public void run(ImageProcessor ip) { dimz = stack.getSize(); dimy = stack.getWidth(); dimx = stack.getHeight(); SaveDialog sd = new SaveDialog("Save Measurements as Text...", "res", ".dat"); String name = sd.getFileName(); if (name == null) return; String directory = sd.getDirectory(); nb = calculnb(stack); // -1; IJ.showStatus("Measure parameters for the " + nb + " objects ..."); if (nb < 1) { IJ.showMessage("volume must be labeled"); } else { double[] volume_m = new double[nb]; int[] volume_p = new int[nb]; double[] surface = new double[nb]; double[] surfacenb = new double[nb]; double[][][] I = new double[3][3][nb]; double[][] J = new double[3][nb]; double[][][] dir = new double[3][3][nb]; double[] xg = new double[nb]; double[] yg = new double[nb]; double[] zg = new double[nb]; byte[] bord = new byte[nb]; // double[] a = new double[nb]; // double[] b = new double[nb]; // double[] c = new double[nb]; // double[] Fab = new double[nb]; // double[] Fac = new double[nb]; // double[] Fbc = new double[nb]; // double[] sp = new double[nb]; double[][] lmin = new double[nb][3]; double[][] lmax = new double[nb][3]; IJ.showStatus("Measure surfaces ..."); calculmarchsurfstack(stack, nb, surface, volume_m); calculmarchsurfstacknb(stack, nb, surfacenb); // calculvolumestack(stack,nb,volume_p); IJ.showStatus("Measure volumes and inertia ..."); calculcgstack(stack, nb, volume_p, xg, yg, zg); calculinertiestack(stack, nb, xg, yg, zg, I); inertie(nb, I, J, dir); IJ.showStatus("Measure bounding boxes ..."); boitestack(stack, nb, xg, yg, zg, dir, lmin, lmax); borderstack(stack, nb, bord); IJ.showStatus("Save results ..."); sauvegarde( volume_p, volume_m, surface, surfacenb, xg, yg, zg, J, dir, nb, bord, lmin, lmax, directory, name); volume_m = null; volume_p = null; surface = null; xg = null; yg = null; zg = null; } }
void loadParticleResults(String filename, ResultsTable res) { try { String line; FileReader fr = new FileReader(filename); BufferedReader br = new BufferedReader(fr); java.lang.String header = " Intensity X (px) Y (px) X (nm) Y (nm) Z (nm) Left-Width(px) Right-Width (px) Up-Height (px) Down-Height (px) X Symmetry (%) Y Symmetry (%) Width minus Height (px) Frame Number"; java.lang.String firstline = br.readLine(); if (!firstline.contains("X (px) Y (px) X (nm) Y (nm) Z (nm)")) { IJ.error("File does not seam to be a Particles Table file"); IJ.log("Found header: " + firstline); IJ.log("Expecting: " + header); return; } res.reset(); int counter = 1; java.util.concurrent.locks.Lock lock = new java.util.concurrent.locks.ReentrantLock(); ThreadedLoader tloader = new ThreadedLoader(); // java.lang.String txt = fr.read(); while ((line = br.readLine()) != null) { tloader = new ThreadedLoader(); tloader.mysetup(res, lock, line); tloader.start(); IJ.showStatus("Loading particle " + counter + "... sit back and relax."); counter++; } try { tloader.join(); } catch (Exception e) { IJ.error("" + e); } if (res.getCounter() < 5000000) { IJ.showStatus("Creating particle table, this should take a few seconds..."); res.show("Results"); } else IJ.showMessage( "Warning", "Results table has too many particles, they will not be shown but the data still exists within it\nyou can still use all the plugin functionality or save table changes though the 'Save Particle Table' command."); fr.close(); IJ.showStatus("Done loading table..."); } catch (FileNotFoundException e) { IJ.error("File not found exception" + e); return; } catch (IOException e) { IJ.error("IOException exception" + e); return; } catch (NumberFormatException e) { IJ.error("Number format exception" + e); return; } }
