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; } }
/** Handle menu events. */ public void actionPerformed(ActionEvent e) { if ((e.getSource() instanceof MenuItem)) { MenuItem item = (MenuItem) e.getSource(); String cmd = e.getActionCommand(); commandName = cmd; ImagePlus imp = null; if (item.getParent() == Menus.getOpenRecentMenu()) { new RecentOpener(cmd); // open image in separate thread return; } else if (item.getParent() == Menus.getPopupMenu()) { Object parent = Menus.getPopupMenu().getParent(); if (parent instanceof ImageCanvas) imp = ((ImageCanvas) parent).getImage(); } int flags = e.getModifiers(); hotkey = false; actionPerformedTime = System.currentTimeMillis(); long ellapsedTime = actionPerformedTime - keyPressedTime; if (cmd != null && (ellapsedTime >= 200L || !cmd.equals(lastKeyCommand))) { if ((flags & Event.ALT_MASK) != 0) IJ.setKeyDown(KeyEvent.VK_ALT); if ((flags & Event.SHIFT_MASK) != 0) IJ.setKeyDown(KeyEvent.VK_SHIFT); new Executer(cmd, imp); } lastKeyCommand = null; if (IJ.debugMode) IJ.log("actionPerformed: time=" + ellapsedTime + ", " + e); } }
void Bernsen(ImagePlus imp, int radius, double par1, double par2, boolean doIwhite) { // Bernsen recommends WIN_SIZE = 31 and CONTRAST_THRESHOLD = 15. // 1) Bernsen J. (1986) "Dynamic Thresholding of Grey-Level Images" // Proc. of the 8th Int. Conf. on Pattern Recognition, pp. 1251-1255 // 2) Sezgin M. and Sankur B. (2004) "Survey over Image Thresholding // Techniques and Quantitative Performance Evaluation" Journal of // Electronic Imaging, 13(1): 146-165 // http://citeseer.ist.psu.edu/sezgin04survey.html // Ported to ImageJ plugin from E Celebi's fourier_0.8 routines // This version uses a circular local window, instead of a rectagular one ImagePlus Maximp, Minimp; ImageProcessor ip = imp.getProcessor(), ipMax, ipMin; int contrast_threshold = 15; int local_contrast; int mid_gray; byte object; byte backg; int temp; if (par1 != 0) { IJ.log("Bernsen: changed contrast_threshold from :" + contrast_threshold + " to:" + par1); contrast_threshold = (int) par1; } if (doIwhite) { object = (byte) 0xff; backg = (byte) 0; } else { object = (byte) 0; backg = (byte) 0xff; } Maximp = duplicateImage(ip); ipMax = Maximp.getProcessor(); RankFilters rf = new RankFilters(); rf.rank(ipMax, radius, rf.MAX); // Maximum // Maximp.show(); Minimp = duplicateImage(ip); ipMin = Minimp.getProcessor(); rf.rank(ipMin, radius, rf.MIN); // Minimum // Minimp.show(); byte[] pixels = (byte[]) ip.getPixels(); byte[] max = (byte[]) ipMax.getPixels(); byte[] min = (byte[]) ipMin.getPixels(); for (int i = 0; i < pixels.length; i++) { local_contrast = (int) ((max[i] & 0xff) - (min[i] & 0xff)); mid_gray = (int) ((min[i] & 0xff) + (max[i] & 0xff)) / 2; temp = (int) (pixels[i] & 0x0000ff); if (local_contrast < contrast_threshold) pixels[i] = (mid_gray >= 128) ? object : backg; // Low contrast region else pixels[i] = (temp >= mid_gray) ? object : backg; } // imp.updateAndDraw(); return; }
/** 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."); }
boolean setProperties(String title, Roi roi) { Frame f = WindowManager.getFrontWindow(); if (f != null && f.getTitle().indexOf("3D Viewer") != -1) return false; if (roi == null) { IJ.error("This command requires a selection."); return false; } RoiProperties rp = new RoiProperties(title, roi); boolean ok = rp.showDialog(); if (IJ.debugMode) IJ.log(roi.getDebugInfo()); return ok; }
void MidGrey(ImagePlus imp, int radius, double par1, double par2, boolean doIwhite) { // See: Image Processing Learning Resourches HIPR2 // http://homepages.inf.ed.ac.uk/rbf/HIPR2/adpthrsh.htm ImagePlus Maximp, Minimp; ImageProcessor ip = imp.getProcessor(), ipMax, ipMin; int c_value = 0; int mid_gray; byte object; byte backg; if (par1 != 0) { IJ.log("MidGrey: changed c_value from :" + c_value + " to:" + par1); c_value = (int) par1; } if (doIwhite) { object = (byte) 0xff; backg = (byte) 0; } else { object = (byte) 0; backg = (byte) 0xff; } Maximp = duplicateImage(ip); ipMax = Maximp.getProcessor(); RankFilters rf = new RankFilters(); rf.rank(ipMax, radius, rf.MAX); // Maximum // Maximp.show(); Minimp = duplicateImage(ip); ipMin = Minimp.getProcessor(); rf.rank(ipMin, radius, rf.MIN); // Minimum // Minimp.show(); byte[] pixels = (byte[]) ip.getPixels(); byte[] max = (byte[]) ipMax.getPixels(); byte[] min = (byte[]) ipMin.getPixels(); for (int i = 0; i < pixels.length; i++) { pixels[i] = ((int) (pixels[i] & 0xff) > (int) (((max[i] & 0xff) + (min[i] & 0xff)) / 2) - c_value) ? object : backg; } // imp.updateAndDraw(); return; }
public void keyTyped(KeyEvent e) { char keyChar = e.getKeyChar(); int flags = e.getModifiers(); if (IJ.debugMode) IJ.log( "keyTyped: char=\"" + keyChar + "\" (" + (int) keyChar + "), flags= " + Integer.toHexString(flags) + " (" + KeyEvent.getKeyModifiersText(flags) + ")"); if (keyChar == '\\' || keyChar == 171 || keyChar == 223) { if (((flags & Event.ALT_MASK) != 0)) doCommand("Animation Options..."); else doCommand("Start Animation [\\]"); } }
