use of ar.com.hjg.pngj.ImageInfo in project xDrip by NightscoutFoundation.
the class SimpleImageEncoder method encodeIndexedPNG.
public byte[] encodeIndexedPNG(int[] pixels, int width, int height, boolean color, int bits) {
ByteArrayOutputStream bos = new ByteArrayOutputStream();
int[] palette = getPalette();
boolean alpha = Color.alpha(palette[0]) == 0;
boolean grayscale = !color;
// Log.d(TAG, "encodeIndexedPNG: color = "+color +", alpha ="+alpha+", grayscale = "+grayscale);
// ImageInfo imageInfo = new ImageInfo(width, height, bits, alpha, grayscale, color);
ImageInfo imageInfo = new ImageInfo(width, height, bits, false, grayscale, color);
PngWriter writer = new PngWriter(bos, imageInfo);
writer.getPixelsWriter().setDeflaterCompLevel(9);
if (color) {
PngChunkPLTE paletteChunk = writer.getMetadata().createPLTEChunk();
paletteChunk.setNentries(palette.length);
for (int i = 0; i < palette.length; i++) {
int c = palette[i];
paletteChunk.setEntry(i, Color.red(c), Color.green(c), Color.blue(c));
}
}
if (alpha) {
PngChunkTRNS trnsChunk = writer.getMetadata().createTRNSChunk();
if (color) {
trnsChunk.setIndexEntryAsTransparent(0);
} else {
trnsChunk.setGray(1);
}
} else {
quantize(pixels, imageInfo.cols);
}
ImageLineInt line = new ImageLineInt(imageInfo);
for (int y = 0; y < imageInfo.rows; y++) {
int[] lineData = line.getScanline();
for (int x = 0; x < imageInfo.cols; x++) {
int pixel = pixels[y * imageInfo.cols + x];
// lineData[x] = getNearestColorIndex(pixel) ^ (x % 2) ^ (y % 2);
lineData[x] = getNearestColorIndex(pixel);
}
writer.writeRow(line);
}
writer.end();
return bos.toByteArray();
}
use of ar.com.hjg.pngj.ImageInfo in project xDrip-plus by jamorham.
the class SimpleImageEncoder method encodeIndexedPNG.
public byte[] encodeIndexedPNG(int[] pixels, int width, int height, boolean color, int bits) {
ByteArrayOutputStream bos = new ByteArrayOutputStream();
int[] palette = getPalette();
boolean alpha = Color.alpha(palette[0]) == 0;
boolean grayscale = !color;
// Log.d(TAG, "encodeIndexedPNG: color = "+color +", alpha ="+alpha+", grayscale = "+grayscale);
// ImageInfo imageInfo = new ImageInfo(width, height, bits, alpha, grayscale, color);
ImageInfo imageInfo = new ImageInfo(width, height, bits, false, grayscale, color);
PngWriter writer = new PngWriter(bos, imageInfo);
writer.getPixelsWriter().setDeflaterCompLevel(9);
if (color) {
PngChunkPLTE paletteChunk = writer.getMetadata().createPLTEChunk();
paletteChunk.setNentries(palette.length);
for (int i = 0; i < palette.length; i++) {
int c = palette[i];
paletteChunk.setEntry(i, Color.red(c), Color.green(c), Color.blue(c));
}
}
if (alpha) {
PngChunkTRNS trnsChunk = writer.getMetadata().createTRNSChunk();
if (color) {
trnsChunk.setIndexEntryAsTransparent(0);
} else {
trnsChunk.setGray(1);
}
} else {
quantize(pixels, imageInfo.cols);
}
ImageLineInt line = new ImageLineInt(imageInfo);
for (int y = 0; y < imageInfo.rows; y++) {
int[] lineData = line.getScanline();
for (int x = 0; x < imageInfo.cols; x++) {
int pixel = pixels[y * imageInfo.cols + x];
// lineData[x] = getNearestColorIndex(pixel) ^ (x % 2) ^ (y % 2);
lineData[x] = getNearestColorIndex(pixel);
}
writer.writeRow(line);
}
writer.end();
return bos.toByteArray();
}
use of ar.com.hjg.pngj.ImageInfo in project OpenTripPlanner by opentripplanner.
the class TimeGridWs method getTimeGridPng.