protected void moveHandle(int sx, int sy) { if (clipboard != null) return; int ox = ic.offScreenX(sx); int oy = ic.offScreenY(sy); if (xpf != null) { double offset = getOffset(-0.5); xpf[activeHandle] = (float) (ic.offScreenXD(sx) - x + offset); ypf[activeHandle] = (float) (ic.offScreenYD(sy) - y + offset); } else { xp[activeHandle] = ox - x; yp[activeHandle] = oy - y; } if (xSpline != null) { fitSpline(splinePoints); updateClipRect(); imp.draw(clipX, clipY, clipWidth, clipHeight); oldX = x; oldY = y; oldWidth = width; oldHeight = height; } else { resetBoundingRect(); if (type == POINT && width == 0 && height == 0) { width = 1; height = 1; } updateClipRectAndDraw(); } String angle = type == ANGLE ? getAngleAsString() : ""; IJ.showStatus(imp.getLocationAsString(ox, oy) + angle); }
/** Overrides ImagePlus.show(). * */ public void show() { if (img == null && ip != null) img = ip.createImage(); ImageWindow.centerNextImage(); win = new ImageWindow(this, new ColorCanvas(this)); draw(); IJ.showStatus(""); }
void loadTransformation(String filename, ResultsTable res) { try { String line; FileReader fr = new FileReader(filename); BufferedReader br = new BufferedReader(fr); if (!br.readLine().equals(" Z-Step Raw Width minus Heigh Calibration Width minus Height")) { IJ.error("File does not seam to be an Astigmatism calibration file"); return; } // java.lang.String [] elements = new java.lang.String [3]; java.lang.String[] elements; int counter = 1; res.reset(); while ((line = br.readLine()) != null) { IJ.showStatus("Loading element " + counter + "... sit back and relax."); counter++; line.trim(); elements = line.split("\t"); res.incrementCounter(); res.addValue("Z-Step", Double.parseDouble(elements[1])); res.addValue("Raw Width minus Heigh", Double.parseDouble(elements[2])); res.addValue("Calibration Width minus Height", Double.parseDouble(elements[3])); } fr.close(); } catch (FileNotFoundException e) { IJ.error("File not found exception" + e); return; } catch (IOException e) { IJ.error("IOException exception" + e); return; } catch (NumberFormatException e) { IJ.error("Number format exception" + e); return; } }
public synchronized void adjustmentValueChanged(AdjustmentEvent e) { if (!checkImage()) { IJ.beep(); IJ.showStatus("No Image"); return; } if (e.getSource() == minSlider) { adjustMinHue((int) minSlider.getValue()); } else if (e.getSource() == maxSlider) { adjustMaxHue((int) maxSlider.getValue()); } else if (e.getSource() == minSlider2) { adjustMinSat((int) minSlider2.getValue()); } else if (e.getSource() == maxSlider2) { adjustMaxSat((int) maxSlider2.getValue()); } else if (e.getSource() == minSlider3) { adjustMinBri((int) minSlider3.getValue()); } else if (e.getSource() == maxSlider3) { adjustMaxBri((int) maxSlider3.getValue()); } originalB.setEnabled(true); updateLabels(); updatePlot(); notify(); }
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)); }
public void mouseMoved(MouseEvent e) { // if (ij==null) return; int sx = e.getX(); int sy = e.getY(); int ox = offScreenX(sx); int oy = offScreenY(sy); flags = e.getModifiers(); setCursor(sx, sy, ox, oy); IJ.setInputEvent(e); Roi roi = imp.getRoi(); if (roi != null && (roi.getType() == Roi.POLYGON || roi.getType() == Roi.POLYLINE || roi.getType() == Roi.ANGLE) && roi.getState() == roi.CONSTRUCTING) { PolygonRoi pRoi = (PolygonRoi) roi; pRoi.handleMouseMove(ox, oy); } else { if (ox < imageWidth && oy < imageHeight) { ImageWindow win = imp.getWindow(); // Cursor must move at least 12 pixels before text // displayed using IJ.showStatus() is overwritten. if ((sx - sx2) * (sx - sx2) + (sy - sy2) * (sy - sy2) > 144) showCursorStatus = true; if (win != null && showCursorStatus) win.mouseMoved(ox, oy); } else IJ.showStatus(""); } }
