void lineToArea(ImagePlus imp) { Roi roi = imp.getRoi(); if (roi == null || !roi.isLine()) { IJ.error("Line to Area", "Line selection required"); return; } Undo.setup(Undo.ROI, imp); Roi roi2 = null; if (roi.getType() == Roi.LINE) { double width = roi.getStrokeWidth(); if (width <= 1.0) roi.setStrokeWidth(1.0000001); FloatPolygon p = roi.getFloatPolygon(); roi.setStrokeWidth(width); roi2 = new PolygonRoi(p, Roi.POLYGON); roi2.setDrawOffset(roi.getDrawOffset()); } else { ImageProcessor ip2 = new ByteProcessor(imp.getWidth(), imp.getHeight()); ip2.setColor(255); roi.drawPixels(ip2); // new ImagePlus("ip2", ip2.duplicate()).show(); ip2.setThreshold(255, 255, ImageProcessor.NO_LUT_UPDATE); ThresholdToSelection tts = new ThresholdToSelection(); roi2 = tts.convert(ip2); } transferProperties(roi, roi2); roi2.setStrokeWidth(0); Color c = roi2.getStrokeColor(); if (c != null) // remove any transparency roi2.setStrokeColor(new Color(c.getRed(), c.getGreen(), c.getBlue())); imp.setRoi(roi2); Roi.previousRoi = (Roi) roi.clone(); }
/** Generate output image whose type is same as input image. */ private ImagePlus makeOutputImage(ImagePlus imp, FloatProcessor fp, int ptype) { int width = imp.getWidth(); int height = imp.getHeight(); float[] pixels = (float[]) fp.getPixels(); ImageProcessor oip = null; // Create output image consistent w/ type of input image. int size = pixels.length; switch (ptype) { case BYTE_TYPE: oip = imp.getProcessor().createProcessor(width, height); byte[] pixels8 = (byte[]) oip.getPixels(); for (int i = 0; i < size; i++) pixels8[i] = (byte) pixels[i]; break; case SHORT_TYPE: oip = imp.getProcessor().createProcessor(width, height); short[] pixels16 = (short[]) oip.getPixels(); for (int i = 0; i < size; i++) pixels16[i] = (short) pixels[i]; break; case FLOAT_TYPE: oip = new FloatProcessor(width, height, pixels, null); break; } // Adjust for display. // Calling this on non-ByteProcessors ensures image // processor is set up to correctly display image. oip.resetMinAndMax(); // Create new image plus object. Don't use // ImagePlus.createImagePlus here because there may be // attributes of input image that are not appropriate for // projection. return new ImagePlus(makeTitle(), oip); }
void lineToArea(ImagePlus imp) { Roi roi = imp.getRoi(); if (roi == null || !roi.isLine()) { IJ.error("Line to Area", "Line selection required"); return; } if (roi.getType() == Roi.LINE && roi.getStrokeWidth() == 1) { IJ.error("Line to Area", "Straight line width must be > 1"); return; } ImageProcessor ip2 = new ByteProcessor(imp.getWidth(), imp.getHeight()); ip2.setColor(255); if (roi.getType() == Roi.LINE) ip2.fillPolygon(roi.getPolygon()); else { roi.drawPixels(ip2); // BufferedImage bi = new BufferedImage(imp.getWidth(), imp.getHeight(), // BufferedImage.TYPE_BYTE_GRAY); // Graphics g = bi.getGraphics(); // Roi roi2 = (Roi)roi.clone(); // roi2.setStrokeColor(Color.white); // roi2.drawOverlay(g); // ip2 = new ByteProcessor(bi); } // new ImagePlus("ip2", ip2.duplicate()).show(); ip2.setThreshold(255, 255, ImageProcessor.NO_LUT_UPDATE); ThresholdToSelection tts = new ThresholdToSelection(); Roi roi2 = tts.convert(ip2); imp.setRoi(roi2); Roi.previousRoi = (Roi) roi.clone(); }