@GET
@Produces({ "image/png" })
public Response getTimeGridPng(@QueryParam("base64") @DefaultValue("false") boolean base64) throws Exception {
/* Fetch the Router for this request using server and routerId fields from superclass. */
Router router = otpServer.getRouter(routerId);
if (precisionMeters < 10)
throw new IllegalArgumentException("Too small precisionMeters: " + precisionMeters);
if (offRoadDistanceMeters < 10)
throw new IllegalArgumentException("Too small offRoadDistanceMeters: " + offRoadDistanceMeters);
// Build the request
RoutingRequest sptRequest = buildRequest();
SampleGridRequest tgRequest = new SampleGridRequest();
tgRequest.maxTimeSec = maxTimeSec;
tgRequest.precisionMeters = precisionMeters;
tgRequest.offRoadDistanceMeters = offRoadDistanceMeters;
if (coordinateOrigin != null)
tgRequest.coordinateOrigin = new GenericLocation(null, coordinateOrigin).getCoordinate();
// Get a sample grid
ZSampleGrid<WTWD> sampleGrid = router.sampleGridRenderer.getSampleGrid(tgRequest, sptRequest);
int cols = sampleGrid.getXMax() - sampleGrid.getXMin() + 1;
int rows = sampleGrid.getYMax() - sampleGrid.getYMin() + 1;
// Hard-coded to RGBA
int channels = 4;
// We force to 8 bits channel depth, some clients won't support more than 8
// (namely, HTML5 canvas...)
ImageInfo imgInfo = new ImageInfo(cols, rows, 8, true, false, false);
/**
* TODO: PNGJ allow for progressive (ie line-by-line) writing. Thus we could theorically
* prevent having to allocate a bit pixel array in the first place, but we would need a
* line-by-line iterator on the sample grid, which is currently not the case.
*/
int[][] rgba = new int[rows][cols * channels];
ByteArrayOutputStream baos = new ByteArrayOutputStream();
PngWriter pw = new PngWriter(baos, imgInfo);
pw.getMetadata().setText(PngChunkTextVar.KEY_Software, "OTPA");
pw.getMetadata().setText(PngChunkTextVar.KEY_Creation_Time, new Date().toString());
pw.getMetadata().setText(PngChunkTextVar.KEY_Description, "Sample grid bitmap");
String gridCornerStr = String.format(Locale.US, "%.8f,%.8f", sampleGrid.getCenter().y + sampleGrid.getYMin() * sampleGrid.getCellSize().y, sampleGrid.getCenter().x + sampleGrid.getXMin() * sampleGrid.getCellSize().x);
String gridCellSzStr = String.format(Locale.US, "%.12f,%.12f", sampleGrid.getCellSize().y, sampleGrid.getCellSize().x);
String offRoadDistStr = String.format(Locale.US, "%d", offRoadDistanceMeters);
PngChunkTEXT gridCornerChunk = new PngChunkTEXT(imgInfo);
gridCornerChunk.setKeyVal(OTPA_GRID_CORNER, gridCornerStr);
pw.getChunksList().queue(gridCornerChunk);
PngChunkTEXT gridCellSzChunk = new PngChunkTEXT(imgInfo);
gridCellSzChunk.setKeyVal(OTPA_GRID_CELL_SIZE, gridCellSzStr);
pw.getChunksList().queue(gridCellSzChunk);
PngChunkTEXT offRoadDistChunk = new PngChunkTEXT(imgInfo);
offRoadDistChunk.setKeyVal(OTPA_OFFROAD_DIST, offRoadDistStr);
pw.getChunksList().queue(offRoadDistChunk);
double unit;
switch(zDataType) {
case TIME:
// 1:1sec, max 18h
unit = 1.0;
break;
case BOARDINGS:
// 1:0.001 boarding, max 65.5
unit = 1000.0;
break;
case WALK_DISTANCE:
// 1:0.1m, max 6.55km
unit = 10.0;
break;
default:
throw new IllegalArgumentException("Unsupported Z DataType.");
}
for (ZSamplePoint<WTWD> p : sampleGrid) {
WTWD z = p.getZ();
int row = p.getY() - sampleGrid.getYMin();
int col = p.getX() - sampleGrid.getXMin();
double zz;
switch(zDataType) {
case TIME:
zz = z.wTime / z.w;
break;
case BOARDINGS:
zz = z.wBoardings / z.w;
break;
case WALK_DISTANCE:
zz = z.wWalkDist / z.w;
break;
default:
throw new IllegalArgumentException("Unsupported Z DataType.");
}
int iz;
if (Double.isInfinite(zz)) {
iz = 65535;
} else {
iz = ImageLineHelper.clampTo_0_65535((int) Math.round(zz * unit));
if (iz == 65535)
// Clamp
iz = 65534;
}
// d is expressed as a percentage of grid size, max 255%.
// Sometimes d will be bigger than 2.55 x grid size,
// but this should not be too much important as we are off-bounds.
int id = ImageLineHelper.clampTo_0_255((int) Math.round(z.d / precisionMeters * 100));
int offset = col * channels;
// z low 8 bits
rgba[row][offset + 0] = (iz & 0xFF);
// z high 8 bits
rgba[row][offset + 1] = (iz >> 8);
// d
rgba[row][offset + 2] = id;
/*
* Keep the alpha channel at 255, otherwise the RGB channel will be downsampled on some
* rendering clients (namely, JS canvas).