public void mouseExited(MouseEvent e) { // autoScroll(e); ImageWindow win = imp.getWindow(); if (win != null) setCursor(defaultCursor); IJ.showStatus(""); mouseExited = true; }
/** * 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}; }
void handleMouseMove(int sx, int sy) { // Do rubber banding int tool = Toolbar.getToolId(); if (!(tool == Toolbar.POLYGON || tool == Toolbar.POLYLINE || tool == Toolbar.ANGLE)) { imp.deleteRoi(); imp.draw(); return; } drawRubberBand(sx, sy); degrees = Double.NaN; double len = -1; if (nPoints > 1) { double x1, y1, x2, y2; if (xpf != null) { x1 = xpf[nPoints - 2]; y1 = ypf[nPoints - 2]; x2 = xpf[nPoints - 1]; y2 = ypf[nPoints - 1]; } else { x1 = xp[nPoints - 2]; y1 = yp[nPoints - 2]; x2 = xp[nPoints - 1]; y2 = yp[nPoints - 1]; } degrees = getAngle( (int) Math.round(x1), (int) Math.round(y1), (int) Math.round(x2), (int) Math.round(y2)); if (tool != Toolbar.ANGLE) { Calibration cal = imp.getCalibration(); double pw = cal.pixelWidth, ph = cal.pixelHeight; if (IJ.altKeyDown()) { pw = 1.0; ph = 1.0; } len = Math.sqrt((x2 - x1) * pw * (x2 - x1) * pw + (y2 - y1) * ph * (y2 - y1) * ph); } } if (tool == Toolbar.ANGLE) { if (nPoints == 2) angle1 = degrees; else if (nPoints == 3) { double angle2 = getAngle(xp[1], yp[1], xp[2], yp[2]); degrees = Math.abs(180 - Math.abs(angle1 - angle2)); if (degrees > 180.0) degrees = 360.0 - degrees; } } String length = len != -1 ? ", length=" + IJ.d2s(len) : ""; double degrees2 = tool == Toolbar.ANGLE && nPoints == 3 && Prefs.reflexAngle ? 360.0 - degrees : degrees; String angle = !Double.isNaN(degrees) ? ", angle=" + IJ.d2s(degrees2) : ""; int ox = ic != null ? ic.offScreenX(sx) : sx; int oy = ic != null ? ic.offScreenY(sy) : sy; IJ.showStatus(imp.getLocationAsString(ox, oy) + length + angle); }
void enlargeCanvas() { imp.unlock(); if (imp.getStackSize() == 1) Undo.setup(Undo.COMPOUND_FILTER, imp); IJ.run("Select All"); IJ.run("Rotate...", "angle=" + angle); Roi roi = imp.getRoi(); Rectangle r = roi.getBounds(); if (r.width < imp.getWidth()) r.width = imp.getWidth(); if (r.height < imp.getHeight()) r.height = imp.getHeight(); IJ.showStatus("Rotate: Enlarging..."); IJ.run( "Canvas Size...", "width=" + r.width + " height=" + r.height + " position=Center " + (fillWithBackground ? "" : "zero")); IJ.showStatus("Rotating..."); }
private boolean checkImage() { imp = WindowManager.getCurrentImage(); if (imp == null) { IJ.beep(); IJ.showStatus("No image"); return false; } ip = setup(imp); if (ip == null) return false; return true; }
public void run(String arg) { int[] wList = WindowManager.getIDList(); if (wList == null) { IJ.error("No images are open."); return; } double thalf = 0.5; boolean keep; GenericDialog gd = new GenericDialog("Bleach correction"); gd.addNumericField("t½:", thalf, 1); gd.addCheckbox("Keep source stack:", true); gd.showDialog(); if (gd.wasCanceled()) return; long start = System.currentTimeMillis(); thalf = gd.getNextNumber(); keep = gd.getNextBoolean(); if (keep) IJ.run("Duplicate...", "title='Bleach corrected' duplicate"); ImagePlus imp1 = WindowManager.getCurrentImage(); int d1 = imp1.getStackSize(); double v1, v2; int width = imp1.getWidth(); int height = imp1.getHeight(); ImageProcessor ip1, ip2, ip3; int slices = imp1.getStackSize(); ImageStack stack1 = imp1.getStack(); ImageStack stack2 = imp1.getStack(); int currentSlice = imp1.getCurrentSlice(); for (int n = 1; n <= slices; n++) { ip1 = stack1.getProcessor(n); ip3 = stack1.getProcessor(1); ip2 = stack2.getProcessor(n); for (int x = 0; x < width; x++) { for (int y = 0; y < height; y++) { v1 = ip1.getPixelValue(x, y); v2 = ip3.getPixelValue(x, y); // =B8/(EXP(-C$7*A8)) v1 = (v1 / Math.exp(-n * thalf)); ip2.putPixelValue(x, y, v1); } } IJ.showProgress((double) n / slices); IJ.showStatus(n + "/" + slices); } // stack2.show(); imp1.updateAndDraw(); }
