Example 26 with ColorModel
use of java.awt.image.ColorModel in project jdk8u_jdk by JetBrains.
the class PNGImageWriterSpi method canEncodeImage.
public boolean canEncodeImage(ImageTypeSpecifier type) {
SampleModel sampleModel = type.getSampleModel();
ColorModel colorModel = type.getColorModel();
// Find the maximum bit depth across all channels
int[] sampleSize = sampleModel.getSampleSize();
int bitDepth = sampleSize[0];
for (int i = 1; i < sampleSize.length; i++) {
if (sampleSize[i] > bitDepth) {
bitDepth = sampleSize[i];
}
}
// Ensure bitDepth is between 1 and 16
if (bitDepth < 1 || bitDepth > 16) {
return false;
}
// Check number of bands, alpha
int numBands = sampleModel.getNumBands();
if (numBands < 1 || numBands > 4) {
return false;
}
boolean hasAlpha = colorModel.hasAlpha();
// the check below to fail and return false.
if (colorModel instanceof IndexColorModel) {
return true;
}
if ((numBands == 1 || numBands == 3) && hasAlpha) {
return false;
}
if ((numBands == 2 || numBands == 4) && !hasAlpha) {
return false;
}
return true;
}
Also used :
SampleModel(java.awt.image.SampleModel)
ColorModel(java.awt.image.ColorModel)
IndexColorModel(java.awt.image.IndexColorModel)
IndexColorModel(java.awt.image.IndexColorModel)
Example 27 with ColorModel
use of java.awt.image.ColorModel in project jdk8u_jdk by JetBrains.
the class PNGMetadata method initialize.
/**
* Sets the IHDR_bitDepth and IHDR_colorType variables.
* The <code>numBands</code> parameter is necessary since
* we may only be writing a subset of the image bands.
*/
public void initialize(ImageTypeSpecifier imageType, int numBands) {
ColorModel colorModel = imageType.getColorModel();
SampleModel sampleModel = imageType.getSampleModel();
// Initialize IHDR_bitDepth
int[] sampleSize = sampleModel.getSampleSize();
int bitDepth = sampleSize[0];
// Fixes bug 4413109
for (int i = 1; i < sampleSize.length; i++) {
if (sampleSize[i] > bitDepth) {
bitDepth = sampleSize[i];
}
}
// Multi-channel images must have a bit depth of 8 or 16
if (sampleSize.length > 1 && bitDepth < 8) {
bitDepth = 8;
}
// Round bit depth up to a power of 2
if (bitDepth > 2 && bitDepth < 4) {
bitDepth = 4;
} else if (bitDepth > 4 && bitDepth < 8) {
bitDepth = 8;
} else if (bitDepth > 8 && bitDepth < 16) {
bitDepth = 16;
} else if (bitDepth > 16) {
throw new RuntimeException("bitDepth > 16!");
}
IHDR_bitDepth = bitDepth;
// Initialize IHDR_colorType
if (colorModel instanceof IndexColorModel) {
IndexColorModel icm = (IndexColorModel) colorModel;
int size = icm.getMapSize();
byte[] reds = new byte[size];
icm.getReds(reds);
byte[] greens = new byte[size];
icm.getGreens(greens);
byte[] blues = new byte[size];
icm.getBlues(blues);
// Determine whether the color tables are actually a gray ramp
// if the color type has not been set previously
boolean isGray = false;
if (!IHDR_present || (IHDR_colorType != PNGImageReader.PNG_COLOR_PALETTE)) {
isGray = true;
int scale = 255 / ((1 << IHDR_bitDepth) - 1);
for (int i = 0; i < size; i++) {
byte red = reds[i];
if ((red != (byte) (i * scale)) || (red != greens[i]) || (red != blues[i])) {
isGray = false;
break;
}
}
}
// Determine whether transparency exists
boolean hasAlpha = colorModel.hasAlpha();
byte[] alpha = null;
if (hasAlpha) {
alpha = new byte[size];
icm.getAlphas(alpha);
}
if (isGray && hasAlpha && (bitDepth == 8 || bitDepth == 16)) {
IHDR_colorType = PNGImageReader.PNG_COLOR_GRAY_ALPHA;
} else if (isGray && !hasAlpha) {
IHDR_colorType = PNGImageReader.PNG_COLOR_GRAY;
} else {
IHDR_colorType = PNGImageReader.PNG_COLOR_PALETTE;
PLTE_present = true;
PLTE_order = null;
PLTE_red = (byte[]) reds.clone();
PLTE_green = (byte[]) greens.clone();
PLTE_blue = (byte[]) blues.clone();
if (hasAlpha) {
tRNS_present = true;
tRNS_colorType = PNGImageReader.PNG_COLOR_PALETTE;
PLTE_order = new int[alpha.length];
// Reorder the palette so that non-opaque entries
// come first. Since the tRNS chunk does not have
// to store trailing 255's, this can save a
// considerable amount of space when encoding
// images with only one transparent pixel value,
// e.g., images from GIF sources.
