@Override protected Product doInBackground(com.bc.ceres.core.ProgressMonitor pm) throws Exception { final TargetProductSelectorModel model = getTargetProductSelector().getModel(); pm.beginTask("Writing...", model.isOpenInAppSelected() ? 100 : 95); ProgressMonitorList.instance().add(pm); // NESTMOD saveTime = 0L; Product product = null; try { // free cache // NESTMOD JAI.getDefaultInstance().getTileCache().flush(); System.gc(); executeStartTime = Calendar.getInstance().getTime(); long t0 = System.currentTimeMillis(); Operator operator = null; if (targetProduct.getProductReader() instanceof OperatorProductReader) { final OperatorProductReader opReader = (OperatorProductReader) targetProduct.getProductReader(); if (opReader.getOperatorContext().getOperator() instanceof Output) { operator = opReader.getOperatorContext().getOperator(); } } if (operator == null) { WriteOp writeOp = new WriteOp(targetProduct, model.getProductFile(), model.getFormatName()); writeOp.setDeleteOutputOnFailure(true); writeOp.setWriteEntireTileRows(true); writeOp.setClearCacheAfterRowWrite(false); operator = writeOp; } final OperatorExecutor executor = OperatorExecutor.create(operator); executor.execute(SubProgressMonitor.create(pm, 95)); saveTime = System.currentTimeMillis() - t0; File targetFile = model.getProductFile(); if (model.isOpenInAppSelected() && targetFile.exists()) { product = ProductIO.readProduct(targetFile); if (product == null) { product = targetProduct; // todo - check - this cannot be ok!!! (nf) } pm.worked(5); } } finally { // free cache JAI.getDefaultInstance().getTileCache().flush(); System.gc(); pm.done(); ProgressMonitorList.instance().remove(pm); // NESTMOD if (product != targetProduct) { targetProduct.dispose(); } } return product; }
public void mouseClicked(MouseEvent e) { int x = e.getX(); int y = e.getY(); int currentTabIndex = -1; int tabCount = tabPane.getTabCount(); for (int i = 0; i < tabCount; i++) { if (rects[i].contains(x, y)) { currentTabIndex = i; break; } // if contains } // for i if (currentTabIndex >= 0) { Rectangle tabRect = rects[currentTabIndex]; x = x - tabRect.x; y = y - tabRect.y; if ((x >= 5) && (x <= 15) && (y >= 5) && (y <= 15)) { try { tabbedPane.remove(currentTabIndex); } catch (Exception ex) { ex.printStackTrace(); } } // if } // if currentTabIndex >= 0 System.gc(); } // mouseClicked
public static void printImage(final Image image) { ImageHandler imh = new ImageHandler(); imh.printImage(image, null); System.gc(); }
public static void printComponent(final java.awt.print.Printable p) { ImageHandler imh = new ImageHandler(); imh.printComponent(p, null); System.gc(); }
public static void assertTiming( String message, long expected, int attempts, @NotNull Runnable actionToMeasure) { while (true) { attempts--; long duration = measure(actionToMeasure); try { assertTiming(message, expected, duration); break; } catch (AssertionFailedError e) { if (attempts == 0) throw e; System.gc(); System.gc(); System.gc(); String s = "Another epic fail (remaining attempts: " + attempts + "): " + e.getMessage(); TeamCityLogger.warning(s, null); System.err.println(s); } } }
public static void main(String[] args) { System.gc(); // Schedule a job for the event-dispatching thread: // creating and showing this application's GUI. javax.swing.SwingUtilities.invokeLater( new Runnable() { public void run() { createAndShowGUI(); } }); } // end of main
public void update(GameEvent e) { this.m_map = e.getMap(); if (e.getState() == Snake.DEAD) { int respond = JOptionPane.showConfirmDialog(this, "Snake is DEAD!!\nPlay again?"); if (respond == JOptionPane.OK_OPTION) { this.m_isBegin = true; this.m_body = new GameBody(this, this.m_map, 125); System.gc(); } else if (respond == JOptionPane.CANCEL_OPTION || respond == JOptionPane.NO_OPTION) { System.exit(0); } } this.repaint(); }
// Static main program for executing a test of the class. public static void main(String args[]) { // Define int variables. int width = 0; int height = 0; // If arguments are greater than zero. if (args.length > 0) { // If arguments are two. if (args.length >= 2) { // Use try block to parse for an integer. try { // Verify first argument is an integer. width = Integer.parseInt(args[0]); height = Integer.parseInt(args[1]); // Define a default instance of JMessagingFrame. JMessagingFrame f = new JMessagingFrame(width, height); } // Catch parsing failure exception. catch (NumberFormatException e) { // Print default runtime message. System.out.println("If you are testing the override constructor,"); System.out.println("then you need to provide two integer values."); } // End try-catch block on integer parse. } // End of if two arguments provided. else // When there are less than or more than two arguments. { // Print default runtime message. System.out.println("If you are testing the override constructor,"); System.out.println("then you need to provide two integer values."); } // End of else when there are less than or more than two arguments. } // End of else when there are two arguments. else // No arguments provided. { // Define a default instance of JMessagingFrame. JMessagingFrame f = new JMessagingFrame(); // Clean-up by signaling the garbage collector. System.gc(); } // End of else when no arguments are provided. } // End of static main.