/** Performs actual projection using specified method. */ public void doProjection() { if (imp == null) return; sliceCount = 0; if (method < AVG_METHOD || method > MEDIAN_METHOD) method = AVG_METHOD; for (int slice = startSlice; slice <= stopSlice; slice += increment) sliceCount++; if (method == MEDIAN_METHOD) { projImage = doMedianProjection(); return; } // Create new float processor for projected pixels. FloatProcessor fp = new FloatProcessor(imp.getWidth(), imp.getHeight()); ImageStack stack = imp.getStack(); RayFunction rayFunc = getRayFunction(method, fp); if (IJ.debugMode == true) { IJ.log("\nProjecting stack from: " + startSlice + " to: " + stopSlice); } // Determine type of input image. Explicit determination of // processor type is required for subsequent pixel // manipulation. This approach is more efficient than the // more general use of ImageProcessor's getPixelValue and // putPixel methods. int ptype; if (stack.getProcessor(1) instanceof ByteProcessor) ptype = BYTE_TYPE; else if (stack.getProcessor(1) instanceof ShortProcessor) ptype = SHORT_TYPE; else if (stack.getProcessor(1) instanceof FloatProcessor) ptype = FLOAT_TYPE; else { IJ.error("Z Project", "Non-RGB stack required"); return; } // Do the projection. for (int n = startSlice; n <= stopSlice; n += increment) { IJ.showStatus("ZProjection " + color + ": " + n + "/" + stopSlice); IJ.showProgress(n - startSlice, stopSlice - startSlice); projectSlice(stack.getPixels(n), rayFunc, ptype); } // Finish up projection. if (method == SUM_METHOD) { fp.resetMinAndMax(); projImage = new ImagePlus(makeTitle(), fp); } else if (method == SD_METHOD) { rayFunc.postProcess(); fp.resetMinAndMax(); projImage = new ImagePlus(makeTitle(), fp); } else { rayFunc.postProcess(); projImage = makeOutputImage(imp, fp, ptype); } if (projImage == null) IJ.error("Z Project", "Error computing projection."); }
void doIterations(ImageProcessor ip, String mode) { if (escapePressed) return; if (!previewing && iterations > 1) IJ.showStatus(arg + "... press ESC to cancel"); for (int i = 0; i < iterations; i++) { if (Thread.currentThread().isInterrupted()) return; if (IJ.escapePressed()) { escapePressed = true; ip.reset(); return; } if (mode.equals("erode")) ((ByteProcessor) ip).erode(count, background); else ((ByteProcessor) ip).dilate(count, background); } }
public void actionPerformed(ActionEvent e) { Button b = (Button) e.getSource(); if (b == null) return; boolean imageThere = checkImage(); if (imageThere) { if (b == originalB) { reset(imp, ip); filteredB.setEnabled(true); } else if (b == filteredB) { apply(imp, ip); } else if (b == sampleB) { reset(imp, ip); sample(); apply(imp, ip); } else if (b == stackB) { applyStack(); } else if (b == helpB) { IJ.showMessage( "Help", "Threshold Colour v1.0\n \n" + "Modification of Bob Dougherty's BandPass2 plugin by G.Landini to\n" + "threshold 24 bit RGB images based on Hue, Saturation and Brightness\n" + "or Red, Green and Blue components.\n \n" + "Pass: Band-pass filter (anything within range is displayed).\n \n" + "Stop: Band-reject filter (anything within range is NOT displayed).