void Mean(ImagePlus imp, int radius, double par1, double par2, boolean doIwhite) { // See: Image Processing Learning Resourches HIPR2 // http://homepages.inf.ed.ac.uk/rbf/HIPR2/adpthrsh.htm ImagePlus Meanimp; ImageProcessor ip = imp.getProcessor(), ipMean; int c_value = 0; byte object; byte backg; if (par1 != 0) { IJ.log("Mean: changed c_value from :" + c_value + " to:" + par1); c_value = (int) par1; } if (doIwhite) { object = (byte) 0xff; backg = (byte) 0; } else { object = (byte) 0; backg = (byte) 0xff; } Meanimp = duplicateImage(ip); ImageConverter ic = new ImageConverter(Meanimp); ic.convertToGray32(); ipMean = Meanimp.getProcessor(); RankFilters rf = new RankFilters(); rf.rank(ipMean, radius, rf.MEAN); // Mean // Meanimp.show(); byte[] pixels = (byte[]) ip.getPixels(); float[] mean = (float[]) ipMean.getPixels(); for (int i = 0; i < pixels.length; i++) pixels[i] = ((int) (pixels[i] & 0xff) > (int) (mean[i] - c_value)) ? object : backg; // imp.updateAndDraw(); return; }
public void keyPressed(KeyEvent e) { // if (e.isConsumed()) return; int keyCode = e.getKeyCode(); IJ.setKeyDown(keyCode); hotkey = false; if (keyCode == KeyEvent.VK_CONTROL || keyCode == KeyEvent.VK_SHIFT) return; char keyChar = e.getKeyChar(); int flags = e.getModifiers(); if (IJ.debugMode) IJ.log( "keyPressed: code=" + keyCode + " (" + KeyEvent.getKeyText(keyCode) + "), char=\"" + keyChar + "\" (" + (int) keyChar + "), flags=" + KeyEvent.getKeyModifiersText(flags)); boolean shift = (flags & KeyEvent.SHIFT_MASK) != 0; boolean control = (flags & KeyEvent.CTRL_MASK) != 0; boolean alt = (flags & KeyEvent.ALT_MASK) != 0; boolean meta = (flags & KeyEvent.META_MASK) != 0; String cmd = null; ImagePlus imp = WindowManager.getCurrentImage(); boolean isStack = (imp != null) && (imp.getStackSize() > 1); if (imp != null && !control && ((keyChar >= 32 && keyChar <= 255) || keyChar == '\b' || keyChar == '\n')) { Roi roi = imp.getRoi(); if (roi instanceof TextRoi) { if ((flags & KeyEvent.META_MASK) != 0 && IJ.isMacOSX()) return; if (alt) { switch (keyChar) { case 'u': case 'm': keyChar = IJ.micronSymbol; break; case 'A': keyChar = IJ.angstromSymbol; break; default: } } ((TextRoi) roi).addChar(keyChar); return; } } // Handle one character macro shortcuts if (!control && !meta) { Hashtable macroShortcuts = Menus.getMacroShortcuts(); if (macroShortcuts.size() > 0) { if (shift) cmd = (String) macroShortcuts.get(new Integer(keyCode + 200)); else cmd = (String) macroShortcuts.get(new Integer(keyCode)); if (cmd != null) { // MacroInstaller.runMacroCommand(cmd); commandName = cmd; MacroInstaller.runMacroShortcut(cmd); return; } } } if ((!Prefs.requireControlKey || control || meta) && keyChar != '+') { Hashtable shortcuts = Menus.getShortcuts(); if (shift) cmd = (String) shortcuts.get(new Integer(keyCode + 200)); else cmd = (String) shortcuts.get(new Integer(keyCode)); } if (cmd == null) { switch (keyChar) { case '<': case ',': if (isStack) cmd = "Previous Slice [<]"; break; case '>': case '.': case ';': if (isStack) cmd = "Next Slice [>]"; break; case '+': case '=': cmd = "In [+]"; break; case '-': cmd = "Out [-]"; break; case '/': cmd = "Reslice [/]..."; break; default: } } if (cmd == null) { switch (keyCode) { case KeyEvent.VK_TAB: WindowManager.putBehind(); return; case KeyEvent.VK_BACK_SPACE: // delete if (deleteOverlayRoi(imp)) return; cmd = "Clear"; hotkey = true; break; // case KeyEvent.VK_BACK_SLASH: cmd=IJ.altKeyDown()?"Animation Options...":"Start // Animation"; break; case KeyEvent.VK_EQUALS: cmd = "In [+]"; break; case KeyEvent.VK_MINUS: cmd = "Out [-]"; break; case KeyEvent.VK_SLASH: case 0xbf: cmd = "Reslice [/]..."; break; case KeyEvent.VK_COMMA: case 0xbc: if (isStack) cmd = "Previous Slice [<]"; break; case KeyEvent.VK_PERIOD: case 0xbe: if (isStack) cmd = "Next Slice [>]"; break; case KeyEvent.VK_LEFT: case KeyEvent.VK_RIGHT: case KeyEvent.VK_UP: case KeyEvent.VK_DOWN: // arrow keys if (imp == null) return; Roi roi = imp.getRoi(); if (IJ.shiftKeyDown() && imp == Orthogonal_Views.getImage()) return; boolean stackKey = imp.getStackSize() > 1 && (roi == null || IJ.shiftKeyDown()); boolean zoomKey = roi == null || IJ.shiftKeyDown() || IJ.controlKeyDown(); if (stackKey && keyCode == KeyEvent.VK_RIGHT) cmd = "Next Slice [>]"; else if (stackKey && keyCode == KeyEvent.VK_LEFT) cmd = "Previous Slice [<]"; else if (zoomKey && keyCode == KeyEvent.VK_DOWN && !ignoreArrowKeys(imp) && Toolbar.getToolId() < Toolbar.SPARE6) cmd = "Out [-]"; else if (zoomKey && keyCode == KeyEvent.VK_UP && !ignoreArrowKeys(imp) && Toolbar.getToolId() < Toolbar.SPARE6) cmd = "In [+]"; else if (roi != null) { if ((flags & KeyEvent.ALT_MASK) != 0) roi.nudgeCorner(keyCode); else roi.nudge(keyCode); return; } break; case KeyEvent.VK_ESCAPE: abortPluginOrMacro(imp); return; case KeyEvent.VK_ENTER: WindowManager.toFront(this); return; default: break; } } if (cmd != null && !cmd.equals("")) { commandName = cmd; if (cmd.equals("Fill") || cmd.equals("Draw")) hotkey = true; if (cmd.charAt(0) == MacroInstaller.commandPrefix) MacroInstaller.runMacroShortcut(cmd); else { doCommand(cmd); keyPressedTime = System.currentTimeMillis(); lastKeyCommand = cmd; } } }