byte[] newAlpha = new byte[alpha.length];
// Scan for non-opaque entries and assign them
// positions starting at 0.
int newIndex = 0;
for (int i = 0; i < alpha.length; i++) {
if (alpha[i] != (byte) 255) {
PLTE_order[i] = newIndex;
newAlpha[newIndex] = alpha[i];
++newIndex;
}
}
int numTransparent = newIndex;
// positions following the non-opaque entries.
for (int i = 0; i < alpha.length; i++) {
if (alpha[i] == (byte) 255) {
PLTE_order[i] = newIndex++;
}
}
// Reorder the palettes
byte[] oldRed = PLTE_red;
byte[] oldGreen = PLTE_green;
byte[] oldBlue = PLTE_blue;
// All have the same length
int len = oldRed.length;
PLTE_red = new byte[len];
PLTE_green = new byte[len];
PLTE_blue = new byte[len];
for (int i = 0; i < len; i++) {
PLTE_red[PLTE_order[i]] = oldRed[i];
PLTE_green[PLTE_order[i]] = oldGreen[i];
PLTE_blue[PLTE_order[i]] = oldBlue[i];
}
// Copy only the transparent entries into tRNS_alpha
tRNS_alpha = new byte[numTransparent];
System.arraycopy(newAlpha, 0, tRNS_alpha, 0, numTransparent);
}
}
} else {
if (numBands == 1) {
IHDR_colorType = PNGImageReader.PNG_COLOR_GRAY;
} else if (numBands == 2) {
IHDR_colorType = PNGImageReader.PNG_COLOR_GRAY_ALPHA;
} else if (numBands == 3) {
IHDR_colorType = PNGImageReader.PNG_COLOR_RGB;
} else if (numBands == 4) {
IHDR_colorType = PNGImageReader.PNG_COLOR_RGB_ALPHA;
} else {
throw new RuntimeException("Number of bands not 1-4!");
}
}
IHDR_present = true;
}
Also used :
SampleModel(java.awt.image.SampleModel)
ColorModel(java.awt.image.ColorModel)
IndexColorModel(java.awt.image.IndexColorModel)
IndexColorModel(java.awt.image.IndexColorModel)
Example 28 with ColorModel
use of java.awt.image.ColorModel in project jdk8u_jdk by JetBrains.
the class RenderableImageProducer method run.
/**
* The runnable method for this class. This will produce an image using
* the current RenderableImage and RenderContext and send it to all the
* ImageConsumer currently registered with this class.
*/
public void run() {
// First get the rendered image
RenderedImage rdrdImage;
if (rc != null) {
rdrdImage = rdblImage.createRendering(rc);
} else {
rdrdImage = rdblImage.createDefaultRendering();
}
// And its ColorModel
ColorModel colorModel = rdrdImage.getColorModel();
Raster raster = rdrdImage.getData();
SampleModel sampleModel = raster.getSampleModel();
DataBuffer dataBuffer = raster.getDataBuffer();
if (colorModel == null) {
colorModel = ColorModel.getRGBdefault();
}
int minX = raster.getMinX();
int minY = raster.getMinY();
int width = raster.getWidth();
int height = raster.getHeight();
Enumeration icList;
ImageConsumer ic;
// Set up the ImageConsumers
icList = ics.elements();
while (icList.hasMoreElements()) {
ic = (ImageConsumer) icList.nextElement();
ic.setDimensions(width, height);
ic.setHints(ImageConsumer.TOPDOWNLEFTRIGHT | ImageConsumer.COMPLETESCANLINES | ImageConsumer.SINGLEPASS | ImageConsumer.SINGLEFRAME);
}
// Get RGB pixels from the raster scanline by scanline and
// send to consumers.
int[] pix = new int[width];
int i, j;
int numBands = sampleModel.getNumBands();
int[] tmpPixel = new int[numBands];
for (j = 0; j < height; j++) {
for (i = 0; i < width; i++) {
sampleModel.getPixel(i, j, tmpPixel, dataBuffer);
pix[i] = colorModel.getDataElement(tmpPixel, 0);
}
// Now send the scanline to the Consumers
icList = ics.elements();
while (icList.hasMoreElements()) {
ic = (ImageConsumer) icList.nextElement();
ic.setPixels(0, j, width, 1, colorModel, pix, 0, width);
}
}
// Now tell the consumers we're done.
icList = ics.elements();
while (icList.hasMoreElements()) {
ic = (ImageConsumer) icList.nextElement();
ic.imageComplete(ImageConsumer.STATICIMAGEDONE);
}
}
Also used :
SampleModel(java.awt.image.SampleModel)
Enumeration(java.util.Enumeration)
ColorModel(java.awt.image.ColorModel)
DirectColorModel(java.awt.image.DirectColorModel)
ImageConsumer(java.awt.image.ImageConsumer)
Raster(java.awt.image.Raster)
RenderedImage(java.awt.image.RenderedImage)
DataBuffer(java.awt.image.DataBuffer)
Example 29 with ColorModel
use of java.awt.image.ColorModel in project jdk8u_jdk by JetBrains.