void createEllipse(ImagePlus imp) { IJ.showStatus("Fitting ellipse"); Roi roi = imp.getRoi(); if (roi == null) { noRoi("Fit Ellipse"); return; } if (roi.isLine()) { IJ.error("Fit Ellipse", "\"Fit Ellipse\" does not work with line selections"); return; } ImageProcessor ip = imp.getProcessor(); ip.setRoi(roi); int options = Measurements.CENTROID + Measurements.ELLIPSE; ImageStatistics stats = ImageStatistics.getStatistics(ip, options, null); double dx = stats.major * Math.cos(stats.angle / 180.0 * Math.PI) / 2.0; double dy = -stats.major * Math.sin(stats.angle / 180.0 * Math.PI) / 2.0; double x1 = stats.xCentroid - dx; double x2 = stats.xCentroid + dx; double y1 = stats.yCentroid - dy; double y2 = stats.yCentroid + dy; double aspectRatio = stats.minor / stats.major; imp.killRoi(); imp.setRoi(new EllipseRoi(x1, y1, x2, y2, aspectRatio)); }
private ImagePlus duplicateImage(ImageProcessor iProcessor) { int w = iProcessor.getWidth(); int h = iProcessor.getHeight(); ImagePlus iPlus = NewImage.createByteImage("Image", w, h, 1, NewImage.FILL_BLACK); ImageProcessor imageProcessor = iPlus.getProcessor(); imageProcessor.copyBits(iProcessor, 0, 0, Blitter.COPY); return iPlus; }
void skeletonize(ImageProcessor ip) { if (Prefs.blackBackground) ip.invert(); boolean edgePixels = hasEdgePixels(ip); ImageProcessor ip2 = expand(ip, edgePixels); ((ByteProcessor) ip2).skeletonize(); ip = shrink(ip, ip2, edgePixels); if (Prefs.blackBackground) ip.invert(); }
ImageProcessor shrink(ImageProcessor ip, ImageProcessor ip2, boolean hasEdgePixels) { if (hasEdgePixels) { int width = ip.getWidth(); int height = ip.getHeight(); for (int y = 0; y < height; y++) for (int x = 0; x < width; x++) ip.putPixel(x, y, ip2.getPixel(x + 1, y + 1)); } return ip; }
/** Constructs a Wand object from an ImageProcessor. */ public Wand(ImageProcessor ip) { this.ip = ip; if (ip instanceof ByteProcessor) bpixels = (byte[]) ip.getPixels(); else if (ip instanceof ColorProcessor) cpixels = (int[]) ip.getPixels(); else if (ip instanceof ShortProcessor) spixels = (short[]) ip.getPixels(); else if (ip instanceof FloatProcessor) fpixels = (float[]) ip.getPixels(); width = ip.getWidth(); height = ip.getHeight(); }
/** Draws an outline of this OvalRoi on the image. */ public void drawPixels(ImageProcessor ip) { Polygon p = getPolygon(); if (p.npoints > 0) { int saveWidth = ip.getLineWidth(); if (getStrokeWidth() > 1f) ip.setLineWidth((int) Math.round(getStrokeWidth())); ip.drawPolygon(p); ip.setLineWidth(saveWidth); } if (Line.getWidth() > 1 || getStrokeWidth() > 1) updateFullWindow = true; }
void lineWidth() { int width = (int) IJ.getNumber("Line Width:", Line.getWidth()); if (width == IJ.CANCELED) return; Line.setWidth(width); LineWidthAdjuster.update(); ImagePlus imp = WindowManager.getCurrentImage(); if (imp != null && imp.isProcessor()) { ImageProcessor ip = imp.getProcessor(); ip.setLineWidth(Line.getWidth()); Roi roi = imp.getRoi(); if (roi != null && roi.isLine()) imp.draw(); } }
boolean setThresholdLevels(ImagePlus imp, ImageProcessor ip) { double t1 = ip.getMinThreshold(); double t2 = ip.getMaxThreshold(); boolean invertedLut = imp.isInvertedLut(); boolean byteImage = ip instanceof ByteProcessor; if (ip instanceof ShortProcessor) imageType = SHORT; else if (ip instanceof FloatProcessor) imageType = FLOAT; else imageType = BYTE; if (t1 == ImageProcessor.NO_THRESHOLD) { ImageStatistics stats = imp.getStatistics(); if (imageType != BYTE || (stats.histogram[0] + stats.histogram[255] != stats.pixelCount)) { IJ.error( "Particle