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()); }
/** * If 'applet' is not null, creates a new ImageJ frame that runs as an applet. If 'mode' is * ImageJ.EMBEDDED and 'applet is null, creates an embedded (non-standalone) version of ImageJ. */ public ImageJ(java.applet.Applet applet, int mode) { super("ImageJ"); if ((mode & DEBUG) != 0) IJ.setDebugMode(true); mode = mode & 255; if (IJ.debugMode) IJ.log("ImageJ starting in debug mode: " + mode); embedded = applet == null && (mode == EMBEDDED || mode == NO_SHOW); this.applet = applet; String err1 = Prefs.load(this, applet); setBackground(backgroundColor); Menus m = new Menus(this, applet); String err2 = m.addMenuBar(); m.installPopupMenu(this); setLayout(new BorderLayout()); // Tool bar toolbar = new Toolbar(); toolbar.addKeyListener(this); add("Center", toolbar); // Status bar statusBar = new Panel(); statusBar.setLayout(new BorderLayout()); statusBar.setForeground(Color.black); statusBar.setBackground(backgroundColor); statusLine = new JLabel(); statusLine.setFont(new Font("SansSerif", Font.PLAIN, 13)); statusLine.addKeyListener(this); statusLine.addMouseListener(this); statusBar.add("Center", statusLine); progressBar = new ProgressBar(120, 20); progressBar.addKeyListener(this); progressBar.addMouseListener(this); statusBar.add("East", progressBar); add("South", statusBar); IJ.init(this, applet); addKeyListener(this); addWindowListener(this); setFocusTraversalKeysEnabled(false); m.installStartupMacroSet(); // add custom tools runStartupMacro(); Point loc = getPreferredLocation(); Dimension tbSize = toolbar.getPreferredSize(); setCursor(Cursor.getDefaultCursor()); // work-around for JDK 1.1.8 bug if (mode != NO_SHOW) { if (IJ.isWindows()) try { setIcon(); } catch (Exception e) { } setLocation(loc.x, loc.y); setResizable(!IJ.isMacOSX()); pack(); setVisible(true); } if (err1 != null) IJ.error(err1); if (err2 != null) { IJ.error(err2); IJ.runPlugIn("ij.plugin.ClassChecker", ""); } if (IJ.isMacintosh() && applet == null) { Object qh = null; qh = IJ.runPlugIn("MacAdapter", ""); if (qh == null) IJ.runPlugIn("QuitHandler", ""); } if (applet == null) IJ.runPlugIn("ij.plugin.DragAndDrop", ""); String str = m.getMacroCount() == 1 ? " macro" : " macros"; IJ.showStatus(version() + m.getPluginCount() + " commands; " + m.getMacroCount() + str); configureProxy(); if (applet == null) loadCursors(); }
void Sauvola(ImagePlus imp, int radius, double par1, double par2, boolean doIwhite) { // Sauvola recommends K_VALUE = 0.5 and R_VALUE = 128. // This is a modification of Niblack's thresholding method. // Sauvola J. and Pietaksinen M. (2000) "Adaptive Document Image Binarization" // Pattern Recognition, 33(2): 225-236 // http://www.ee.oulu.fi/mvg/publications/show_pdf.php?ID=24 // Ported to ImageJ plugin from E Celebi's fourier_0.8 routines // This version uses a circular local window, instead of a rectagular one ImagePlus Meanimp, Varimp; ImageProcessor ip = imp.getProcessor(), ipMean, ipVar; double k_value = 0.5; double r_value = 128; byte object; byte backg; if (par1 != 0) { IJ.log("Sauvola: changed k_value from :" + k_value + " to:" + par1); k_value = par1; } if (par2 != 0) { IJ.log("Sauvola: changed r_value from :" + r_value + " to:" + par2); r_value = par2; } if (doIwhite) { object = (byte) 0xff; backg = (byte) 0; } else { object = (byte) 0; backg = (byte) 0xff; } Meanimp = duplicateImage(ip); ImageConverter ic = new ImageConverter(Meanimp); ic.convertToGray32(); ipMean = Meanimp.getProcessor(); RankFilters rf = new RankFilters(); rf.rank(ipMean, radius, rf.MEAN); // Mean // Meanimp.show(); Varimp = duplicateImage(ip); ic = new ImageConverter(Varimp); ic.convertToGray32(); ipVar = Varimp.getProcessor(); rf.rank(ipVar, radius, rf.VARIANCE); // Variance // Varimp.show(); byte[] pixels = (byte[]) ip.getPixels(); float[] mean = (float[]) ipMean.getPixels(); float[] var = (float[]) ipVar.getPixels(); for (int i = 0; i < pixels.length; i++) pixels[i] = ((int) (pixels[i] & 0xff) > (int) (mean[i] * (1.0 + k_value * ((Math.sqrt(var[i]) / r_value) - 1.0)))) ? object : backg; // imp.updateAndDraw(); return; }