the class BMPImageWriter method write.
public void write(IIOMetadata streamMetadata, IIOImage image, ImageWriteParam param) throws IOException {
if (stream == null) {
throw new IllegalStateException(I18N.getString("BMPImageWriter7"));
}
if (image == null) {
throw new IllegalArgumentException(I18N.getString("BMPImageWriter8"));
}
clearAbortRequest();
processImageStarted(0);
if (param == null)
param = getDefaultWriteParam();
BMPImageWriteParam bmpParam = (BMPImageWriteParam) param;
// Default is using 24 bits per pixel.
int bitsPerPixel = 24;
boolean isPalette = false;
int paletteEntries = 0;
IndexColorModel icm = null;
RenderedImage input = null;
Raster inputRaster = null;
boolean writeRaster = image.hasRaster();
Rectangle sourceRegion = param.getSourceRegion();
SampleModel sampleModel = null;
ColorModel colorModel = null;
compImageSize = 0;
if (writeRaster) {
inputRaster = image.getRaster();
sampleModel = inputRaster.getSampleModel();
colorModel = ImageUtil.createColorModel(null, sampleModel);
if (sourceRegion == null)
sourceRegion = inputRaster.getBounds();
else
sourceRegion = sourceRegion.intersection(inputRaster.getBounds());
} else {
input = image.getRenderedImage();
sampleModel = input.getSampleModel();
colorModel = input.getColorModel();
Rectangle rect = new Rectangle(input.getMinX(), input.getMinY(), input.getWidth(), input.getHeight());
if (sourceRegion == null)
sourceRegion = rect;
else
sourceRegion = sourceRegion.intersection(rect);
}
IIOMetadata imageMetadata = image.getMetadata();
BMPMetadata bmpImageMetadata = null;
if (imageMetadata != null && imageMetadata instanceof BMPMetadata) {
bmpImageMetadata = (BMPMetadata) imageMetadata;
} else {
ImageTypeSpecifier imageType = new ImageTypeSpecifier(colorModel, sampleModel);
bmpImageMetadata = (BMPMetadata) getDefaultImageMetadata(imageType, param);
}
if (sourceRegion.isEmpty())
throw new RuntimeException(I18N.getString("BMPImageWrite0"));
int scaleX = param.getSourceXSubsampling();
int scaleY = param.getSourceYSubsampling();
int xOffset = param.getSubsamplingXOffset();
int yOffset = param.getSubsamplingYOffset();
// cache the data type;
int dataType = sampleModel.getDataType();
sourceRegion.translate(xOffset, yOffset);
sourceRegion.width -= xOffset;
sourceRegion.height -= yOffset;
int minX = sourceRegion.x / scaleX;
int minY = sourceRegion.y / scaleY;
w = (sourceRegion.width + scaleX - 1) / scaleX;
h = (sourceRegion.height + scaleY - 1) / scaleY;
xOffset = sourceRegion.x % scaleX;
yOffset = sourceRegion.y % scaleY;
Rectangle destinationRegion = new Rectangle(minX, minY, w, h);
boolean noTransform = destinationRegion.equals(sourceRegion);
// Raw data can only handle bytes, everything greater must be ASCII.
int[] sourceBands = param.getSourceBands();
boolean noSubband = true;
int numBands = sampleModel.getNumBands();
if (sourceBands != null) {
sampleModel = sampleModel.createSubsetSampleModel(sourceBands);
colorModel = null;
noSubband = false;
numBands = sampleModel.getNumBands();
} else {
sourceBands = new int[numBands];
for (int i = 0; i < numBands; i++) sourceBands[i] = i;
}
int[] bandOffsets = null;
boolean bgrOrder = true;
if (sampleModel instanceof ComponentSampleModel) {
bandOffsets = ((ComponentSampleModel) sampleModel).getBandOffsets();
if (sampleModel instanceof BandedSampleModel) {
// for images with BandedSampleModel we can not work
// with raster directly and must use writePixels()
bgrOrder = false;
} else {
// In any other case we must use writePixels()
for (int i = 0; i < bandOffsets.length; i++) {
bgrOrder &= (bandOffsets[i] == (bandOffsets.length - i - 1));
}
}
} else {
if (sampleModel instanceof SinglePixelPackedSampleModel) {
// BugId 4892214: we can not work with raster directly
// if image have different color order than RGB.