Analyzer", "A thresholded image or 8-bit binary image is\n" + "required. Threshold levels can be set using\n" + "the Image->Adjust->Threshold tool."); canceled = true; return false; } boolean threshold255 = invertedLut; if (Prefs.blackBackground) threshold255 = !threshold255; if (threshold255) { level1 = 255; level2 = 255; fillColor = 64; } else { level1 = 0; level2 = 0; fillColor = 192; } } else { level1 = t1; level2 = t2; if (imageType == BYTE) { if (level1 > 0) fillColor = 0; else if (level2 < 255) fillColor = 255; } else if (imageType == SHORT) { if (level1 > 0) fillColor = 0; else if (level2 < 65535) fillColor = 65535; } else if (imageType == FLOAT) fillColor = -Float.MAX_VALUE; else return false; } imageType2 = imageType; if (redirectIP != null) { if (redirectIP instanceof ShortProcessor) imageType2 = SHORT; else if (redirectIP instanceof FloatProcessor) imageType2 = FLOAT; else if (redirectIP instanceof ColorProcessor) imageType2 = RGB; else imageType2 = BYTE; } return true; }
public void mousePressed(MouseEvent e) { // super.mousePressed(e); ImageProcessor ip = imp.getProcessor(); ip.setLineWidth(1); if (Toolbar.getToolId() == Toolbar.DROPPER) IJ.setTool(Toolbar.RECTANGLE); Rectangle flipperRect = new Rectangle(86, 268, 18, 18); Rectangle resetRect = new Rectangle(86, 294, 18, 18); Rectangle foreground1Rect = new Rectangle(9, 266, 45, 10); Rectangle foreground2Rect = new Rectangle(9, 276, 23, 25); Rectangle background1Rect = new Rectangle(33, 302, 45, 10); Rectangle background2Rect = new Rectangle(56, 277, 23, 25); int x = offScreenX(e.getX()); int y = offScreenY(e.getY()); long difference = System.currentTimeMillis() - mouseDownTime; boolean doubleClick = (difference <= 250); mouseDownTime = System.currentTimeMillis(); if (flipperRect.contains(x, y)) { Color c = Toolbar.getBackgroundColor(); Toolbar.setBackgroundColor(Toolbar.getForegroundColor()); Toolbar.setForegroundColor(c); } else if (resetRect.contains(x, y)) { Toolbar.setForegroundColor(new Color(0x000000)); Toolbar.setBackgroundColor(new Color(0xffffff)); } else if ((background1Rect.contains(x, y)) || (background2Rect.contains(x, y))) { background = true; if (doubleClick) editColor(); ((ColorGenerator) ip).refreshForeground(); ((ColorGenerator) ip).refreshBackground(); } else if ((foreground1Rect.contains(x, y)) || (foreground2Rect.contains(x, y))) { background = false; if (doubleClick) editColor(); ((ColorGenerator) ip).refreshBackground(); ((ColorGenerator) ip).refreshForeground(); } else { // IJ.log(" " + difference + " " + doubleClick); if (doubleClick) editColor(); else { setDrawingColor(offScreenX(e.getX()), offScreenY(e.getY()), background); } } if (ip instanceof ColorGenerator) { if (background) { ((ColorGenerator) ip).refreshForeground(); ((ColorGenerator) ip).refreshBackground(); } else { ((ColorGenerator) ip).refreshBackground(); ((ColorGenerator) ip).refreshForeground(); } } }
