public SampleModel getSampleModel() {
if (sampleModel != null) return sampleModel;
int realWidth = (int) Math.min(tileWidth, width);
int realHeight = (int) Math.min(tileHeight, height);
if (nComp == 1 && (maxDepth == 1 || maxDepth == 2 || maxDepth == 4))
sampleModel =
new MultiPixelPackedSampleModel(DataBuffer.TYPE_BYTE, realWidth, realHeight, maxDepth);
else if (maxDepth <= 8)
sampleModel =
new PixelInterleavedSampleModel(
DataBuffer.TYPE_BYTE, realWidth, realHeight, nComp, realWidth * nComp, bandOffsets);
else if (maxDepth <= 16)
sampleModel =
new PixelInterleavedSampleModel(
isSigned ? DataBuffer.TYPE_SHORT : DataBuffer.TYPE_USHORT,
realWidth,
realHeight,
nComp,
realWidth * nComp,
bandOffsets);
else if (maxDepth <= 32)
sampleModel =
new PixelInterleavedSampleModel(
DataBuffer.TYPE_INT, realWidth, realHeight, nComp, realWidth * nComp, bandOffsets);
else throw new IllegalArgumentException(I18N.getString("J2KReadState11") + " " + +maxDepth);
return sampleModel;
}
/**
* Constructs <code>J2KReadState</code>.
*
* @param iis The input stream.
* @param param The reading parameters.
* @param reader The <code>J2KImageReader</code> which holds this state. It is necessary for
* processing abortion.
* @throw IllegalArgumentException If the provided <code>iis</code>, or <code>param</code> is
* <code>null</code>.
*/
public J2KReadState(ImageInputStream iis, J2KImageReadParamJava param, J2KImageReader reader) {
if (iis == null || param == null)
throw new IllegalArgumentException(I18N.getString("J2KReadState0"));
this.iis = iis;
this.j2krparam = param;
this.reader = reader;
initializeRead(0, param, null);
}
private void initializeRead(int imageIndex, J2KImageReadParamJava param, J2KMetadata metadata) {
try {
iis.mark();
in = new IISRandomAccessIO(iis);
// **** File Format ****
// If the codestream is wrapped in the jp2 fileformat, Read the
// file format wrapper
ff = new FileFormatReader(in, metadata);
ff.readFileFormat();
in.seek(ff.getFirstCodeStreamPos());
hi = new HeaderInfo();
try {
hd = new HeaderDecoder(in, j2krparam, hi);
} catch (EOFException e) {
throw new RuntimeException(I18N.getString("J2KReadState2"));
} catch (IOException ioe) {
throw new RuntimeException(ioe);
}
this.width = hd.getImgWidth();
this.height = hd.getImgHeight();
Rectangle sourceRegion = param.getSourceRegion();
sourceOrigin = new Point();
sourceRegion = new Rectangle(hd.getImgULX(), hd.getImgULY(), this.width, this.height);
// if the subsample rate for components are not consistent
boolean compConsistent = true;
stepX = hd.getCompSubsX(0);
stepY = hd.getCompSubsY(0);
for (int i = 1; i < nComp; i++) {
if (stepX != hd.getCompSubsX(i) || stepY != hd.getCompSubsY(i))
throw new RuntimeException(I18N.getString("J2KReadState12"));
}
// Get minimum number of resolution levels available across
// all tile-components.
int minResLevels = hd.getDecoderSpecs().dls.getMin();
// Set current resolution level.
this.resolution = param != null ? param.getResolution() : minResLevels;
if (resolution < 0 || resolution > minResLevels) {
resolution = minResLevels;
}
// Convert source region to lower resolution level.