\n \n" + "Original: Shows the original image and updates the buffer when\n" + " switching to another image.\n \n" + "Filtered: Shows the filtered image.\n \n" + "Stack: Processes the rest of the slices in the stack (if any)\n" + " using the current settings.\n \n" + "Threshold: Shows the object/background in the foreground and\n" + " background colours selected in the ImageJ toolbar.\n \n" + "Invert: Swaps the fore/background colours.\n \n" + "Sample: (experimental) Sets the ranges of the filters based on the\n" + " pixel value componentd in a rectangular, user-defined, ROI.\n \n" + "HSB RGB: Selects HSB or RGB space and resets all the filters.\n \n" + "Note that the \'thresholded\' image is RGB, not 8 bit grey."); } updatePlot(); updateLabels(); imp.updateAndDraw(); } else { IJ.beep(); IJ.showStatus("No Image"); } notify(); }
void setStackDisplayRange(ImagePlus imp) { ImageStack stack = imp.getStack(); double min = Double.MAX_VALUE; double max = -Double.MAX_VALUE; int n = stack.getSize(); for (int i = 1; i <= n; i++) { if (!silentMode) IJ.showStatus("Calculating stack min and max: " + i + "/" + n); ImageProcessor ip = stack.getProcessor(i); ip.resetMinAndMax(); if (ip.getMin() < min) min = ip.getMin(); if (ip.getMax() > max) max = ip.getMax(); } imp.getProcessor().setMinAndMax(min, max); imp.updateAndDraw(); }
/** 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 createNewStack(ImagePlus imp, ImageProcessor ip) { int nSlices = imp.getStackSize(); int w = imp.getWidth(), h = imp.getHeight(); ImagePlus imp2 = imp.createImagePlus(); Rectangle r = ip.getRoi(); boolean crop = r.width != imp.getWidth() || r.height != imp.getHeight(); ImageStack stack1 = imp.getStack(); ImageStack stack2 = new ImageStack(newWidth, newHeight); ImageProcessor ip1, ip2; int method = interpolationMethod; if (w == 1 || h == 1) method = ImageProcessor.NONE; for (int i = 1; i <= nSlices; i++) { IJ.showStatus("Scale: " + i + "/" + nSlices); ip1 = stack1.getProcessor(i); String label = stack1.getSliceLabel(i); if (crop) { ip1.setRoi(r); ip1 = ip1.crop(); } ip1.setInterpolationMethod(method); ip2 = ip1.resize(newWidth, newHeight, averageWhenDownsizing); if (ip2 != null) stack2.addSlice(label, ip2); IJ.showProgress(i, nSlices); } imp2.setStack(title, stack2); Calibration cal = imp2.getCalibration(); if (cal.scaled()) { cal.pixelWidth *= 1.0 / xscale; cal.pixelHeight *= 1.0 / yscale; } IJ.showProgress(1.0); int[] dim = imp.getDimensions(); imp2.setDimensions(dim[2], dim[3], dim[4]); if (imp.isComposite()) { imp2 = new CompositeImage(imp2, ((CompositeImage) imp).getMode()); ((CompositeImage) imp2).copyLuts(imp); } if (imp.isHyperStack()) imp2.setOpenAsHyperStack(true); if (newDepth > 0 && newDepth != oldDepth) imp2 = (new Resizer()).zScale(imp2, newDepth, interpolationMethod); if (imp2 != null) { imp2.show(); imp2.changes = true; } }
void applyStack() { // int minKeepH = minHue, maxKeepH = maxHue; //GL not needed? // int minKeepS = minSat, maxKeepS = maxSat; // int minKeepB = minBri, maxKeepB = maxBri; for (int i = 1; i <= numSlices; i++) { imp.setSlice(i); if (!checkImage()) { IJ.beep(); IJ.showStatus("No Image"); return; } // minHue = minKeepH; // maxHue = maxKeepH; // minSat = minKeepS; // maxSat = maxKeepS; // minBri = minKeepB; // maxBri = maxKeepB; apply(imp, ip); } }