void Phansalkar(ImagePlus imp, int radius, double par1, double par2, boolean doIwhite) { // This is a modification of Sauvola's thresholding method to deal with low contrast images. // Phansalskar N. et al. Adaptive local thresholding for detection of nuclei in diversity // stained // cytology images.International Conference on Communications and Signal Processing (ICCSP), // 2011, // 218 - 220. // In this method, the threshold t = mean*(1+p*exp(-q*mean)+k*((stdev/r)-1)) // Phansalkar recommends k = 0.25, r = 0.5, p = 2 and q = 10. In this plugin, k and r are the // parameters 1 and 2 respectively, but the values of p and q are fixed. // // Implemented from Phansalkar's paper description by G. Landini // This version uses a circular local window, instead of a rectagular one ImagePlus Meanimp, Varimp, Orimp; ImageProcessor ip = imp.getProcessor(), ipMean, ipVar, ipOri; double k_value = 0.25; double r_value = 0.5; double p_value = 2.0; double q_value = 10.0; byte object; byte backg; if (par1 != 0) { IJ.log("Phansalkar: changed k_value from :" + k_value + " to:" + par1); k_value = par1; } if (par2 != 0) { IJ.log("Phansalkar: changed r_value from :" + r_value + " to:" + par2); r_value = par2; } if (doIwhite) { object = (byte) 0xff; backg = (byte) 0; } else { object = (byte) 0; backg = (byte) 0xff; } Meanimp = duplicateImage(ip); ContrastEnhancer ce = new ContrastEnhancer(); ce.stretchHistogram(Meanimp, 0.0); ImageConverter ic = new ImageConverter(Meanimp); ic.convertToGray32(); ipMean = Meanimp.getProcessor(); ipMean.multiply(1.0 / 255); Orimp = duplicateImage(ip); ce.stretchHistogram(Orimp, 0.0); ic = new ImageConverter(Orimp); ic.convertToGray32(); ipOri = Orimp.getProcessor(); ipOri.multiply(1.0 / 255); // original to compare // Orimp.show(); RankFilters rf = new RankFilters(); rf.rank(ipMean, radius, rf.MEAN); // Mean // Meanimp.show(); Varimp = duplicateImage(ip); ce.stretchHistogram(Varimp, 0.0); ic = new ImageConverter(Varimp); ic.convertToGray32(); ipVar = Varimp.getProcessor(); ipVar.multiply(1.0 / 255); rf.rank(ipVar, radius, rf.VARIANCE); // Variance ipVar.sqr(); // SD // Varimp.show(); byte[] pixels = (byte[]) ip.getPixels(); float[] ori = (float[]) ipOri.getPixels(); float[] mean = (float[]) ipMean.getPixels(); float[] sd = (float[]) ipVar.getPixels(); for (int i = 0; i < pixels.length; i++) pixels[i] = ((ori[i]) > (mean[i] * (1.0 + p_value * Math.exp(-q_value * mean[i]) + k_value * ((sd[i] / r_value) - 1.0)))) ? object : backg; // imp.updateAndDraw(); return; }
void Niblack(ImagePlus imp, int radius, double par1, double par2, boolean doIwhite) { // Niblack recommends K_VALUE = -0.2 for images with black foreground // objects, and K_VALUE = +0.2 for images with white foreground objects. // Niblack W. (1986) "An introduction to Digital Image Processing" Prentice-Hall. // Ported to ImageJ plugin from E Celebi's fourier_0.8 routines // This version uses a circular local window, instead of a rectagular one ImagePlus Meanimp, Varimp; ImageProcessor ip = imp.getProcessor(), ipMean, ipVar; double k_value; int c_value = 0; byte object; byte backg; if (doIwhite) { k_value = 0.2; object = (byte) 0xff; backg = (byte) 0; } else { k_value = -0.2; object = (byte) 0; backg = (byte) 0xff; } if (par1 != 0) { IJ.log("Niblack: changed k_value from :" + k_value + " to:" + par1); k_value = par1; } if (par2 != 0) { IJ.log( "Niblack: changed c_value from :" + c_value + " to:" + par2); // requested feature, not in original c_value = (int) par2; } Meanimp = duplicateImage(ip); ImageConverter ic = new ImageConverter(Meanimp); ic.convertToGray32(); ipMean = Meanimp.getProcessor(); RankFilters rf = new RankFilters(); rf.rank(ipMean, radius, rf.MEAN); // Mean // Meanimp.show(); Varimp = duplicateImage(ip); ic = new ImageConverter(Varimp); ic.convertToGray32(); ipVar = Varimp.getProcessor(); rf.rank(ipVar, radius, rf.VARIANCE); // Variance // Varimp.show(); byte[] pixels = (byte[]) ip.getPixels(); float[] mean = (float[]) ipMean.getPixels(); float[] var = (float[]) ipVar.getPixels(); for (int i = 0; i < pixels.length; i++) pixels[i] = ((int) (pixels[i] & 0xff) > (int) (mean[i] + k_value * Math.sqrt(var[i]) - c_value)) ? object : backg; // imp.updateAndDraw(); return; }
public static void main(String args[]) { if (System.getProperty("java.version").substring(0, 3).compareTo("1.5") < 0) { javax.swing.JOptionPane.showMessageDialog( null, "ImageJ " + VERSION + " requires Java 1.5 or later."); System.exit(0); } boolean noGUI = false; int mode = STANDALONE; arguments = args; // System.setProperty("file.encoding", "UTF-8"); int nArgs = args != null ? args.length : 0; boolean commandLine = false; for (int i = 0; i < nArgs; i++) { String arg = args[i]; if (arg == null) continue; if (args[i].startsWith("-")) { if (args[i].startsWith("-batch")) noGUI = true; else if (args[i].startsWith("-debug")) IJ.setDebugMode(true); else if (args[i].startsWith("-ijpath") && i + 1 < nArgs) { if (IJ.debugMode) IJ.log("-ijpath: " + args[i + 1]); Prefs.setHomeDir(args[i + 1]); commandLine = true; args[i + 1] = null; } else if (args[i].startsWith("-port")) { int delta = (int) Tools.parseDouble(args[i].substring(5, args[i].length()), 0.0); commandLine = true; if (delta == 0) mode = EMBEDDED; else if (delta > 0 && DEFAULT_PORT + delta < 65536) port = DEFAULT_PORT + delta; } } } // If existing ImageJ instance, pass arguments to it and quit. boolean passArgs = mode == STANDALONE && !noGUI; if (IJ.isMacOSX() && !commandLine) passArgs = false; if (passArgs && isRunning(args)) return; ImageJ ij = IJ.getInstance(); if (!noGUI && (ij == null || (ij != null && !ij.isShowing()))) { ij = new ImageJ(null, mode); ij.exitWhenQuitting = true; } int macros = 0; for (int i = 0; i < nArgs; i++) { String arg = args[i]; if (arg == null) continue; if (arg.startsWith("-")) { if ((arg.startsWith("-macro") || arg.startsWith("-batch")) && i + 1 < nArgs) { String arg2 = i + 2 < nArgs ? args[i + 2] : null; Prefs.commandLineMacro = true; if (noGUI && args[i + 1].endsWith(".js")) Interpreter.batchMode = true; IJ.runMacroFile(args[i + 1], arg2); break; } else if (arg.startsWith("-eval") && i + 1 < nArgs) { String rtn = IJ.runMacro(args[i + 1]); if (rtn != null) System.out.print(rtn); args[i + 1] = null; } else if (arg.startsWith("-run") && i + 1 < nArgs) { IJ.run(args[i + 1]); args[i + 1] = null; } } else if (macros == 0 && (arg.endsWith(".ijm") || arg.endsWith(".txt"))) { IJ.runMacroFile(arg); macros++; } else if (arg.length() > 0 && arg.indexOf("ij.ImageJ") == -1) { File file = new File(arg); IJ.open(file.getAbsolutePath()); } } if (IJ.debugMode && IJ.getInstance() == null) new JavaProperties().run(""); if (noGUI) System.exit(0); }
/* if selection is closed shape, create a circle with the same area and centroid, otherwise use<br> the Pratt method to fit a circle to the points that define the line or multi-point selection.<br> Reference: Pratt V., Direct least-squares fitting of algebraic surfaces", Computer Graphics, Vol. 21, pages 145-152 (1987).<br> Original code: Nikolai Chernov's MATLAB script for Newton-based Pratt fit.<br> (http://www.math.uab.edu/~chernov/cl/MATLABcircle.html)<br> Java version: https://github.com/mdoube/BoneJ/blob/master/src/org/doube/geometry/FitCircle.java<br> @authors Nikolai Chernov, Michael Doube, Ved Sharma */ void fitCircle(ImagePlus imp) { Roi roi = imp.getRoi(); if (roi == null) { noRoi("Fit Circle"); return; } if (roi.isArea()) { // create circle with the same area and centroid ImageProcessor ip = imp.getProcessor(); ip.setRoi(roi); ImageStatistics stats = ImageStatistics.getStatistics(ip, Measurements.AREA + Measurements.CENTROID, null); double r = Math.sqrt(stats.pixelCount / Math.PI); imp.killRoi(); int d = (int) Math.round(2.0 * r); IJ.makeOval( (int) Math.round(stats.xCentroid - r), (int) Math.round(stats.yCentroid - r), d, d); return; } Polygon poly = roi.getPolygon(); int n = poly.npoints; int[] x = poly.xpoints; int[] y = poly.ypoints; if (n < 3) { IJ.error("Fit Circle", "At least 3 points are required to fit a circle."); return; } // calculate point centroid double sumx = 0, sumy = 0; for (int i = 0; i < n; i++) { sumx = sumx + poly.xpoints[i]; sumy = sumy + poly.ypoints[i]; } double meanx = sumx / n; double meany = sumy / n; // calculate moments double[] X = new double[n], Y = new double[n]; double Mxx = 0, Myy = 0, Mxy = 0, Mxz = 0, Myz = 0, Mzz = 0; for (int i = 0; i < n; i++) { X[i] = x[i] - meanx; Y[i] = y[i] - meany; double Zi = X[i] * X[i] + Y[i] * Y[i]; Mxy = Mxy + X[i] * Y[i]; Mxx = Mxx + X[i] * X[i]; Myy = Myy + Y[i] * Y[i]; Mxz = Mxz + X[i] * Zi; Myz = Myz + Y[i] * Zi; Mzz = Mzz + Zi * Zi; } Mxx = Mxx / n; Myy = Myy / n; Mxy = Mxy / n; Mxz = Mxz / n; Myz = Myz / n; Mzz = Mzz / n; // calculate the coefficients of the characteristic polynomial double Mz = Mxx + Myy; double Cov_xy = Mxx * Myy - Mxy * Mxy; double Mxz2 = Mxz * Mxz; double Myz2 = Myz * Myz; double A2 = 4 * Cov_xy - 3 * Mz * Mz - Mzz; double A1 = Mzz * Mz + 4 * Cov_xy * Mz - Mxz2 - Myz2 - Mz * Mz * Mz; double A0 = Mxz2 * Myy + Myz2 * Mxx - Mzz * Cov_xy - 2 * Mxz * Myz * Mxy + Mz * Mz * Cov_xy; double A22 = A2 + A2; double epsilon = 1e-12; double ynew = 1e+20; int IterMax = 20; double xnew = 0; int iterations = 0; // Newton's method starting at x=0 for (int iter = 1; iter <= IterMax; iter++) { iterations = iter; double yold = ynew; ynew = A0 + xnew * (A1 + xnew * (A2 + 4. * xnew * xnew)); if (Math.abs(ynew) > Math.abs(yold)) { if (IJ.debugMode) IJ.log("Fit Circle: wrong direction: |ynew| > |yold|"); xnew = 0; break; } double Dy = A1 + xnew * (A22 + 16 * xnew * xnew); double xold = xnew; xnew = xold - ynew / Dy; if (Math.abs((xnew - xold) / xnew) < epsilon) break; if (iter >= IterMax) { if (IJ.debugMode) IJ.log("Fit Circle: will not converge"); xnew = 0; } if (xnew < 0) { if (IJ.debugMode) IJ.log("Fit Circle: negative root: x = " + xnew); xnew = 0; } } if (IJ.debugMode) IJ.log("Fit Circle: n=" + n + ", xnew=" + IJ.d2s(xnew, 2) + ", iterations=" + iterations); // calculate the circle parameters double DET = xnew * xnew - xnew * Mz + Cov_xy; double CenterX = (Mxz * (Myy - xnew) - Myz * Mxy) / (2 * DET); double CenterY = (Myz * (Mxx - xnew) - Mxz * Mxy) / (2 * DET); double radius = Math.sqrt(CenterX * CenterX + CenterY * CenterY + Mz + 2 * xnew); if (Double.isNaN(radius)) { IJ.error("Fit Circle", "Points are collinear."); return; } CenterX = CenterX + meanx; CenterY = CenterY + meany; imp.killRoi(); IJ.makeOval( (int) Math.round(CenterX - radius), (int) Math.round(CenterY - radius), (int) Math.round(2 * radius), (int) Math.round(2 * radius)); }