// We should use writePixels() for such images.
int[] bitOffsets = ((SinglePixelPackedSampleModel) sampleModel).getBitOffsets();
for (int i = 0; i < bitOffsets.length - 1; i++) {
bgrOrder &= bitOffsets[i] > bitOffsets[i + 1];
}
}
}
if (bandOffsets == null) {
// we will use getPixels() to extract pixel data for writePixels()
// Please note that getPixels() provides rgb bands order.
bandOffsets = new int[numBands];
for (int i = 0; i < numBands; i++) bandOffsets[i] = i;
}
noTransform &= bgrOrder;
int[] sampleSize = sampleModel.getSampleSize();
//XXX: check more
// Number of bytes that a scanline for the image written out will have.
int destScanlineBytes = w * numBands;
switch(bmpParam.getCompressionMode()) {
case ImageWriteParam.MODE_EXPLICIT:
compressionType = BMPCompressionTypes.getType(bmpParam.getCompressionType());
break;
case ImageWriteParam.MODE_COPY_FROM_METADATA:
compressionType = bmpImageMetadata.compression;
break;
case ImageWriteParam.MODE_DEFAULT:
compressionType = getPreferredCompressionType(colorModel, sampleModel);
break;
default:
// ImageWriteParam.MODE_DISABLED:
compressionType = BI_RGB;
}
if (!canEncodeImage(compressionType, colorModel, sampleModel)) {
throw new IOException("Image can not be encoded with compression type " + BMPCompressionTypes.getName(compressionType));
}
byte[] r = null, g = null, b = null, a = null;
if (compressionType == BI_BITFIELDS) {
bitsPerPixel = DataBuffer.getDataTypeSize(sampleModel.getDataType());
if (bitsPerPixel != 16 && bitsPerPixel != 32) {
// we should use 32bpp images in case of BI_BITFIELD
// compression to avoid color conversion artefacts
bitsPerPixel = 32;
// Setting this flag to false ensures that generic
// writePixels() will be used to store image data
noTransform = false;
}
destScanlineBytes = w * bitsPerPixel + 7 >> 3;
isPalette = true;
paletteEntries = 3;
r = new byte[paletteEntries];
g = new byte[paletteEntries];
b = new byte[paletteEntries];
a = new byte[paletteEntries];
int rmask = 0x00ff0000;
int gmask = 0x0000ff00;
int bmask = 0x000000ff;
if (bitsPerPixel == 16) {
/* NB: canEncodeImage() ensures we have image of
* either USHORT_565_RGB or USHORT_555_RGB type here.
* Technically, it should work for other direct color
* model types but it might be non compatible with win98
* and friends.
*/
if (colorModel instanceof DirectColorModel) {
DirectColorModel dcm = (DirectColorModel) colorModel;
rmask = dcm.getRedMask();
gmask = dcm.getGreenMask();
bmask = dcm.getBlueMask();
} else {
// an exception related to unsupported image format
throw new IOException("Image can not be encoded with " + "compression type " + BMPCompressionTypes.getName(compressionType));
}
}
writeMaskToPalette(rmask, 0, r, g, b, a);
writeMaskToPalette(gmask, 1, r, g, b, a);
writeMaskToPalette(bmask, 2, r, g, b, a);
if (!noTransform) {
// prepare info for writePixels procedure
bitMasks = new int[3];
bitMasks[0] = rmask;
bitMasks[1] = gmask;
bitMasks[2] = bmask;
bitPos = new int[3];
bitPos[0] = firstLowBit(rmask);
bitPos[1] = firstLowBit(gmask);
bitPos[2] = firstLowBit(bmask);
}
if (colorModel instanceof IndexColorModel) {
icm = (IndexColorModel) colorModel;
}
} else {
// handle BI_RGB compression
if (colorModel instanceof IndexColorModel) {
isPalette = true;
icm = (IndexColorModel) colorModel;
paletteEntries = icm.getMapSize();
if (paletteEntries <= 2) {
bitsPerPixel = 1;
destScanlineBytes = w + 7 >> 3;
} else if (paletteEntries <= 16) {
bitsPerPixel = 4;
destScanlineBytes = w + 1 >> 1;
} else if (paletteEntries <= 256) {
bitsPerPixel = 8;
} else {
// Cannot be written as a Palette image. So write out as
// 24 bit image.
bitsPerPixel = 24;
isPalette = false;
paletteEntries = 0;
destScanlineBytes = w * 3;
}
if (isPalette == true) {
r = new byte[paletteEntries];
g = new byte[paletteEntries];
b = new byte[paletteEntries];
a = new byte[paletteEntries];
icm.getAlphas(a);
icm.getReds(r);
icm.getGreens(g);
icm.getBlues(b);
}
} else {
// Grey scale images
if (numBands == 1) {
isPalette = true;
paletteEntries = 256;
bitsPerPixel = sampleSize[0];
destScanlineBytes = (w * bitsPerPixel + 7 >> 3);
r = new byte[256];
g = new byte[256];
b = new byte[256];
a = new byte[256];
for (int i = 0; i < 256; i++) {
r[i] = (byte) i;
g[i] = (byte) i;
b[i] = (byte) i;
a[i] = (byte) 255;
}
} else {
if (sampleModel instanceof SinglePixelPackedSampleModel && noSubband) {
/* NB: the actual pixel size can be smaller than
* size of used DataBuffer element.