protected void setDrawingColor(int ox, int oy, boolean setBackground) { // IJ.log("setDrawingColor: "+setBackground+this); int type = imp.getType(); int[] v = imp.getPixel(ox, oy); switch (type) { case ImagePlus.GRAY8: { if (setBackground) setBackgroundColor(getColor(v[0])); else setForegroundColor(getColor(v[0])); break; } case ImagePlus.GRAY16: case ImagePlus.GRAY32: { double min = imp.getProcessor().getMin(); double max = imp.getProcessor().getMax(); double value = (type == ImagePlus.GRAY32) ? Float.intBitsToFloat(v[0]) : v[0]; int index = (int) (255.0 * ((value - min) / (max - min))); if (index < 0) index = 0; if (index > 255) index = 255; if (setBackground) setBackgroundColor(getColor(index)); else setForegroundColor(getColor(index)); break; } case ImagePlus.COLOR_RGB: case ImagePlus.COLOR_256: { Color c = new Color(v[0], v[1], v[2]); if (setBackground) setBackgroundColor(c); else setForegroundColor(c); break; } } Color c; if (setBackground) c = Toolbar.getBackgroundColor(); else { c = Toolbar.getForegroundColor(); imp.setColor(c); } IJ.showStatus("(" + c.getRed() + ", " + c.getGreen() + ", " + c.getBlue() + ")"); }
void createNewStack(ImagePlus imp, ImageProcessor ip) { Rectangle r = ip.getRoi(); boolean crop = r.width != imp.getWidth() || r.height != imp.getHeight(); int nSlices = imp.getStackSize(); ImageStack stack1 = imp.getStack(); ImageStack stack2 = new ImageStack(newWidth, newHeight); ImageProcessor ip1, ip2; boolean interp = interpolate; if (imp.getWidth() == 1 || imp.getHeight() == 1) interp = false; for (int i = 1; i <= nSlices; i++) { IJ.showStatus("Scale: " + i + "/" + nSlices); ip1 = stack1.getProcessor(i); String label = stack1.getSliceLabel(i); if (crop) { ip1.setRoi(r); ip1 = ip1.crop(); } ip1.setInterpolate(interp); ip2 = ip1.resize(newWidth, newHeight); if (ip2 != null) stack2.addSlice(label, ip2); IJ.showProgress(i, nSlices); } ImagePlus imp2 = imp.createImagePlus(); imp2.setStack(title, stack2); Calibration cal = imp2.getCalibration(); if (cal.scaled()) { cal.pixelWidth *= 1.0 / xscale; cal.pixelHeight *= 1.0 / yscale; } int[] dim = imp.getDimensions(); imp2.setDimensions(dim[2], dim[3], dim[4]); IJ.showProgress(1.0); if (imp.isComposite()) { imp2 = new CompositeImage(imp2, 0); ((CompositeImage) imp2).copyLuts(imp); } if (imp.isHyperStack()) imp2.setOpenAsHyperStack(true); imp2.show(); imp2.changes = true; }
public boolean dialogItemChanged(GenericDialog gd, AWTEvent e) { int width = imp.getWidth(); int height = imp.getHeight(); type = gd.getNextChoice(); areaPerPoint = gd.getNextNumber(); color = gd.getNextChoice(); randomOffset = gd.getNextBoolean(); double minArea = (width * height) / 50000.0; if (type.equals(types[1]) && minArea < 144.0) minArea = 144.0; else if (minArea < 16) minArea = 16.0; if (areaPerPoint / (pixelWidth * pixelHeight) < minArea) { String err = "\"Area per Point\" too small"; if (gd.wasOKed()) IJ.error("Grid", err); else IJ.showStatus(err); return true; } double tileSize = Math.sqrt(areaPerPoint); tileWidth = tileSize / pixelWidth; tileHeight = tileSize / pixelHeight; if (randomOffset) { xstart = (int) (random.nextDouble() * tileWidth); ystart = (int) (random.nextDouble() * tileHeight); } else { xstart = (int) (tileWidth / 2.0 + 0.5); ystart = (int) (tileHeight / 2.0 + 0.5); } linesV = (int) ((width - xstart) / tileWidth) + 1; linesH = (int) ((height - ystart) / tileHeight) + 1; if (gd.invalidNumber()) return true; if (type.equals(types[0])) drawLines(); else if (type.equals(types[1])) drawCrosses(); else if (type.equals(types[2])) drawPoints(); else showGrid(null); return true; }