void drawOutline(ImageProcessor ip, Roi roi, int count) { if (showChoice == OVERLAY_OUTLINES || showChoice == OVERLAY_MASKS) { if (overlay == null) { overlay = new Overlay(); overlay.drawLabels(true); overlay.setLabelFont(new Font("SansSerif", Font.PLAIN, fontSize)); } Roi roi2 = (Roi) roi.clone(); roi2.setStrokeColor(Color.cyan); if (lineWidth != 1) roi2.setStrokeWidth(lineWidth); if (showChoice == OVERLAY_MASKS) roi2.setFillColor(Color.cyan); overlay.add(roi2); } else { Rectangle r = roi.getBounds(); int nPoints = ((PolygonRoi) roi).getNCoordinates(); int[] xp = ((PolygonRoi) roi).getXCoordinates(); int[] yp = ((PolygonRoi) roi).getYCoordinates(); int x = r.x, y = r.y; if (!inSituShow) ip.setValue(0.0); ip.moveTo(x + xp[0], y + yp[0]); for (int i = 1; i < nPoints; i++) ip.lineTo(x + xp[i], y + yp[i]); ip.lineTo(x + xp[0], y + yp[0]); if (showChoice != BARE_OUTLINES) { String s = ResultsTable.d2s(count, 0); ip.moveTo(r.x + r.width / 2 - ip.getStringWidth(s) / 2, r.y + r.height / 2 + fontSize / 2); if (!inSituShow) ip.setValue(1.0); ip.drawString(s); } } }
void reset(ImagePlus imp, ImageProcessor ip) { // Assign the pixels of ip to the data in the restore array, while // taking care to not give the address the restore array to the // image processor. int[] pixels = (int[]) ip.getPixels(); for (int i = 0; i < numPixels; i++) pixels[i] = restore[i]; }
/*------------------------------------------------------------------*/ void putRow(ImageProcessor ip, int y, double[] row) { int rowLength = ip.getWidth(); if (rowLength != row.length) { throw new IndexOutOfBoundsException("Incoherent array sizes"); } y *= rowLength; if (ip.getPixels() instanceof float[]) { float[] floatPixels = (float[]) ip.getPixels(); for (int i = 0; (i < rowLength); i++) { floatPixels[y++] = (float) row[i]; } } else { throw new IllegalArgumentException("Float image required"); } } /* end putRow */
/*------------------------------------------------------------------*/ void putColumn(ImageProcessor ip, int x, double[] column) { int width = ip.getWidth(); if (ip.getHeight() != column.length) { throw new IndexOutOfBoundsException("Incoherent array sizes"); } if (ip.getPixels() instanceof float[]) { float[] floatPixels = (float[]) ip.getPixels(); for (int i = 0; (i < column.length); i++) { floatPixels[x] = (float) column[i]; x += width; } } else { throw new IllegalArgumentException("Float image required"); } } /* end putColumn */
/** Opens a stack of images. */ ImagePlus openStack(ColorModel cm, boolean show) { ImageStack stack = new ImageStack(fi.width, fi.height, cm); long skip = fi.getOffset(); Object pixels; try { ImageReader reader = new ImageReader(fi); InputStream is = createInputStream(fi); if (is == null) return null; IJ.resetEscape(); for (int i = 1; i <= fi.nImages; i++) { if (!silentMode) IJ.showStatus("Reading: " + i + "/" + fi.nImages); if (IJ.escapePressed()) { IJ.beep(); IJ.showProgress(1.0); silentMode = false; return null; } pixels = reader.readPixels(is, skip); if (pixels == null) break; stack.addSlice(null, pixels); skip = fi.gapBetweenImages; if (!silentMode) IJ.showProgress(i, fi.nImages); } is.close(); } catch (Exception e) { IJ.log("" + e); } catch (OutOfMemoryError e) { IJ.outOfMemory(fi.fileName); stack.trim(); } if (!silentMode) IJ.showProgress(1.0); if (stack.getSize() == 0) return null; if (fi.sliceLabels != null && fi.sliceLabels.length <= stack.getSize()) { for (int i = 0; i < fi.sliceLabels.length; i++) stack.setSliceLabel(fi.sliceLabels[i], i + 1); } ImagePlus imp = new ImagePlus(fi.fileName, stack); if (fi.info != null) imp.setProperty("Info", fi.info); if (show) imp.show(); imp.setFileInfo(fi); setCalibration(imp); ImageProcessor ip = imp.getProcessor(); if (ip.getMin() == ip.getMax()) // find stack min and max if first slice is blank setStackDisplayRange(imp); if (!silentMode) IJ.showProgress(1.0); silentMode = false; return imp; }