if (resolution != minResLevels || stepX != 1 || stepY != 1) {
sourceRegion =
J2KImageReader.getReducedRect(sourceRegion, minResLevels, resolution, stepX, stepY);
}
destinationRegion = (Rectangle) sourceRegion.clone();
J2KImageReader.computeRegionsWrapper(
param,
false,
this.width,
this.height,
param.getDestination(),
sourceRegion,
destinationRegion);
sourceOrigin = new Point(sourceRegion.x, sourceRegion.y);
scaleX = param.getSourceXSubsampling();
scaleY = param.getSourceYSubsampling();
xOffset = param.getSubsamplingXOffset();
yOffset = param.getSubsamplingYOffset();
this.width = destinationRegion.width;
this.height = destinationRegion.height;
Point tileOffset = hd.getTilingOrigin(null);
this.tileWidth = hd.getNomTileWidth();
this.tileHeight = hd.getNomTileHeight();
// Convert tile 0 to lower resolution level.
if (resolution != minResLevels || stepX != 1 || stepY != 1) {
Rectangle tileRect = new Rectangle(tileOffset);
tileRect.width = tileWidth;
tileRect.height = tileHeight;
tileRect = J2KImageReader.getReducedRect(tileRect, minResLevels, resolution, stepX, stepY);
tileOffset = tileRect.getLocation();
tileWidth = tileRect.width;
tileHeight = tileRect.height;
}
tileXOffset = tileOffset.x;
tileYOffset = tileOffset.y;
// Set the tile step sizes. These values are used because it
// is possible that tiles will be empty. In particular at lower
// resolution levels when subsampling is used this may be the
// case. This method of calculation will work at least for
// Profile-0 images.
if (tileWidth * (1 << (minResLevels - resolution)) * stepX > hd.getNomTileWidth()) {
tileStepX =
(tileWidth * (1 << (minResLevels - resolution)) * stepX + hd.getNomTileWidth() - 1)
/ hd.getNomTileWidth();
} else {
tileStepX = 1;
}
if (tileHeight * (1 << (minResLevels - resolution)) * stepY > hd.getNomTileHeight()) {
tileStepY =
(tileHeight * (1 << (minResLevels - resolution)) * stepY + hd.getNomTileHeight() - 1)
/ hd.getNomTileHeight();
} else {
tileStepY = 1;
}
if (!destinationRegion.equals(sourceRegion)) noTransform = false;
// **** Header decoder ****
// Instantiate header decoder and read main header
decSpec = hd.getDecoderSpecs();
// **** Instantiate decoding chain ****
// Get demixed bitdepths
nComp = hd.getNumComps();
int[] depth = new int[nComp];
for (int i = 0; i < nComp; i++) depth[i] = hd.getOriginalBitDepth(i);
// Get channel mapping
ChannelDefinitionBox cdb = null;
if (metadata != null)
cdb = (ChannelDefinitionBox) metadata.getElement("JPEG2000ChannelDefinitionBox");
channelMap = new int[nComp];
if (cdb != null && metadata.getElement("JPEG2000PaletteBox") == null) {
short[] assoc = cdb.getAssociation();
short[] types = cdb.getTypes();
short[] channels = cdb.getChannel();
for (int i = 0; i < types.length; i++)
if (types[i] == 0) channelMap[channels[i]] = assoc[i] - 1;
else if (types[i] == 1 || types[i] == 2) channelMap[channels[i]] = channels[i];
} else {
for (int i = 0; i < nComp; i++) channelMap[i] = i;
}
// **** Bitstream reader ****
try {
boolean logJJ2000Messages = Boolean.getBoolean("jj2000.j2k.decoder.log");
breader =
BitstreamReaderAgent.createInstance(in, hd, j2krparam, decSpec, logJJ2000Messages, hi);
} catch (IOException e) {
throw new RuntimeException(
I18N.getString("J2KReadState3")
+ " "
+ ((e.getMessage() != null) ? (":\n" + e.getMessage()) : ""));
} catch (IllegalArgumentException e) {
throw new RuntimeException(
I18N.getString("J2KReadState4")
+ " "
+ ((e.getMessage() != null) ? (":\n" + e.getMessage()) : ""));
}
// **** Entropy decoder ****
try {
entdec = hd.createEntropyDecoder(breader, j2krparam);
} catch (IllegalArgumentException e) {
throw new RuntimeException(
I18N.getString("J2KReadState5")
+ " "