* For example: in case of TYPE_INT_RGB actual pixel
* size is 24 bits, but size of DataBuffere element
* is 32 bits
*/
int[] sample_sizes = sampleModel.getSampleSize();
bitsPerPixel = 0;
for (int size : sample_sizes) {
bitsPerPixel += size;
}
bitsPerPixel = roundBpp(bitsPerPixel);
if (bitsPerPixel != DataBuffer.getDataTypeSize(sampleModel.getDataType())) {
noTransform = false;
}
destScanlineBytes = w * bitsPerPixel + 7 >> 3;
}
}
}
}
// actual writing of image data
int fileSize = 0;
int offset = 0;
int headerSize = 0;
int imageSize = 0;
int xPelsPerMeter = 0;
int yPelsPerMeter = 0;
int colorsUsed = 0;
int colorsImportant = paletteEntries;
// Calculate padding for each scanline
int padding = destScanlineBytes % 4;
if (padding != 0) {
padding = 4 - padding;
}
// FileHeader is 14 bytes, BitmapHeader is 40 bytes,
// add palette size and that is where the data will begin
offset = 54 + paletteEntries * 4;
imageSize = (destScanlineBytes + padding) * h;
fileSize = imageSize + offset;
headerSize = 40;
long headPos = stream.getStreamPosition();
writeFileHeader(fileSize, offset);
/* According to MSDN description, the top-down image layout
* is allowed only if compression type is BI_RGB or BI_BITFIELDS.
* Images with any other compression type must be wrote in the
* bottom-up layout.
*/
if (compressionType == BI_RGB || compressionType == BI_BITFIELDS) {
isTopDown = bmpParam.isTopDown();
} else {
isTopDown = false;
}
writeInfoHeader(headerSize, bitsPerPixel);
// compression
stream.writeInt(compressionType);
// imageSize
stream.writeInt(imageSize);
// xPelsPerMeter
stream.writeInt(xPelsPerMeter);
// yPelsPerMeter
stream.writeInt(yPelsPerMeter);
// Colors Used
stream.writeInt(colorsUsed);
// Colors Important
stream.writeInt(colorsImportant);
// palette
if (isPalette == true) {
// write palette
if (compressionType == BI_BITFIELDS) {
// write masks for red, green and blue components.
for (int i = 0; i < 3; i++) {
int mask = (a[i] & 0xFF) + ((r[i] & 0xFF) * 0x100) + ((g[i] & 0xFF) * 0x10000) + ((b[i] & 0xFF) * 0x1000000);
stream.writeInt(mask);
}
} else {
for (int i = 0; i < paletteEntries; i++) {
stream.writeByte(b[i]);
stream.writeByte(g[i]);
stream.writeByte(r[i]);
stream.writeByte(a[i]);
}
}
}
// Writing of actual image data
int scanlineBytes = w * numBands;
// Buffer for up to 8 rows of pixels
int[] pixels = new int[scanlineBytes * scaleX];
// Also create a buffer to hold one line of the data
// to be written to the file, so we can use array writes.
bpixels = new byte[destScanlineBytes];
int l;
if (compressionType == BI_JPEG || compressionType == BI_PNG) {
// prepare embedded buffer
embedded_stream = new ByteArrayOutputStream();
writeEmbedded(image, bmpParam);
// update the file/image Size
embedded_stream.flush();
imageSize = embedded_stream.size();
long endPos = stream.getStreamPosition();
fileSize = (int) (offset + imageSize);
stream.seek(headPos);
writeSize(fileSize, 2);
stream.seek(headPos);
writeSize(imageSize, 34);
stream.seek(endPos);
stream.write(embedded_stream.toByteArray());
embedded_stream = null;
if (abortRequested()) {
processWriteAborted();
} else {
processImageComplete();
stream.flushBefore(stream.getStreamPosition());
}
return;
}
int maxBandOffset = bandOffsets[0];
for (int i = 1; i < bandOffsets.length; i++) if (bandOffsets[i] > maxBandOffset)
maxBandOffset = bandOffsets[i];
int[] pixel = new int[maxBandOffset + 1];
int destScanlineLength = destScanlineBytes;
if (noTransform && noSubband) {
destScanlineLength = destScanlineBytes / (DataBuffer.getDataTypeSize(dataType) >> 3);
}
for (int i = 0; i < h; i++) {
if (abortRequested()) {
break;
}
int row = minY + i;
if (!isTopDown)
row = minY + h - i - 1;
// Get the pixels
Raster src = inputRaster;
Rectangle srcRect = new Rectangle(minX * scaleX + xOffset, row * scaleY + yOffset, (w - 1) * scaleX + 1, 1);
if (!writeRaster)
src = input.getData(srcRect);
if (noTransform && noSubband) {
SampleModel sm = src.getSampleModel();
int pos = 0;
int startX = srcRect.x - src.getSampleModelTranslateX();
int startY = srcRect.y - src.getSampleModelTranslateY();
if (sm instanceof ComponentSampleModel) {
ComponentSampleModel csm = (ComponentSampleModel) sm;
pos = csm.getOffset(startX, startY, 0);
for (int nb = 1; nb < csm.getNumBands(); nb++) {
if (pos > csm.getOffset(startX, startY, nb)) {
pos = csm.getOffset(startX, startY, nb);
