny
if (w <= 32 && h <= 32) {
w = h = 32;
}
}
if (srcRas != null) {
return srcRas.createCompatibleWritableRaster(w, h);
} else {
return cm.createCompatibleWritableRaster(w, h);
}
}
synchronized static void dropRaster(ColorModel cm, Raster outRas) {
if (outRas == null) {
return;
}
if (xrgbmodel == cm) {
xrgbRasRef = new WeakReference<>(outRas);
} else if (argbmodel == cm) {
argbRasRef = new WeakReference<>(outRas);
}
}
private static WeakReference<Raster> byteRasRef;
synchronized static WritableRaster makeByteRaster(Raster srcRas,
int w, int h)
{
if (byteRasRef != null) {
WritableRaster wr = (WritableRaster) byteRasRef.get();
if (wr != null && wr.getWidth() >= w && wr.getHeight() >= h) {
byteRasRef = null;
return wr;
}
}
// If we are going to cache this Raster, make it non-tiny
if (w <= 32 && h <= 32) {
w = h = 32;
}
return srcRas.createCompatibleWritableRaster(w, h);
}
synchronized static void dropByteRaster(Raster outRas) {
if (outRas == null) {
return;
}
byteRasRef = new WeakReference<>(outRas);
}
public abstract WritableRaster makeRaster(int w, int h);
public abstract void setRaster(int x, int y, int xerr, int yerr,
int w, int h, int bWidth, int bHeight,
int colincx, int colincxerr,
int colincy, int colincyerr,
int rowincx, int rowincxerr,
int rowincy, int rowincyerr);
/*
* Blends the four ARGB values in the rgbs array using the factors
* described by xmul and ymul in the following ratio:
*
* rgbs[0] * (1-xmul) * (1-ymul) +
* rgbs[1] * ( xmul) * (1-ymul) +
* rgbs[2] * (1-xmul) * ( ymul) +
* rgbs[3] * ( xmul) * ( ymul)
*
* xmul and ymul are integer values in the half-open range [0, 2^31)
* where 0 == 0.0 and 2^31 == 1.0.
*
* Note that since the range is half-open, the values are always
* logically less than 1.0. This makes sense because while choosing
* pixels to blend, when the error values reach 1.0 we move to the
* next pixel and reset them to 0.0.
*/
public static int blend(int rgbs[], int xmul, int ymul) {
// xmul/ymul are 31 bits wide, (0 => 2^31-1)
// shift them to 12 bits wide, (0 => 2^12-1)
xmul = (xmul >>> 19);
ymul = (ymul >>> 19);
int accumA, accumR, accumG, accumB;
accumA = accumR = accumG = accumB = 0;
for (int i = 0; i < 4; i++) {
int rgb = rgbs[i];
// The complement of the [xy]mul values (1-[xy]mul) can result
// in new values in the range (1 => 2^12). Thus for any given
// loop iteration, the values could be anywhere in (0 => 2^12).
xmul = (1<<12) - xmul;
if ((i & 1) == 0) {
ymul = (1<<12) - ymul;
}
// xmul and ymul are each 12 bits (0 => 2^12)
// factor is thus 24 bits (0 => 2^24)
int factor = xmul * ymul;
if (factor != 0) {
// accum variables will accumulate 32 bits
// bytes extracted from rgb fit in 8 bits (0 => 255)
// byte * factor thus fits in 32 bits (0 => 255 * 2^24)
accumA += (((rgb >>> 24) ) * factor);
accumR += (((rgb >>> 16) & 0xff) * factor);
accumG += (((rgb >>> 8) & 0xff) * factor);
accumB += (((rgb ) & 0xff) * factor);
}
}
return ((((accumA + (1<<23)) >>> 24) << 24) |
(((accumR + (1<<23)) >>> 24) << 16) |
(((accumG + (1<<23)) >>> 24) << 8) |
(((accumB + (1<<23)) >>> 24) ));
}
static class Int extends TexturePaintContext {
IntegerInterleavedRaster srcRas;
int inData[];
int inOff;
int inSpan;
int outData[];
int outOff;
int outSpan;
boolean filter;