void lineToArea(ImagePlus imp) { Roi roi = imp.getRoi(); if (roi == null || !roi.isLine()) { IJ.error("Line to Area", "Line selection required"); return; } ImageProcessor ip2 = new ByteProcessor(imp.getWidth(), imp.getHeight()); ip2.setColor(255); if (roi.getType() == Roi.LINE && roi.getStrokeWidth() > 1) ip2.fillPolygon(roi.getPolygon()); else roi.drawPixels(ip2); // new ImagePlus("ip2", ip2.duplicate()).show(); ip2.setThreshold(255, 255, ImageProcessor.NO_LUT_UPDATE); ThresholdToSelection tts = new ThresholdToSelection(); Roi roi2 = tts.convert(ip2); imp.setRoi(roi2); Roi.previousRoi = (Roi) roi.clone(); }
void setHistogram(ImagePlus imp, int j) { ImageProcessor ip = imp.getProcessor(); ImageStatistics stats = ImageStatistics.getStatistics(ip, AREA + MODE, null); int maxCount2 = 0; histogram = stats.histogram; for (int i = 0; i < stats.nBins; i++) if ((histogram[i] > maxCount2) && (i != stats.mode)) maxCount2 = histogram[i]; hmax = stats.maxCount; if ((hmax > (maxCount2 * 1.5)) && (maxCount2 != 0)) { // GL 1.5 was 2 hmax = (int) (maxCount2 * 1.1); // GL 1.1 was 1.5 histogram[stats.mode] = hmax; } os = null; ColorModel cm = ip.getColorModel(); if (!(cm instanceof IndexColorModel)) return; IndexColorModel icm = (IndexColorModel) cm; int mapSize = icm.getMapSize(); if (mapSize != 256) return; byte[] r = new byte[256]; byte[] g = new byte[256]; byte[] b = new byte[256]; icm.getReds(r); icm.getGreens(g); icm.getBlues(b); hColors = new Color[256]; if (isRGB) { if (j == 0) { for (int i = 0; i < 256; i++) hColors[i] = new Color(i & 255, 0 & 255, 0 & 255); } else if (j == 1) { for (int i = 0; i < 256; i++) hColors[i] = new Color(0 & 255, i & 255, 0 & 255); } else if (j == 2) { for (int i = 0; i < 256; i++) hColors[i] = new Color(0 & 255, 0 & 255, i & 255); } } else { if (j == 0) { for (int i = 0; i < 256; i++) hColors[i] = new Color(r[i] & 255, g[i] & 255, b[i] & 255); } else if (j == 1) { for (int i = 0; i < 256; i++) // hColors[i] = new Color(127-i/2&255, 127+i/2&255, 127-i/2&255); hColors[i] = new Color(192 - i / 4 & 255, 192 + i / 4 & 255, 192 - i / 4 & 255); } else if (j == 2) { for (int i = 0; i < 256; i++) hColors[i] = new Color(i & 255, i & 255, 0 & 255); } } }
void createMask(ImagePlus imp) { Roi roi = imp.getRoi(); boolean useInvertingLut = Prefs.useInvertingLut; Prefs.useInvertingLut = false; if (roi == null || !(roi.isArea() || roi.getType() == Roi.POINT)) { createMaskFromThreshold(imp); Prefs.useInvertingLut = useInvertingLut; return; } ImagePlus maskImp = null; Frame frame = WindowManager.getFrame("Mask"); if (frame != null && (frame instanceof ImageWindow)) maskImp = ((ImageWindow) frame).getImagePlus(); if (maskImp == null) { ImageProcessor ip = new ByteProcessor(imp.getWidth(), imp.getHeight()); if (!Prefs.blackBackground) ip.invertLut(); maskImp = new ImagePlus("Mask", ip); maskImp.show(); } ImageProcessor ip = maskImp.getProcessor(); ip.setRoi(roi); ip.setValue(255); ip.fill(ip.getMask()); maskImp.updateAndDraw(); Prefs.useInvertingLut = useInvertingLut; }