}
}
} else if (sm instanceof MultiPixelPackedSampleModel) {
MultiPixelPackedSampleModel mppsm = (MultiPixelPackedSampleModel) sm;
pos = mppsm.getOffset(startX, startY);
} else if (sm instanceof SinglePixelPackedSampleModel) {
SinglePixelPackedSampleModel sppsm = (SinglePixelPackedSampleModel) sm;
pos = sppsm.getOffset(startX, startY);
}
if (compressionType == BI_RGB || compressionType == BI_BITFIELDS) {
switch(dataType) {
case DataBuffer.TYPE_BYTE:
byte[] bdata = ((DataBufferByte) src.getDataBuffer()).getData();
stream.write(bdata, pos, destScanlineLength);
break;
case DataBuffer.TYPE_SHORT:
short[] sdata = ((DataBufferShort) src.getDataBuffer()).getData();
stream.writeShorts(sdata, pos, destScanlineLength);
break;
case DataBuffer.TYPE_USHORT:
short[] usdata = ((DataBufferUShort) src.getDataBuffer()).getData();
stream.writeShorts(usdata, pos, destScanlineLength);
break;
case DataBuffer.TYPE_INT:
int[] idata = ((DataBufferInt) src.getDataBuffer()).getData();
stream.writeInts(idata, pos, destScanlineLength);
break;
}
for (int k = 0; k < padding; k++) {
stream.writeByte(0);
}
} else if (compressionType == BI_RLE4) {
if (bpixels == null || bpixels.length < scanlineBytes)
bpixels = new byte[scanlineBytes];
src.getPixels(srcRect.x, srcRect.y, srcRect.width, srcRect.height, pixels);
for (int h = 0; h < scanlineBytes; h++) {
bpixels[h] = (byte) pixels[h];
}
encodeRLE4(bpixels, scanlineBytes);
} else if (compressionType == BI_RLE8) {
//System.arraycopy(bdata, pos, bpixels, 0, scanlineBytes);
if (bpixels == null || bpixels.length < scanlineBytes)
bpixels = new byte[scanlineBytes];
src.getPixels(srcRect.x, srcRect.y, srcRect.width, srcRect.height, pixels);
for (int h = 0; h < scanlineBytes; h++) {
bpixels[h] = (byte) pixels[h];
}
encodeRLE8(bpixels, scanlineBytes);
}
} else {
src.getPixels(srcRect.x, srcRect.y, srcRect.width, srcRect.height, pixels);
if (scaleX != 1 || maxBandOffset != numBands - 1) {
for (int j = 0, k = 0, n = 0; j < w; j++, k += scaleX * numBands, n += numBands) {
System.arraycopy(pixels, k, pixel, 0, pixel.length);
for (int m = 0; m < numBands; m++) {
// pixel data is provided here in RGB order
pixels[n + m] = pixel[sourceBands[m]];
}
}
}
writePixels(0, scanlineBytes, bitsPerPixel, pixels, padding, numBands, icm);
}
processImageProgress(100.0f * (((float) i) / ((float) h)));
}
if (compressionType == BI_RLE4 || compressionType == BI_RLE8) {
// Write the RLE EOF marker and
stream.writeByte(0);
stream.writeByte(1);
incCompImageSize(2);
// update the file/image Size
imageSize = compImageSize;
fileSize = compImageSize + offset;
long endPos = stream.getStreamPosition();
stream.seek(headPos);
writeSize(fileSize, 2);
stream.seek(headPos);
writeSize(imageSize, 34);
stream.seek(endPos);
}
if (abortRequested()) {
processWriteAborted();
} else {
processImageComplete();
stream.flushBefore(stream.getStreamPosition());
}
}
Also used :
Rectangle(java.awt.Rectangle)
MultiPixelPackedSampleModel(java.awt.image.MultiPixelPackedSampleModel)
ComponentSampleModel(java.awt.image.ComponentSampleModel)
DataBufferInt(java.awt.image.DataBufferInt)
DataBufferByte(java.awt.image.DataBufferByte)
ImageTypeSpecifier(javax.imageio.ImageTypeSpecifier)
DataBufferShort(java.awt.image.DataBufferShort)
IndexColorModel(java.awt.image.IndexColorModel)
DirectColorModel(java.awt.image.DirectColorModel)
ColorModel(java.awt.image.ColorModel)
BandedSampleModel(java.awt.image.BandedSampleModel)
DirectColorModel(java.awt.image.DirectColorModel)
DataBufferUShort(java.awt.image.DataBufferUShort)
IndexColorModel(java.awt.image.IndexColorModel)
Raster(java.awt.image.Raster)
SinglePixelPackedSampleModel(java.awt.image.SinglePixelPackedSampleModel)
BMPImageWriteParam(javax.imageio.plugins.bmp.BMPImageWriteParam)
IOException(java.io.IOException)
ByteArrayOutputStream(java.io.ByteArrayOutputStream)
IIOMetadata(javax.imageio.metadata.IIOMetadata)
ComponentSampleModel(java.awt.image.ComponentSampleModel)
SampleModel(java.awt.image.SampleModel)
BandedSampleModel(java.awt.image.BandedSampleModel)
MultiPixelPackedSampleModel(java.awt.image.MultiPixelPackedSampleModel)
SinglePixelPackedSampleModel(java.awt.image.SinglePixelPackedSampleModel)
RenderedImage(java.awt.image.RenderedImage)
Example 30 with ColorModel
use of java.awt.image.ColorModel in project jdk8u_jdk by JetBrains.