public Int(IntegerInterleavedRaster srcRas, ColorModel cm,
AffineTransform xform, int maxw, boolean filter)
{
super(cm, xform, srcRas.getWidth(), srcRas.getHeight(), maxw);
this.srcRas = srcRas;
this.inData = srcRas.getDataStorage();
this.inSpan = srcRas.getScanlineStride();
this.inOff = srcRas.getDataOffset(0);
this.filter = filter;
}
public WritableRaster makeRaster(int w, int h) {
WritableRaster ras = makeRaster(colorModel, srcRas, w, h);
IntegerInterleavedRaster iiRas = (IntegerInterleavedRaster) ras;
outData = iiRas.getDataStorage();
outSpan = iiRas.getScanlineStride();
outOff = iiRas.getDataOffset(0);
return ras;
}
public void setRaster(int x, int y, int xerr, int yerr,
int w, int h, int bWidth, int bHeight,
int colincx, int colincxerr,
int colincy, int colincyerr,
int rowincx, int rowincxerr,
int rowincy, int rowincyerr) {
int[] inData = this.inData;
int[] outData = this.outData;
int out = outOff;
int inSpan = this.inSpan;
int inOff = this.inOff;
int outSpan = this.outSpan;
boolean filter = this.filter;
boolean normalx = (colincx == 1 && colincxerr == 0 &&
colincy == 0 && colincyerr == 0) && !filter;
int rowx = x;
int rowy = y;
int rowxerr = xerr;
int rowyerr = yerr;
if (normalx) {
outSpan -= w;
}
int rgbs[] = filter ? new int[4] : null;
for (int j = 0; j < h; j++) {
if (normalx) {
int in = inOff + rowy * inSpan + bWidth;
x = bWidth - rowx;
out += w;
if (bWidth >= 32) {
int i = w;
while (i > 0) {
int copyw = (i < x) ? i : x;
System.arraycopy(inData, in - x,
outData, out - i,
copyw);
i -= copyw;
if ((x -= copyw) == 0) {
x = bWidth;
}
}
} else {
for (int i = w; i > 0; i--) {
outData[out - i] = inData[in - x];
if (--x == 0) {
x = bWidth;
}
}
}
} else {
x = rowx;
y = rowy;
xerr = rowxerr;
yerr = rowyerr;
for (int i = 0; i < w; i++) {
if (filter) {
int nextx, nexty;
if ((nextx = x + 1) >= bWidth) {
nextx = 0;
}
if ((nexty = y + 1) >= bHeight) {
nexty = 0;
}
rgbs[0] = inData[inOff + y * inSpan + x];
rgbs[1] = inData[inOff + y * inSpan + nextx];
rgbs[2] = inData[inOff + nexty * inSpan + x];
rgbs[3] = inData[inOff + nexty * inSpan + nextx];
outData[out + i] =
TexturePaintContext.blend(rgbs, xerr, yerr);
} else {
outData[out + i] = inData[inOff + y * inSpan + x];
}
if ((xerr += colincxerr) < 0) {
xerr &= Integer.MAX_VALUE;
x++;
}
if ((x += colincx) >= bWidth) {
x -= bWidth;
}
if ((yerr += colincyerr) < 0) {
yerr &= Integer.MAX_VALUE;
y++;
}
if ((y += colincy) >= bHeight) {
y -= bHeight;
}
}
}
if ((rowxerr += rowincxerr) < 0) {
rowxerr &= Integer.MAX_VALUE;
rowx++;
}
if ((rowx += rowincx) >= bWidth) {
rowx -= bWidth;
}
if ((rowyerr += rowincyerr) < 0) {
rowyerr &= Integer.MAX_VALUE;
rowy++;
}
if ((rowy += rowincy) >= bHeight) {
rowy -= bHeight;
}
out += outSpan;
}
}
}
static class Byte extends TexturePaintContext {
ByteInterleavedRaster srcRas;
byte inData[];
int inOff;
int inSpan;
byte outData[];
int outOff;
int outSpan;
public Byte(ByteInterleavedRaster srcRas, ColorModel cm,
AffineTransform xform, int maxw)
{
super(cm, xform, srcRas.getWidth(), srcRas.getHeight(), maxw);
this.srcRas = srcRas;
this.inData = srcRas.getDataStorage();
this.inSpan = srcRas.getScanlineStride();
this.inOff = srcRas.getDataOffset(0);
}
public WritableRaster makeRaster(int w, int h) {
WritableRaster ras = makeByteRaster(srcRas, w, h);