/** * Reduce error in thickness quantitation by trimming the one pixel overhang in the thickness map * * @param imp Binary input image * @param impLTC Thickness map * @param inv true if calculating thickness of background, false for foreground * @return Thickness map with pixels masked by input image */ private ImagePlus trimOverhang(ImagePlus imp, ImagePlus impLTC, boolean inv) { final int w = imp.getWidth(); final int h = imp.getHeight(); final int d = imp.getImageStackSize(); final ImageStack stack = imp.getImageStack(); final ImageStack mapStack = impLTC.getImageStack(); final int keepValue = inv ? 0 : 255; ImageProcessor ip = new ByteProcessor(w, h); ImageProcessor map = new FloatProcessor(w, h); for (int z = 1; z <= d; z++) { IJ.showStatus("Masking thickness map..."); IJ.showProgress(z, d); ip = stack.getProcessor(z); map = mapStack.getProcessor(z); for (int y = 0; y < h; y++) { for (int x = 0; x < w; x++) { if (ip.get(x, y) != keepValue) map.set(x, y, 0); } } } return impLTC; }
ImagePlus doMedianProjection() { IJ.showStatus("Calculating median..."); ImageStack stack = imp.getStack(); ImageProcessor[] slices = new ImageProcessor[sliceCount]; int index = 0; for (int slice = startSlice; slice <= stopSlice; slice += increment) slices[index++] = stack.getProcessor(slice); ImageProcessor ip2 = slices[0].duplicate(); ip2 = ip2.convertToFloat(); float[] values = new float[sliceCount]; int width = ip2.getWidth(); int height = ip2.getHeight(); int inc = Math.max(height / 30, 1); for (int y = 0; y < height; y++) { if (y % inc == 0) IJ.showProgress(y, height - 1); for (int x = 0; x < width; x++) { for (int i = 0; i < sliceCount; i++) values[i] = slices[i].getPixelValue(x, y); ip2.putPixelValue(x, y, median(values)); } } if (imp.getBitDepth() == 8) ip2 = ip2.convertToByte(false); IJ.showProgress(1, 1); return new ImagePlus(makeTitle(), ip2); }
/** Restores original disk or network version of image. */ public void revertToSaved(ImagePlus imp) { Image img; ProgressBar pb = IJ.getInstance().getProgressBar(); ImageProcessor ip; String path = fi.directory + fi.fileName; if (fi.fileFormat == fi.GIF_OR_JPG) { // restore gif or jpg img = Toolkit.getDefaultToolkit().createImage(path); imp.setImage(img); if (imp.getType() == ImagePlus.COLOR_RGB) Opener.convertGrayJpegTo8Bits(imp); return; } if (fi.fileFormat == fi.DICOM) { // restore DICOM ImagePlus imp2 = (ImagePlus) IJ.runPlugIn("ij.plugin.DICOM", path); if (imp2 != null) imp.setProcessor(null, imp2.getProcessor()); return; } if (fi.fileFormat == fi.BMP) { // restore BMP ImagePlus imp2 = (ImagePlus) IJ.runPlugIn("ij.plugin.BMP_Reader", path); if (imp2 != null) imp.setProcessor(null, imp2.getProcessor()); return; } if (fi.fileFormat == fi.PGM) { // restore PGM ImagePlus imp2 = (ImagePlus) IJ.runPlugIn("ij.plugin.PGM_Reader", path); if (imp2 != null) imp.setProcessor(null, imp2.getProcessor()); return; } if (fi.fileFormat == fi.ZIP_ARCHIVE) { // restore ".zip" file ImagePlus imp2 = (new Opener()).openZip(path); if (imp2 != null) imp.setProcessor(null, imp2.getProcessor()); return; } // restore PNG or another image opened using ImageIO if (fi.fileFormat == fi.IMAGEIO) { ImagePlus imp2 = (new Opener()).openUsingImageIO(path); if (imp2 != null) imp.setProcessor(null, imp2.getProcessor()); return; } if (fi.nImages > 1) return; ColorModel cm; if (fi.url == null || fi.url.equals("")) IJ.showStatus("Loading: " + path); else IJ.showStatus("Loading: " + fi.url + fi.fileName); Object pixels = readPixels(fi); if (pixels == null) return; cm = createColorModel(fi); switch (fi.fileType) { case FileInfo.GRAY8: case FileInfo.COLOR8: case FileInfo.BITMAP: ip = new ByteProcessor(width, height, (byte[]) pixels, cm); imp.setProcessor(null, ip); break; case FileInfo.GRAY16_SIGNED: case FileInfo.GRAY16_UNSIGNED: case FileInfo.GRAY12_UNSIGNED: ip = new ShortProcessor(width, height, (short[]) pixels, cm); imp.setProcessor(null, ip); break; case FileInfo.GRAY32_INT: case FileInfo.GRAY32_FLOAT: ip = new FloatProcessor(width, height, (float[]) pixels, cm); imp.setProcessor(null, ip); break; case FileInfo.RGB: case FileInfo.BGR: case FileInfo.ARGB: case FileInfo.ABGR: case FileInfo.RGB_PLANAR: img = Toolkit.getDefaultToolkit() .createImage(new MemoryImageSource(width, height, (int[]) pixels, 0, width)); imp.setImage(img); break; } }