the class ImageUtil method createColorModel.
/* XXX testing only
public static void main(String[] args) {
ImageTypeSpecifier bilevel =
ImageTypeSpecifier.createIndexed(new byte[] {(byte)0, (byte)255},
new byte[] {(byte)0, (byte)255},
new byte[] {(byte)0, (byte)255},
null, 1,
DataBuffer.TYPE_BYTE);
ImageTypeSpecifier gray =
ImageTypeSpecifier.createGrayscale(8, DataBuffer.TYPE_BYTE, false);
ImageTypeSpecifier grayAlpha =
ImageTypeSpecifier.createGrayscale(8, DataBuffer.TYPE_BYTE, false,
false);
ImageTypeSpecifier rgb =
ImageTypeSpecifier.createInterleaved(ColorSpace.getInstance(ColorSpace.CS_sRGB),
new int[] {0, 1, 2},
DataBuffer.TYPE_BYTE,
false,
false);
ImageTypeSpecifier rgba =
ImageTypeSpecifier.createInterleaved(ColorSpace.getInstance(ColorSpace.CS_sRGB),
new int[] {0, 1, 2, 3},
DataBuffer.TYPE_BYTE,
true,
false);
ImageTypeSpecifier packed =
ImageTypeSpecifier.createPacked(ColorSpace.getInstance(ColorSpace.CS_sRGB),
0xff000000,
0x00ff0000,
0x0000ff00,
0x000000ff,
DataBuffer.TYPE_BYTE,
false);
SampleModel bandedSM =
new java.awt.image.BandedSampleModel(DataBuffer.TYPE_BYTE,
1, 1, 15);
System.out.println(createColorModel(bilevel.getSampleModel()));
System.out.println(createColorModel(gray.getSampleModel()));
System.out.println(createColorModel(grayAlpha.getSampleModel()));
System.out.println(createColorModel(rgb.getSampleModel()));
System.out.println(createColorModel(rgba.getSampleModel()));
System.out.println(createColorModel(packed.getSampleModel()));
System.out.println(createColorModel(bandedSM));
}
*/
/**
* Creates a <code>ColorModel</code> that may be used with the
* specified <code>SampleModel</code>. If a suitable
* <code>ColorModel</code> cannot be found, this method returns
* <code>null</code>.
*
* <p> Suitable <code>ColorModel</code>s are guaranteed to exist
* for all instances of <code>ComponentSampleModel</code>.
* For 1- and 3- banded <code>SampleModel</code>s, the returned
* <code>ColorModel</code> will be opaque. For 2- and 4-banded
* <code>SampleModel</code>s, the output will use alpha transparency
* which is not premultiplied. 1- and 2-banded data will use a
* grayscale <code>ColorSpace</code>, and 3- and 4-banded data a sRGB
* <code>ColorSpace</code>. Data with 5 or more bands will have a
* <code>BogusColorSpace</code>.</p>
*
* <p>An instance of <code>DirectColorModel</code> will be created for
* instances of <code>SinglePixelPackedSampleModel</code> with no more
* than 4 bands.</p>
*
* <p>An instance of <code>IndexColorModel</code> will be created for
* instances of <code>MultiPixelPackedSampleModel</code>. The colormap
* will be a grayscale ramp with <code>1 << numberOfBits</code>
* entries ranging from zero to at most 255.</p>
*
* @return An instance of <code>ColorModel</code> that is suitable for
* the supplied <code>SampleModel</code>, or <code>null</code>.
*
* @throws IllegalArgumentException If <code>sampleModel</code> is
* <code>null</code>.