public void build_bricks() { ImagePlus imp; ImagePlus orgimp; ImageStack stack; FileInfo finfo; if (lvImgTitle.isEmpty()) return; orgimp = WindowManager.getImage(lvImgTitle.get(0)); imp = orgimp; finfo = imp.getFileInfo(); if (finfo == null) return; int[] dims = imp.getDimensions(); int imageW = dims[0]; int imageH = dims[1]; int nCh = dims[2]; int imageD = dims[3]; int nFrame = dims[4]; int bdepth = imp.getBitDepth(); double xspc = finfo.pixelWidth; double yspc = finfo.pixelHeight; double zspc = finfo.pixelDepth; double z_aspect = Math.max(xspc, yspc) / zspc; int orgW = imageW; int orgH = imageH; int orgD = imageD; double orgxspc = xspc; double orgyspc = yspc; double orgzspc = zspc; lv = lvImgTitle.size(); if (filetype == "JPEG") { for (int l = 0; l < lv; l++) { if (WindowManager.getImage(lvImgTitle.get(l)).getBitDepth() != 8) { IJ.error("A SOURCE IMAGE MUST BE 8BIT GLAYSCALE"); return; } } } // calculate levels /* int baseXY = 256; int baseZ = 256; if (z_aspect < 0.5) baseZ = 128; if (z_aspect > 2.0) baseXY = 128; if (z_aspect >= 0.5 && z_aspect < 1.0) baseZ = (int)(baseZ*z_aspect); if (z_aspect > 1.0 && z_aspect <= 2.0) baseXY = (int)(baseXY/z_aspect); IJ.log("Z_aspect: " + z_aspect); IJ.log("BaseXY: " + baseXY); IJ.log("BaseZ: " + baseZ); */ int baseXY = 256; int baseZ = 128; int dbXY = Math.max(orgW, orgH) / baseXY; if (Math.max(orgW, orgH) % baseXY > 0) dbXY *= 2; int dbZ = orgD / baseZ; if (orgD % baseZ > 0) dbZ *= 2; lv = Math.max(log2(dbXY), log2(dbZ)) + 1; int ww = orgW; int hh = orgH; int dd = orgD; for (int l = 0; l < lv; l++) { int bwnum = ww / baseXY; if (ww % baseXY > 0) bwnum++; int bhnum = hh / baseXY; if (hh % baseXY > 0) bhnum++; int bdnum = dd / baseZ; if (dd % baseZ > 0) bdnum++; if (bwnum % 2 == 0) bwnum++; if (bhnum % 2 == 0) bhnum++; if (bdnum % 2 == 0) bdnum++; int bw = (bwnum <= 1) ? ww : ww / bwnum + 1 + (ww % bwnum > 0 ? 1 : 0); int bh = (bhnum <= 1) ? hh : hh / bhnum + 1 + (hh % bhnum > 0 ? 1 : 0); int bd = (bdnum <= 1) ? dd : dd / bdnum + 1 + (dd % bdnum > 0 ? 1 : 0); bwlist.add(bw); bhlist.add(bh); bdlist.add(bd); IJ.log("LEVEL: " + l); IJ.log(" width: " + ww); IJ.log(" hight: " + hh); IJ.log(" depth: " + dd); IJ.log(" bw: " + bw); IJ.log(" bh: " + bh); IJ.log(" bd: " + bd); int xyl2 = Math.max(ww, hh) / baseXY; if (Math.max(ww, hh) % baseXY > 0) xyl2 *= 2; if (lv - 1 - log2(xyl2) <= l) { ww /= 2; hh /= 2; } IJ.log(" xyl2: " + (lv - 1 - log2(xyl2))); int zl2 = dd / baseZ; if (dd % baseZ > 0) zl2 *= 2; if (lv - 1 - log2(zl2) <= l) dd /= 2; IJ.log(" zl2: " + (lv - 1 - log2(zl2))); if (l < lv - 1) { lvImgTitle.add(lvImgTitle.get(0) + "_level" + (l + 1)); IJ.selectWindow(lvImgTitle.get(0)); IJ.run( "Scale...", "x=- y=- z=- width=" + ww + " height=" + hh + " depth=" + dd + " interpolation=Bicubic average process create title=" + lvImgTitle.get(l + 1)); } } for (int l = 0; l < lv; l++) { IJ.log(lvImgTitle.get(l)); } Document doc = newXMLDocument(); Element root = doc.createElement("BRK"); root.setAttribute("version", "1.0"); root.setAttribute("nLevel", String.valueOf(lv)); root.setAttribute("nChannel", String.valueOf(nCh)); root.setAttribute("nFrame", String.valueOf(nFrame)); doc.appendChild(root); for (int l = 0; l < lv; l++) { IJ.showProgress(0.0); int[] dims2 = imp.getDimensions(); IJ.log( "W: " + String.valueOf(dims2[0]) + " H: " + String.valueOf(dims2[1]) + " C: " + String.valueOf(dims2[2]) + " D: " + String.valueOf(dims2[3]) + " T: " + String.valueOf(dims2[4]) + " b: " + String.valueOf(bdepth)); bw = bwlist.get(l).intValue(); bh = bhlist.get(l).intValue(); bd = bdlist.get(l).intValue(); boolean force_pow2 = false; /* if(IsPowerOf2(bw) && IsPowerOf2(bh) && IsPowerOf2(bd)) force_pow2 = true; if(force_pow2){ //force pow2 if(Pow2(bw) > bw) bw = Pow2(bw)/2; if(Pow2(bh) > bh) bh = Pow2(bh)/2; if(Pow2(bd) > bd) bd = Pow2(bd)/2; } if(bw > imageW) bw = (Pow2(imageW) == imageW) ? imageW : Pow2(imageW)/2; if(bh > imageH) bh = (Pow2(imageH) == imageH) ? imageH : Pow2(imageH)/2; if(bd > imageD) bd = (Pow2(imageD) == imageD) ? imageD : Pow2(imageD)/2; */ if (bw > imageW) bw = imageW; if (bh > imageH) bh = imageH; if (bd > imageD) bd = imageD; if (bw <= 1 || bh <= 1 || bd <= 1) break; if (filetype == "JPEG" && (bw < 8 || bh < 8)) break; Element lvnode = doc.createElement("Level"); lvnode.setAttribute("lv", String.valueOf(l)); lvnode.setAttribute("imageW", String.valueOf(imageW)); lvnode.setAttribute("imageH", String.valueOf(imageH)); lvnode.setAttribute("imageD", String.valueOf(imageD)); lvnode.setAttribute("xspc", String.valueOf(xspc)); lvnode.setAttribute("yspc", String.valueOf(yspc)); lvnode.setAttribute("zspc", String.valueOf(zspc)); lvnode.setAttribute("bitDepth", String.valueOf(bdepth)); root.appendChild(lvnode); Element brksnode = doc.createElement("Bricks"); brksnode.setAttribute("brick_baseW", String.valueOf(bw)); brksnode.setAttribute("brick_baseH", String.valueOf(bh)); brksnode.setAttribute("brick_baseD", String.valueOf(bd)); lvnode.appendChild(brksnode); ArrayList<Brick> bricks = new ArrayList<Brick>(); int mw, mh, md, mw2, mh2, md2; double tx0, ty0, tz0, tx1, ty1, tz1; double bx0, by0, bz0, bx1, by1, bz1; for (int k = 0; k < imageD; k += bd) { if (k > 0) k--; for (int j = 0; j < imageH; j += bh) { if (j > 0) j--; for (int i = 0; i < imageW; i += bw) { if (i > 0) i--; mw = Math.min(bw, imageW - i); mh = Math.min(bh, imageH - j); md = Math.min(bd, imageD - k); if (force_pow2) { mw2 = Pow2(mw); mh2 = Pow2(mh); md2 = Pow2(md); } else { mw2 = mw; mh2 = mh; md2 = md; } if (filetype == "JPEG") { if (mw2 < 8) mw2 = 8; if (mh2 < 8) mh2 = 8; } tx0 = i == 0 ? 0.0d : ((mw2 - mw + 0.5d) / mw2); ty0 = j == 0 ? 0.0d : ((mh2 - mh + 0.5d) / mh2); tz0 = k == 0 ? 0.0d : ((md2 - md + 0.5d) / md2); tx1 = 1.0d - 0.5d / mw2; if (mw < bw) tx1 = 1.0d; if (imageW - i == bw) tx1 = 1.0d; ty1 = 1.0d - 0.5d / mh2; if (mh < bh) ty1 = 1.0d; if (imageH - j == bh) ty1 = 1.0d; tz1 = 1.0d - 0.5d / md2; if (md < bd) tz1 = 1.0d; if (imageD - k == bd) tz1 = 1.0d; bx0 = i == 0 ? 0.0d : (i + 0.5d) / (double) imageW; by0 = j == 0 ? 0.0d : (j + 0.5d) / (double) imageH; bz0 = k == 0 ? 0.0d : (k + 0.5d) / (double) imageD; bx1 = Math.min((i + bw - 0.5d) / (double) imageW, 1.0d); if (imageW - i == bw) bx1 = 1.0d; by1 = Math.min((j + bh - 0.5d) / (double) imageH, 1.0d); if (imageH - j == bh) by1 = 1.0d; bz1 = Math.min((k + bd - 0.5d) / (double) imageD, 1.0d); if (imageD - k == bd) bz1 = 1.0d; int x, y, z; x = i - (mw2 - mw); y = j - (mh2 - mh); z = k - (md2 - md); bricks.add( new Brick( x, y, z, mw2, mh2, md2, 0, 0, tx0, ty0, tz0, tx1, ty1, tz1, bx0, by0, bz0, bx1, by1, bz1)); } } } Element fsnode = doc.createElement("Files"); lvnode.appendChild(fsnode); stack = imp.getStack(); int totalbricknum = nFrame * nCh * bricks.size(); int curbricknum = 0; for (int f = 0; f < nFrame; f++) { for (int ch = 0; ch < nCh; ch++) { int sizelimit = bdsizelimit * 1024 * 1024; int bytecount = 0; int filecount = 0; int pd_bufsize = Math.max(sizelimit, bw * bh * bd * bdepth / 8); byte[] packed_data = new byte[pd_bufsize]; String base_dataname = basename + "_Lv" + String.valueOf(l) + "_Ch" + String.valueOf(ch) + "_Fr" + String.valueOf(f); String current_dataname = base_dataname + "_data" + filecount; Brick b_first = bricks.get(0); if (b_first.z_ != 0) IJ.log("warning"); int st_z = b_first.z_; int ed_z = b_first.z_ + b_first.d_; LinkedList<ImageProcessor> iplist = new LinkedList<ImageProcessor>(); for (int s = st_z; s < ed_z; s++) iplist.add(stack.getProcessor(imp.getStackIndex(ch + 1, s + 1, f + 1))); // ImagePlus test; // ImageStack tsst; // test = NewImage.createByteImage("test", imageW, imageH, imageD, // NewImage.FILL_BLACK); // tsst = test.getStack(); for (int i = 0; i < bricks.size(); i++) { Brick b = bricks.get(i); if (ed_z > b.z_ || st_z < b.z_ + b.d_) { if (b.z_ > st_z) { for (int s = 0; s < b.z_ - st_z; s++) iplist.pollFirst(); st_z = b.z_; } else if (b.z_ < st_z) { IJ.log("warning"); for (int s = st_z - 1; s > b.z_; s--) iplist.addFirst(stack.getProcessor(imp.getStackIndex(ch + 1, s + 1, f + 1))); st_z = b.z_; } if (b.z_ + b.d_ > ed_z) { for (int s = ed_z; s < b.z_ + b.d_; s++) iplist.add(stack.getProcessor(imp.getStackIndex(ch + 1, s + 1, f + 1))); ed_z = b.z_ + b.d_; } else if (b.z_ + b.d_ < ed_z) { IJ.log("warning"); for (int s = 0; s < ed_z - (b.z_ + b.d_); s++) iplist.pollLast(); ed_z = b.z_ + b.d_; } } else { IJ.log("warning"); iplist.clear(); st_z = b.z_; ed_z = b.z_ + b.d_; for (int s = st_z; s < ed_z; s++) iplist.add(stack.getProcessor(imp.getStackIndex(ch + 1, s + 1, f + 1))); } if (iplist.size() != b.d_) { IJ.log("Stack Error"); return; } // int zz = st_z; int bsize = 0; byte[] bdata = new byte[b.w_ * b.h_ * b.d_ * bdepth / 8]; Iterator<ImageProcessor> ipite = iplist.iterator(); while (ipite.hasNext()) { // ImageProcessor tsip = tsst.getProcessor(zz+1); ImageProcessor ip = ipite.next(); ip.setRoi(b.x_, b.y_, b.w_, b.h_); if (bdepth == 8) { byte[] data = (byte[]) ip.crop().getPixels(); System.arraycopy(data, 0, bdata, bsize, data.length); bsize += data.length; } else if (bdepth == 16) { ByteBuffer buffer = ByteBuffer.allocate(b.w_ * b.h_ * bdepth / 8); buffer.order(ByteOrder.LITTLE_ENDIAN); short[] data = (short[]) ip.crop().getPixels(); for (short e : data) buffer.putShort(e); System.arraycopy(buffer.array(), 0, bdata, bsize, buffer.array().length); bsize += buffer.array().length; } else if (bdepth == 32) { ByteBuffer buffer = ByteBuffer.allocate(b.w_ * b.h_ * bdepth / 8); buffer.order(ByteOrder.LITTLE_ENDIAN); float[] data = (float[]) ip.crop().getPixels(); for (float e : data) buffer.putFloat(e); System.arraycopy(buffer.array(), 0, bdata, bsize, buffer.array().length); bsize += buffer.array().length; } } String filename = basename + "_Lv" + String.valueOf(l) + "_Ch" + String.valueOf(ch) + "_Fr" + String.valueOf(f) + "_ID" + String.valueOf(i); int