+ ((e.getMessage() != null) ? (":\n" + e.getMessage()) : ""));
}
// **** ROI de-scaler ****
try {
roids = hd.createROIDeScaler(entdec, j2krparam, decSpec);
} catch (IllegalArgumentException e) {
throw new RuntimeException(
I18N.getString("J2KReadState6")
+ " "
+ ((e.getMessage() != null) ? (":\n" + e.getMessage()) : ""));
}
// **** Dequantizer ****
try {
deq = hd.createDequantizer(roids, depth, decSpec);
} catch (IllegalArgumentException e) {
throw new RuntimeException(
I18N.getString("J2KReadState7")
+ " "
+ ((e.getMessage() != null) ? (":\n" + e.getMessage()) : ""));
}
// **** Inverse wavelet transform ***
try {
// full page inverse wavelet transform
invWT = InverseWT.createInstance(deq, decSpec);
} catch (IllegalArgumentException e) {
throw new RuntimeException(
I18N.getString("J2KReadState8")
+ " "
+ ((e.getMessage() != null) ? (":\n" + e.getMessage()) : ""));
}
int res = breader.getImgRes();
int mrl = decSpec.dls.getMin();
invWT.setImgResLevel(res);
// **** Data converter **** (after inverse transform module)
converter = new ImgDataConverter(invWT, 0);
// **** Inverse component transformation ****
ictransf = new InvCompTransf(converter, decSpec, depth);
// If the destination band is set used it
sourceBands = j2krparam.getSourceBands();
if (sourceBands == null) {
sourceBands = new int[nComp];
for (int i = 0; i < nComp; i++) sourceBands[i] = i;
}
nComp = sourceBands.length;
destinationBands = j2krparam.getDestinationBands();
if (destinationBands == null) {
destinationBands = new int[nComp];
for (int i = 0; i < nComp; i++) destinationBands[i] = i;
}
J2KImageReader.checkReadParamBandSettingsWrapper(
param, hd.getNumComps(), destinationBands.length);
levelShift = new int[nComp];
minValues = new int[nComp];
maxValues = new int[nComp];
fracBits = new int[nComp];
dataBlocks = new DataBlkInt[nComp];
depth = new int[nComp];
bandOffsets = new int[nComp];
maxDepth = 0;
isSigned = false;
for (int i = 0; i < nComp; i++) {
depth[i] = hd.getOriginalBitDepth(sourceBands[i]);
if (depth[i] > maxDepth) maxDepth = depth[i];
dataBlocks[i] = new DataBlkInt();
// XXX: may need to change if ChannelDefinition is used to
// define the color channels, such as BGR order
bandOffsets[i] = i;
if (hd.isOriginalSigned(sourceBands[i])) isSigned = true;
else {
levelShift[i] = 1 << (ictransf.getNomRangeBits(sourceBands[i]) - 1);
}
// Get the number of bits in the image, and decide what the max
// value should be, depending on whether it is signed or not
int nomRangeBits = ictransf.getNomRangeBits(sourceBands[i]);
maxValues[i] = (1 << (isSigned == true ? (nomRangeBits - 1) : nomRangeBits)) - 1;
minValues[i] = isSigned ? -(maxValues[i] + 1) : 0;
fracBits[i] = ictransf.getFixedPoint(sourceBands[i]);
}
iis.reset();
} catch (IllegalArgumentException e) {
throw new RuntimeException(e.getMessage(), e);
} catch (Error e) {
if (e.getMessage() != null) throw new RuntimeException(e.getMessage(), e);
else {
throw new RuntimeException(I18N.getString("J2KReadState9"), e);
}
} catch (RuntimeException e) {
if (e.getMessage() != null)
throw new RuntimeException(I18N.getString("J2KReadState10") + " " + e.getMessage(), e);
else {
throw new RuntimeException(I18N.getString("J2KReadState10"), e);
}
} catch (Throwable e) {
throw new RuntimeException(I18N.getString("J2KReadState10"), e);
}
}
public Raster getTile(int tileX, int tileY, WritableRaster raster) throws IOException {
Point nT = ictransf.getNumTiles(null);
if (noTransform) {
if (tileX >= nT.x || tileY >= nT.y)
throw new IllegalArgumentException(I18N.getString("J2KImageReader0"));
ictransf.setTile(tileX * tileStepX, tileY * tileStepY);
// The offset of the active tiles is the same for all components,
// since we don't support different component dimensions.