/** * Execute the plugin functionality: duplicate and scale the given image. * * @return an Object[] array with the name and the scaled ImagePlus. Does NOT show the new, image; * just returns it. */ public Object[] exec( ImagePlus imp, String myMethod, int radius, double par1, double par2, boolean doIwhite) { // 0 - Check validity of parameters if (null == imp) return null; ImageProcessor ip = imp.getProcessor(); int xe = ip.getWidth(); int ye = ip.getHeight(); // int [] data = (ip.getHistogram()); IJ.showStatus("Thresholding..."); long startTime = System.currentTimeMillis(); // 1 Do it if (imp.getStackSize() == 1) { ip.snapshot(); Undo.setup(Undo.FILTER, imp); } // Apply the selected algorithm if (myMethod.equals("Bernsen")) { Bernsen(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Contrast")) { Contrast(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Mean")) { Mean(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Median")) { Median(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("MidGrey")) { MidGrey(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Niblack")) { Niblack(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Otsu")) { Otsu(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Phansalkar")) { Phansalkar(imp, radius, par1, par2, doIwhite); } else if (myMethod.equals("Sauvola")) { Sauvola(imp, radius, par1, par2, doIwhite); } // IJ.showProgress((double)(255-i)/255); imp.updateAndDraw(); imp.getProcessor().setThreshold(255, 255, ImageProcessor.NO_LUT_UPDATE); // 2 - Return the threshold and the image IJ.showStatus("\nDone " + (System.currentTimeMillis() - startTime) / 1000.0); return new Object[] {imp}; }
/*------------------------------------------------------------------*/ public void getVerticalHessian(ImageProcessor ip, double tolerance) { if (!(ip.getPixels() instanceof float[])) { throw new IllegalArgumentException("Float image required"); } float[] floatPixels = (float[]) ip.getPixels(); int width = ip.getWidth(); int height = ip.getHeight(); double line[] = new double[height]; for (int x = 0; (x < width); x++) { getColumn(ip, x, line); getSplineInterpolationCoefficients(line, tolerance); getHessian(line); putColumn(ip, x, line); stepProgressBar(); } } /* end getVerticalHessian */
/*------------------------------------------------------------------*/ public void getHorizontalGradient(ImageProcessor ip, double tolerance) { if (!(ip.getPixels() instanceof float[])) { throw new IllegalArgumentException("Float image required"); } float[] floatPixels = (float[]) ip.getPixels(); int width = ip.getWidth(); int height = ip.getHeight(); double line[] = new double[width]; for (int y = 0; (y < height); y++) { getRow(ip, y, line); getSplineInterpolationCoefficients(line, tolerance); getGradient(line); putRow(ip, y, line); stepProgressBar(); } } /* end getHorizontalGradient */
// get a pixel value; returns Float.NaN if outside the field. private float getPixel(int x, int y) { if (x < 0 || x >= width || y < 0 || y >= height) return Float.NaN; if (bpixels != null) return bpixels[y * width + x] & 0xff; else if (spixels != null) return spixels[y * width + x] & 0xffff; else if (fpixels != null) return fpixels[y * width + x]; else if (exactPixelValue) // RGB for exact match return cpixels[y * width + x] & 0xffffff; // don't care for upper byte else // gray value of RGB return ip.getPixelValue(x, y); }
private String addMean(int column, String line, int start) { if (start == -1) { line += "\tNaN"; summaryHdr += "\t" + ResultsTable.getDefaultHeading(column); } else { float[] c = column >= 0 ? rt.getColumn(column) : null; if (c != null) { ImageProcessor ip = new FloatProcessor(c.length, 1, c, null); if (ip == null) return line; ip.setRoi(start, 0, ip.getWidth() - start, 1); ip = ip.crop(); ImageStatistics stats = new FloatStatistics(ip); if (stats == null) return line; line += n(stats.mean); } else line += "\tNaN"; summaryHdr += "\t" + rt.getColumnHeading(column); } return line; }