offset = bytecount; int datasize = bdata.length; if (filetype == "RAW") { int dummy = -1; // do nothing } if (filetype == "JPEG" && bdepth == 8) { try { DataBufferByte db = new DataBufferByte(bdata, datasize); Raster raster = Raster.createPackedRaster(db, b.w_, b.h_ * b.d_, 8, null); BufferedImage img = new BufferedImage(b.w_, b.h_ * b.d_, BufferedImage.TYPE_BYTE_GRAY); img.setData(raster); ByteArrayOutputStream baos = new ByteArrayOutputStream(); ImageOutputStream ios = ImageIO.createImageOutputStream(baos); String format = "jpg"; Iterator<javax.imageio.ImageWriter> iter = ImageIO.getImageWritersByFormatName("jpeg"); javax.imageio.ImageWriter writer = iter.next(); ImageWriteParam iwp = writer.getDefaultWriteParam(); iwp.setCompressionMode(ImageWriteParam.MODE_EXPLICIT); iwp.setCompressionQuality((float) jpeg_quality * 0.01f); writer.setOutput(ios); writer.write(null, new IIOImage(img, null, null), iwp); // ImageIO.write(img, format, baos); bdata = baos.toByteArray(); datasize = bdata.length; } catch (IOException e) { e.printStackTrace(); return; } } if (filetype == "ZLIB") { byte[] tmpdata = new byte[b.w_ * b.h_ * b.d_ * bdepth / 8]; Deflater compresser = new Deflater(); compresser.setInput(bdata); compresser.setLevel(Deflater.DEFAULT_COMPRESSION); compresser.setStrategy(Deflater.DEFAULT_STRATEGY); compresser.finish(); datasize = compresser.deflate(tmpdata); bdata = tmpdata; compresser.end(); } if (bytecount + datasize > sizelimit && bytecount > 0) { BufferedOutputStream fis = null; try { File file = new File(directory + current_dataname); fis = new BufferedOutputStream(new FileOutputStream(file)); fis.write(packed_data, 0, bytecount); } catch (IOException e) { e.printStackTrace(); return; } finally { try { if (fis != null) fis.close(); } catch (IOException e) { e.printStackTrace(); return; } } filecount++; current_dataname = base_dataname + "_data" + filecount; bytecount = 0; offset = 0; System.arraycopy(bdata, 0, packed_data, bytecount, datasize); bytecount += datasize; } else { System.arraycopy(bdata, 0, packed_data, bytecount, datasize); bytecount += datasize; } Element filenode = doc.createElement("File"); filenode.setAttribute("filename", current_dataname); filenode.setAttribute("channel", String.valueOf(ch)); filenode.setAttribute("frame", String.valueOf(f)); filenode.setAttribute("brickID", String.valueOf(i)); filenode.setAttribute("offset", String.valueOf(offset)); filenode.setAttribute("datasize", String.valueOf(datasize)); filenode.setAttribute("filetype", String.valueOf(filetype)); fsnode.appendChild(filenode); curbricknum++; IJ.showProgress((double) (curbricknum) / (double) (totalbricknum)); } if (bytecount > 0) { BufferedOutputStream fis = null; try { File file = new File(directory + current_dataname); fis = new BufferedOutputStream(new FileOutputStream(file)); fis.write(packed_data, 0, bytecount); } catch (IOException e) { e.printStackTrace(); return; } finally { try { if (fis != null) fis.close(); } catch (IOException e) { e.printStackTrace(); return; } } } } } for (int i = 0; i < bricks.size(); i++) { Brick b = bricks.get(i); Element bricknode = doc.createElement("Brick"); bricknode.setAttribute("id", String.valueOf(i)); bricknode.setAttribute("st_x", String.valueOf(b.x_)); bricknode.setAttribute("st_y", String.valueOf(b.y_)); bricknode.setAttribute("st_z", String.valueOf(b.z_)); bricknode.setAttribute("width", String.valueOf(b.w_)); bricknode.setAttribute("height", String.valueOf(b.h_)); bricknode.setAttribute("depth", String.valueOf(b.d_)); brksnode.appendChild(bricknode); Element tboxnode = doc.createElement("tbox"); tboxnode.setAttribute("x0", String.valueOf(b.tx0_)); tboxnode.setAttribute("y0", String.valueOf(b.ty0_)); tboxnode.setAttribute("z0", String.valueOf(b.tz0_)); tboxnode.setAttribute("x1", String.valueOf(b.tx1_)); tboxnode.setAttribute("y1", String.valueOf(b.ty1_)); tboxnode.setAttribute("z1", String.valueOf(b.tz1_)); bricknode.appendChild(tboxnode); Element bboxnode = doc.createElement("bbox"); bboxnode.setAttribute("x0", String.valueOf(b.bx0_)); bboxnode.setAttribute("y0", String.valueOf(b.by0_)); bboxnode.setAttribute("z0", String.valueOf(b.bz0_)); bboxnode.setAttribute("x1", String.valueOf(b.bx1_)); bboxnode.setAttribute("y1", String.valueOf(b.by1_)); bboxnode.setAttribute("z1", String.valueOf(b.bz1_)); bricknode.appendChild(bboxnode); } if (l < lv - 1) { imp = WindowManager.getImage(lvImgTitle.get(l + 1)); int[] newdims = imp.getDimensions(); imageW = newdims[0]; imageH = newdims[1]; imageD = newdims[3]; xspc = orgxspc * ((double) orgW / (double) imageW); yspc = orgyspc * ((double) orgH / (double) imageH); zspc = orgzspc * ((double) orgD / (double) imageD); bdepth = imp.getBitDepth(); } } File newXMLfile = new File(directory + basename + ".vvd"); writeXML(newXMLfile, doc); for (int l = 1; l < lv; l++) { imp = WindowManager.getImage(lvImgTitle.get(l)); imp.changes = false; imp.close(); } }