*/
public static final ColorModel createColorModel(SampleModel sampleModel) {
// Check the parameter.
if (sampleModel == null) {
throw new IllegalArgumentException("sampleModel == null!");
}
// Get the data type.
int dataType = sampleModel.getDataType();
// Check the data type
switch(dataType) {
case DataBuffer.TYPE_BYTE:
case DataBuffer.TYPE_USHORT:
case DataBuffer.TYPE_SHORT:
case DataBuffer.TYPE_INT:
case DataBuffer.TYPE_FLOAT:
case DataBuffer.TYPE_DOUBLE:
break;
default:
// Return null for other types.
return null;
}
// The return variable.
ColorModel colorModel = null;
// Get the sample size.
int[] sampleSize = sampleModel.getSampleSize();
// Create a Component ColorModel.
if (sampleModel instanceof ComponentSampleModel) {
// Get the number of bands.
int numBands = sampleModel.getNumBands();
// Determine the color space.
ColorSpace colorSpace = null;
if (numBands <= 2) {
colorSpace = ColorSpace.getInstance(ColorSpace.CS_GRAY);
} else if (numBands <= 4) {
colorSpace = ColorSpace.getInstance(ColorSpace.CS_sRGB);
} else {
colorSpace = new BogusColorSpace(numBands);
}
boolean hasAlpha = (numBands == 2) || (numBands == 4);
boolean isAlphaPremultiplied = false;
int transparency = hasAlpha ? Transparency.TRANSLUCENT : Transparency.OPAQUE;
colorModel = new ComponentColorModel(colorSpace, sampleSize, hasAlpha, isAlphaPremultiplied, transparency, dataType);
} else if (sampleModel.getNumBands() <= 4 && sampleModel instanceof SinglePixelPackedSampleModel) {
SinglePixelPackedSampleModel sppsm = (SinglePixelPackedSampleModel) sampleModel;
int[] bitMasks = sppsm.getBitMasks();
int rmask = 0;
int gmask = 0;
int bmask = 0;
int amask = 0;
int numBands = bitMasks.length;
if (numBands <= 2) {
rmask = gmask = bmask = bitMasks[0];
if (numBands == 2) {
amask = bitMasks[1];
}
} else {
rmask = bitMasks[0];
gmask = bitMasks[1];
bmask = bitMasks[2];
if (numBands == 4) {
amask = bitMasks[3];
}
}
int bits = 0;
for (int i = 0; i < sampleSize.length; i++) {
bits += sampleSize[i];
}
return new DirectColorModel(bits, rmask, gmask, bmask, amask);
} else if (sampleModel instanceof MultiPixelPackedSampleModel) {
// Load the colormap with a ramp.
int bitsPerSample = sampleSize[0];
int numEntries = 1 << bitsPerSample;
byte[] map = new byte[numEntries];
for (int i = 0; i < numEntries; i++) {
map[i] = (byte) (i * 255 / (numEntries - 1));
}
colorModel = new IndexColorModel(bitsPerSample, numEntries, map, map, map);
}
return colorModel;
}
Also used :
ColorSpace(java.awt.color.ColorSpace)
ComponentColorModel(java.awt.image.ComponentColorModel)
SinglePixelPackedSampleModel(java.awt.image.SinglePixelPackedSampleModel)
MultiPixelPackedSampleModel(java.awt.image.MultiPixelPackedSampleModel)
ComponentSampleModel(java.awt.image.ComponentSampleModel)
Point(java.awt.Point)
IndexColorModel(java.awt.image.IndexColorModel)
DirectColorModel(java.awt.image.DirectColorModel)
ComponentColorModel(java.awt.image.ComponentColorModel)
ColorModel(java.awt.image.ColorModel)
DirectColorModel(java.awt.image.DirectColorModel)
IndexColorModel(java.awt.image.IndexColorModel)
Aggregations
ColorModel (java.awt.image.ColorModel)85
IndexColorModel (java.awt.image.IndexColorModel)35
WritableRaster (java.awt.image.WritableRaster)32
BufferedImage (java.awt.image.BufferedImage)30
DirectColorModel (java.awt.image.DirectColorModel)23
ComponentColorModel (java.awt.image.ComponentColorModel)18
Raster (java.awt.image.Raster)16
SampleModel (java.awt.image.SampleModel)16
ColorSpace (java.awt.color.ColorSpace)12
SurfaceData (sun.java2d.SurfaceData)9
ComponentSampleModel (java.awt.image.ComponentSampleModel)8
Graphics2D (java.awt.Graphics2D)7
Rectangle (java.awt.Rectangle)7
ImageTypeSpecifier (javax.imageio.ImageTypeSpecifier)7
Point (java.awt.Point)5
Component (java.awt.Component)4
Paint (java.awt.Paint)4
AffineTransform (java.awt.geom.AffineTransform)4
DataBufferByte (java.awt.image.DataBufferByte)4
MultiPixelPackedSampleModel (java.awt.image.MultiPixelPackedSampleModel)4