void createSelectionFromMask(ImagePlus imp) { ImageProcessor ip = imp.getProcessor(); if (ip.getMinThreshold() != ImageProcessor.NO_THRESHOLD) { IJ.runPlugIn("ij.plugin.filter.ThresholdToSelection", ""); return; } if (!ip.isBinary()) { IJ.error( "Create Selection", "This command creates a composite selection from\n" + "a mask (8-bit binary image with white background)\n" + "or from an image that has been thresholded using\n" + "the Image>Adjust>Threshold tool. The current\n" + "image is not a mask and has not been thresholded."); return; } int threshold = ip.isInvertedLut() ? 255 : 0; ip.setThreshold(threshold, threshold, ImageProcessor.NO_LUT_UPDATE); IJ.runPlugIn("ij.plugin.filter.ThresholdToSelection", ""); }
float[] getCurvature(float[] x, float[] y, int n) { float[] x2 = new float[n]; float[] y2 = new float[n]; for (int i = 0; i < n; i++) { x2[i] = x[i]; y2[i] = y[i]; } ImageProcessor ipx = new FloatProcessor(n, 1, x, null); ImageProcessor ipy = new FloatProcessor(n, 1, y, null); ipx.convolve(kernel, kernel.length, 1); ipy.convolve(kernel, kernel.length, 1); float[] indexes = new float[n]; float[] curvature = new float[n]; for (int i = 0; i < n; i++) { indexes[i] = i; curvature[i] = (float) Math.sqrt((x2[i] - x[i]) * (x2[i] - x[i]) + (y2[i] - y[i]) * (y2[i] - y[i])); } return curvature; }
ImagePlus duplicateStack(ImagePlus img1) { ImageStack stack1 = img1.getStack(); int width = stack1.getWidth(); int height = stack1.getHeight(); int n = stack1.getSize(); ImageStack stack2 = img1.createEmptyStack(); try { for (int i = 1; i <= n; i++) { ImageProcessor ip1 = stack1.getProcessor(i); ip1.resetRoi(); ImageProcessor ip2 = ip1.crop(); stack2.addSlice(stack1.getSliceLabel(i), ip2); } } catch (OutOfMemoryError e) { stack2.trim(); stack2 = null; return null; } return new ImagePlus("Duplicate", stack2); }
void avg_col(ImageProcessor ip) { float sum; // sum of pixel values column float avg; // average pixel value of a column float[] sliceavgs = new float[width]; // means across columns of one slice int sliceNumber = ip.getSliceNumber() - 1; // slice number for (int x = 0; x < width; x += 1) { sum = 0; // reset with each column avg = 0; // reset with each column for (int y = 0; y < height; y += 1) { sum = sum + ip.getPixelValue(x, y); } avg = sum / height; sliceavgs[x] = avg; // building array of means } this.slicecols[sliceNumber] = sliceavgs; // add this slice's means to array }
public void run(ImageProcessor ip) { int fg = Prefs.blackBackground ? 255 : 0; foreground = ip.isInvertedLut() ? 255 - fg : fg; background = 255 - foreground; ip.setSnapshotCopyMode(true); if (arg.equals("outline")) outline(ip); else if (arg.startsWith("fill")) fill(ip, foreground, background); else if (arg.startsWith("skel")) { ip.resetRoi(); skeletonize(ip); } else if (arg.equals("erode") || arg.equals("dilate")) doIterations((ByteProcessor) ip, arg); else if (arg.equals("open")) { doIterations(ip, "erode"); doIterations(ip, "dilate"); } else if (arg.equals("close")) { doIterations(ip, "dilate"); doIterations(ip, "erode"); } ip.setSnapshotCopyMode(false); ip.setBinaryThreshold(); }