*/
rgba[row][offset + 3] = 255;
}
for (int row = 0; row < rgba.length; row++) {
ImageLineInt iline = new ImageLineInt(imgInfo, rgba[row]);
pw.writeRow(iline, row);
}
pw.end();
// Disallow caching on client side
CacheControl cc = new CacheControl();
cc.setNoCache(true);
// Also put the meta-data in the HTML header (easier to read from JS)
byte[] data = baos.toByteArray();
if (base64) {
data = Base64.encodeBase64(data);
}
return Response.ok().cacheControl(cc).entity(data).header(OTPA_GRID_CORNER, gridCornerStr).header(OTPA_GRID_CELL_SIZE, gridCellSzStr).header(OTPA_OFFROAD_DIST, offRoadDistStr).build();
}
use of ar.com.hjg.pngj.ImageInfo in project BiomeTweaker by superckl.
the class BiomePainter method paintImage.
public void paintImage(final int radius, final ChunkPos center, final File outputFile, final GuiGeneratingBiomeLayoutImage gui) {
Arrays.fill(this.colorArray, -1);
final ImageInfo iInfo = new ImageInfo(radius * 2, radius * 2, 8, false);
final IImageLineFactory<ImageLineInt> factory = ImageLineInt.getFactory(iInfo);
final PngWriter writer = new PngWriter(outputFile, iInfo);
final int[] colors = new int[iInfo.cols];
final int currentX = center.x - iInfo.cols / 2;
final int currentY = center.z + iInfo.rows / 2;
for (int i = 0; i < iInfo.rows; i++) {
gui.setCurrentX(currentX + i);
for (int j = 0; j < colors.length; j++) {
gui.setCurrentY(currentY + j);
colors[j] = this.getColor(currentX + i, currentY + j);
}
final ImageLineInt line = factory.createImageLine(iInfo);
ImageLineHelper.setPixelsRGB8(line, colors);
writer.writeRow(line);
gui.setProgress(((double) i) / iInfo.rows);
}
writer.end();
gui.setFinished();
}
use of ar.com.hjg.pngj.ImageInfo in project imageio-ext by geosolutions-it.
the class PNGWriter method writePNG.
public RenderedImage writePNG(RenderedImage image, OutputStream outStream, float quality, FilterType filterType, Map<String, String> text) throws Exception {
// compute the compression level similarly to what the Clib code does
int level = Math.round(9 * (1f - quality));
// get the optimal scanline provider for this image
RenderedImage original = image;
ScanlineProvider scanlines = ScanlineProviderFactory.getProvider(image);
if (scanlines == null) {
throw new IllegalArgumentException("Could not find a scanline extractor for " + original);
}
// encode using the PNGJ library and the GeoServer own scanline providers
ColorModel colorModel = image.getColorModel();
boolean indexed = colorModel instanceof IndexColorModel;
ImageInfo ii = getImageInfo(image, scanlines, colorModel, indexed);
PngWriter pw = new PngWriter(outStream, ii);
pw.setShouldCloseStream(false);
try {
pw.setCompLevel(level);
pw.setFilterType(filterType);
ChunksListForWrite chunkList = pw.getChunksList();
PngMetadata metadata = pw.getMetadata();
if (indexed) {
IndexColorModel icm = (IndexColorModel) colorModel;
PngChunkPLTE palette = metadata.createPLTEChunk();
int ncolors = icm.getMapSize();
palette.setNentries(ncolors);
for (int i = 0; i < ncolors; i++) {
final int red = icm.getRed(i);
final int green = icm.getGreen(i);
final int blue = icm.getBlue(i);
palette.setEntry(i, red, green, blue);
}
if (icm.hasAlpha()) {
PngChunkTRNS transparent = new PngChunkTRNS(ii);
int[] alpha = new int[ncolors];
for (int i = 0; i < ncolors; i++) {
final int a = icm.getAlpha(i);
alpha[i] = a;
}
transparent.setPalletteAlpha(alpha);
chunkList.queue(transparent);
}
}
if (text != null && !text.isEmpty()) {
Iterator<Entry<String, String>> entrySetIterator = text.entrySet().iterator();
while (entrySetIterator.hasNext()) {
Entry<String, String> entrySet = entrySetIterator.next();
metadata.setText(entrySet.getKey(), entrySet.getValue(), true, false);
}
}
// write out the actual image lines
for (int row = 0; row < image.getHeight(); row++) {
pw.writeRow(scanlines);
}
pw.end();
} catch (Exception e) {
LOGGER.log(Level.SEVERE, "Failed to encode the PNG", e);
throw e;
} finally {
pw.close();
}
return image;
}
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