private void fitglobal() { int nparams = 11; int nsel = 0; for (int i = 0; i < ncurves; i++) { if (include[i]) { nsel++; } } double[][] params = new double[nsel][nparams]; String[][] tempformulas = new String[nsel][nparams]; double[][][] constraints = new double[2][nsel][nparams]; int[][] vflmatrix = new int[nsel][nparams]; int counter = 0; for (int i = 0; i < ncurves; i++) { if (include[i]) { for (int j = 0; j < nparams; j++) { params[counter][j] = globalparams[i][j]; tempformulas[counter][j] = globalformulas[i][j]; constraints[0][counter][j] = globalconstraints[0][i][j]; constraints[1][counter][j] = globalconstraints[1][i][j]; vflmatrix[counter][j] = globalvflmatrix[i][j]; } counter++; } for (int j = 0; j < nparams; j++) { undoparams[i][j] = globalparams[i][j]; undoformulas[i][j] = globalformulas[i][j]; undovflmatrix[i][j] = globalvflmatrix[i][j]; } for (int j = 0; j < xpts; j++) { for (int k = 0; k < ypts; k++) { undofit[i][j][k] = fit[i][j][k]; } } undoc2[i] = c2[i]; } undoglobalc2 = globalc2; if (showglobalfitdialog(params, tempformulas, vflmatrix)) { counter = 0; for (int i = 0; i < ncurves; i++) { if (include[i]) { for (int j = 0; j < nparams; j++) { globalparams[i][j] = params[counter][j]; globalformulas[i][j] = tempformulas[counter][j]; globalvflmatrix[i][j] = vflmatrix[counter][j]; } counter++; } } double[] stats = new double[2]; float[][] tempdata = new float[nsel][xpts * ypts]; float[][] tempweights = new float[nsel][xpts * ypts]; counter = 0; for (int i = 0; i < ncurves; i++) { if (include[i]) { for (int j = 0; j < xpts; j++) { for (int k = 0; k < ypts; k++) { tempdata[counter][j + k * xpts] = (float) ((double) pch[i][j][k] / (double) nmeas[i]); tempweights[counter][j + k * xpts] = weights[i][j][k]; } } counter++; } } int tempmaxiter = globalfitclass.maxiter; if (checkc2) { globalfitclass.changemaxiter(0); } double[] tempc2vals = new double[nsel]; IJ.showStatus("Fitting Globally"); float[][] tempfit = globalfitclass.fitdata( params, vflmatrix, tempformulas, paramsnames, constraints, tempdata, tempweights, stats, tempc2vals, false); IJ.showStatus("Fit Complete"); globalfitclass.changemaxiter(tempmaxiter); globalc2 = stats[1]; globalc2label.setText("Global chi^2 = " + (float) globalc2); counter = 0; for (int i = 0; i < ncurves; i++) { if (include[i]) { for (int j = 0; j < xpts; j++) { for (int k = 0; k < ypts; k++) { fit[i][j][k] = tempfit[counter][j + xpts * k] * (float) nmeas[i]; } } if (i == dispcurve) { pwfit.updateSeries(fit[dispcurve], 1, true); } for (int j = 0; j < nparams; j++) { globalparams[i][j] = params[counter][j]; } c2[i] = tempc2vals[counter]; c2array[i].setText("" + (float) c2[i]); counter++; } } float[] temp = pwfit.getLimits(); temp[4] = 1.0f; pwfit.setLimits(temp); } }
public void showresults(String results) { IJ.showStatus(results); IJ.log(results); }
public void mousePressed(MouseEvent e) { Undo.reset(); if (!Prefs.noClickToGC) System.gc(); IJ.showStatus(version() + IJ.freeMemory()); if (IJ.debugMode) IJ.log("Windows: " + WindowManager.getWindowCount()); }