ByteInterleavedRaster biRas = (ByteInterleavedRaster) ras;
outData = biRas.getDataStorage();
outSpan = biRas.getScanlineStride();
outOff = biRas.getDataOffset(0);
return ras;
}
public void dispose() {
dropByteRaster(outRas);
}
public void setRaster(int x, int y, int xerr, int yerr,
int w, int h, int bWidth, int bHeight,
int colincx, int colincxerr,
int colincy, int colincyerr,
int rowincx, int rowincxerr,
int rowincy, int rowincyerr) {
byte[] inData = this.inData;
byte[] outData = this.outData;
int out = outOff;
int inSpan = this.inSpan;
int inOff = this.inOff;
int outSpan = this.outSpan;
boolean normalx = (colincx == 1 && colincxerr == 0 &&
colincy == 0 && colincyerr == 0);
int rowx = x;
int rowy = y;
int rowxerr = xerr;
int rowyerr = yerr;
if (normalx) {
outSpan -= w;
}
for (int j = 0; j < h; j++) {
if (normalx) {
int in = inOff + rowy * inSpan + bWidth;
x = bWidth - rowx;
out += w;
if (bWidth >= 32) {
int i = w;
while (i > 0) {
int copyw = (i < x) ? i : x;
System.arraycopy(inData, in - x,
outData, out - i,
copyw);
i -= copyw;
if ((x -= copyw) == 0) {
x = bWidth;
}
}
} else {
for (int i = w; i > 0; i--) {
outData[out - i] = inData[in - x];
if (--x == 0) {
x = bWidth;
}
}
}
} else {
x = rowx;
y = rowy;
xerr = rowxerr;
yerr = rowyerr;
for (int i = 0; i < w; i++) {
outData[out + i] = inData[inOff + y * inSpan + x];
if ((xerr += colincxerr) < 0) {
xerr &= Integer.MAX_VALUE;
x++;
}
if ((x += colincx) >= bWidth) {
x -= bWidth;
}
if ((yerr += colincyerr) < 0) {
yerr &= Integer.MAX_VALUE;
y++;
}
if ((y += colincy) >= bHeight) {
y -= bHeight;
}
}
}
if ((rowxerr += rowincxerr) < 0) {
rowxerr &= Integer.MAX_VALUE;
rowx++;
}
if ((rowx += rowincx) >= bWidth) {
rowx -= bWidth;
}
if ((rowyerr += rowincyerr) < 0) {
rowyerr &= Integer.MAX_VALUE;
rowy++;
}
if ((rowy += rowincy) >= bHeight) {
rowy -= bHeight;
}
out += outSpan;
}
}
}
static class ByteFilter extends TexturePaintContext {
ByteInterleavedRaster srcRas;
int inPalette[];
byte inData[];
int inOff;
int inSpan;
int outData[];
int outOff;
int outSpan;
public ByteFilter(ByteInterleavedRaster srcRas, ColorModel cm,
AffineTransform xform, int maxw)
{
super((cm.getTransparency() == Transparency.OPAQUE
? xrgbmodel : argbmodel),
xform, srcRas.getWidth(), srcRas.getHeight(), maxw);
this.inPalette = new int[256];
((IndexColorModel) cm).getRGBs(this.inPalette);
this.srcRas = srcRas;
this.inData = srcRas.getDataStorage();
this.inSpan = srcRas.getScanlineStride();
this.inOff = srcRas.getDataOffset(0);
}
public WritableRaster makeRaster(int w, int h) {
// Note that we do not pass srcRas to makeRaster since it
// is a Byte Raster and this colorModel needs an Int Raster
WritableRaster ras = makeRaster(colorModel, null, w, h);
IntegerInterleavedRaster iiRas = (IntegerInterleavedRaster) ras;
outData = iiRas.getDataStorage();
outSpan = iiRas.getScanlineStride();
outOff = iiRas.getDataOffset(0);
return ras;
}
public void setRaster(int x, int y, int xerr, int yerr,
int w, int h, int bWidth, int bHeight,
int colincx, int colincxerr,
int colincy, int colincyerr,
int rowincx, int rowincxerr,
int rowincy, int rowincyerr) {
byte[] inData = this.inData;
int[] outData = this.outData;
int out = outOff;
int inSpan = this.inSpan;
int inOff = this.inOff;
int outSpan = this.outSpan;
int rowx = x;
int rowy = y;
int rowxerr = xerr;