int tOffx;
int tOffy;
int cTileWidth;
int cTileHeight;
if (raster != null && (this.resolution < hd.getDecoderSpecs().dls.getMin())
|| stepX != 1
|| stepY != 1) {
tOffx = raster.getMinX();
tOffy = raster.getMinY();
cTileWidth = Math.min(raster.getWidth(), ictransf.getTileWidth());
cTileHeight = Math.min(raster.getHeight(), ictransf.getTileHeight());
} else {
tOffx =
ictransf.getCompULX(0)
- (ictransf.getImgULX() + ictransf.getCompSubsX(0) - 1) / ictransf.getCompSubsX(0)
+ destinationRegion.x;
tOffy =
ictransf.getCompULY(0)
- (ictransf.getImgULY() + ictransf.getCompSubsY(0) - 1) / ictransf.getCompSubsY(0)
+ destinationRegion.y;
cTileWidth = ictransf.getTileWidth();
cTileHeight = ictransf.getTileHeight();
}
if (raster == null)
raster = Raster.createWritableRaster(sampleModel, new Point(tOffx, tOffy));
int numBands = sampleModel.getNumBands();
if (tOffx + cTileWidth >= destinationRegion.width + destinationRegion.x)
cTileWidth = destinationRegion.width + destinationRegion.x - tOffx;
if (tOffy + cTileHeight >= destinationRegion.height + destinationRegion.y)
cTileHeight = destinationRegion.height + destinationRegion.y - tOffy;
// create the line buffer for pixel data if it is not large enough
// or null
if (pixbuf == null || pixbuf.length < cTileWidth * numBands)
pixbuf = new int[cTileWidth * numBands];
boolean prog = false;
// Deliver in lines to reduce memory usage
for (int l = 0; l < cTileHeight; l++) {
if (reader.getAbortRequest()) break;
// Request line data
for (int i = 0; i < numBands; i++) {
if (reader.getAbortRequest()) break;
DataBlkInt db = dataBlocks[i];
db.ulx = 0;
db.uly = l;
db.w = cTileWidth;
db.h = 1;
ictransf.getInternCompData(db, channelMap[sourceBands[i]]);
prog = prog || db.progressive;
int[] data = db.data;
int k1 = db.offset + cTileWidth - 1;
int fracBit = fracBits[i];
int lS = levelShift[i];
int min = minValues[i];
int max = maxValues[i];
if (ImageUtil.isBinary(sampleModel)) {
// Force min max to 0 and 1.
min = 0;
max = 1;
if (bytebuf == null || bytebuf.length < cTileWidth * numBands)
bytebuf = new byte[cTileWidth * numBands];
for (int j = cTileWidth - 1; j >= 0; j--) {
int tmp = (data[k1--] >> fracBit) + lS;
bytebuf[j] = (byte) ((tmp < min) ? min : ((tmp > max) ? max : tmp));
}
ImageUtil.setUnpackedBinaryData(
bytebuf, raster, new Rectangle(tOffx, tOffy + l, cTileWidth, 1));
} else {
for (int j = cTileWidth - 1; j >= 0; j--) {
int tmp = (data[k1--] >> fracBit) + lS;
pixbuf[j] = (tmp < min) ? min : ((tmp > max) ? max : tmp);
}
raster.setSamples(tOffx, tOffy + l, cTileWidth, 1, destinationBands[i], pixbuf);
}
}
}
} else {
readSubsampledRaster(raster);
}
return raster;
}