int rowyerr = yerr;
int rgbs[] = new int[4];
for (int j = 0; j < h; j++) {
x = rowx;
y = rowy;
xerr = rowxerr;
yerr = rowyerr;
for (int i = 0; i < w; i++) {
int nextx, nexty;
if ((nextx = x + 1) >= bWidth) {
nextx = 0;
}
if ((nexty = y + 1) >= bHeight) {
nexty = 0;
}
rgbs[0] = inPalette[0xff & inData[inOff + x +
inSpan * y]];
rgbs[1] = inPalette[0xff & inData[inOff + nextx +
inSpan * y]];
rgbs[2] = inPalette[0xff & inData[inOff + x +
inSpan * nexty]];
rgbs[3] = inPalette[0xff & inData[inOff + nextx +
inSpan * nexty]];
outData[out + i] =
TexturePaintContext.blend(rgbs, xerr, yerr);
if ((xerr += colincxerr) < 0) {
xerr &= Integer.MAX_VALUE;
x++;
}
if ((x += colincx) >= bWidth) {
x -= bWidth;
}
if ((yerr += colincyerr) < 0) {
yerr &= Integer.MAX_VALUE;
y++;
}
if ((y += colincy) >= bHeight) {
y -= bHeight;
}
}
if ((rowxerr += rowincxerr) < 0) {
rowxerr &= Integer.MAX_VALUE;
rowx++;
}
if ((rowx += rowincx) >= bWidth) {
rowx -= bWidth;
}
if ((rowyerr += rowincyerr) < 0) {
rowyerr &= Integer.MAX_VALUE;
rowy++;
}
if ((rowy += rowincy) >= bHeight) {
rowy -= bHeight;
}
out += outSpan;
}
}
}
static class Any extends TexturePaintContext {
WritableRaster srcRas;
boolean filter;
public Any(WritableRaster srcRas, ColorModel cm,
AffineTransform xform, int maxw, boolean filter)
{
super(cm, xform, srcRas.getWidth(), srcRas.getHeight(), maxw);
this.srcRas = srcRas;
this.filter = filter;
}
public WritableRaster makeRaster(int w, int h) {
return makeRaster(colorModel, srcRas, w, h);
}
public void setRaster(int x, int y, int xerr, int yerr,
int w, int h, int bWidth, int bHeight,
int colincx, int colincxerr,
int colincy, int colincyerr,
int rowincx, int rowincxerr,
int rowincy, int rowincyerr) {
Object data = null;
int rowx = x;
int rowy = y;
int rowxerr = xerr;
int rowyerr = yerr;
WritableRaster srcRas = this.srcRas;
WritableRaster outRas = this.outRas;
int rgbs[] = filter ? new int[4] : null;
for (int j = 0; j < h; j++) {
x = rowx;
y = rowy;
xerr = rowxerr;
yerr = rowyerr;
for (int i = 0; i < w; i++) {
data = srcRas.getDataElements(x, y, data);
if (filter) {
int nextx, nexty;
if ((nextx = x + 1) >= bWidth) {
nextx = 0;
}
if ((nexty = y + 1) >= bHeight) {
nexty = 0;
}
rgbs[0] = colorModel.getRGB(data);
data = srcRas.getDataElements(nextx, y, data);
rgbs[1] = colorModel.getRGB(data);
data = srcRas.getDataElements(x, nexty, data);
rgbs[2] = colorModel.getRGB(data);
data = srcRas.getDataElements(nextx, nexty, data);
rgbs[3] = colorModel.getRGB(data);
int rgb =
TexturePaintContext.blend(rgbs, xerr, yerr);
data = colorModel.getDataElements(rgb, data);
}
outRas.setDataElements(i, j, data);
if ((xerr += colincxerr) < 0) {
xerr &= Integer.MAX_VALUE;
x++;
}
if ((x += colincx) >= bWidth) {
x -= bWidth;
}
if ((yerr += colincyerr) < 0) {
yerr &= Integer.MAX_VALUE;
y++;
}
if ((y += colincy) >= bHeight) {
y -= bHeight;
}
}
if ((rowxerr += rowincxerr) < 0) {
rowxerr &= Integer.MAX_VALUE;
rowx++;
}
if ((rowx += rowincx) >= bWidth) {
rowx -= bWidth;
}
if ((rowyerr += rowincyerr) < 0) {
rowyerr &= Integer.MAX_VALUE;
rowy++;
}
if ((rowy += rowincy) >= bHeight) {
rowy -= bHeight;
}
}
}
}
}
⏎ java/awt/TexturePaintContext.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, 247455👍, 4💬
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