/** * This method represents the application code that we'd like to run on a separate thread. It * simulates slowly computing a value, in this case just a string 'All Done'. It updates the * progress bar every half second to remind the user that we're still busy. */ Object doWork() { try { if (Thread.interrupted()) { throw new InterruptedException(); } while (!this.state.terminator.isTerminated(this.state.optimizer.getPopulation())) { if (Thread.interrupted()) { throw new InterruptedException(); } this.state.optimizer.optimize(); } System.gc(); } catch (InterruptedException e) { updateStatus("Interrupted", 0); return "Interrupted"; } updateStatus("All Done", 0); return "All Done"; }
/** * This method represents the application code that we'd like to run on a separate thread. It * simulates slowly computing a value, in this case just a string 'All Done'. It updates the * progress bar every half second to remind the user that we're still busy. */ public Object doWork() { try { this.optimizationParameters.saveInstance(); if (this.show) { this.statusField.setText("Optimizing..."); } RNG.setRandomSeed(optimizationParameters.getRandomSeed()); // opening output file... if (!this.outputFileName.equalsIgnoreCase("none")) { String name = ""; SimpleDateFormat formatter = new SimpleDateFormat("E'_'yyyy.MM.dd'_'HH.mm.ss"); String startDate = formatter.format(new Date()); name = this.outputPath + this.outputFileName + "_" + this.experimentName + "_" + startDate + ".dat"; try { this.outputFile = new BufferedWriter(new OutputStreamWriter(new FileOutputStream(name))); } catch (FileNotFoundException e) { System.out.println("Could not open output file! Filename: " + name); } } else { this.outputFile = null; } // initialize problem this.optimizationParameters.getProblem().initializeProblem(); this.optimizationParameters .getOptimizer() .setProblem(this.optimizationParameters.getProblem()); // int optimizer and population // this.optimizationParameters.getOptimizer().initialize(); // initialize the log data ArrayList tmpMultiRun = new ArrayList(); this.performedRuns.add(tmpMultiRun); // something to log file // if (outputFile != null) // this.writeToFile(this.optimizationParameters.getOptimizer().getStringRepresentation()); // this.writeToFile("Here i'll write something characterizing the algorithm."); for (int j = 0; j < this.multiRuns; j++) { this.optimizationParameters .getProblem() .initializeProblem(); // in the loop as well, dynamic probs may need that (MK) this.tmpData = new ArrayList<>(); this.currentRun = j; if (this.show) { this.statusField.setText( "Optimizing Run " + (j + 1) + " of " + this.multiRuns + " Multi Runs..."); } if (Thread.interrupted()) { throw new InterruptedException(); } // write header to file this.writeToFile( " FitnessCalls\t Best\t Mean\t Worst \t" + BeanInspector.toString( this.optimizationParameters.getProblem().getAdditionalDataHeader(), '\t', false, "")); if ((this.continueFlag) && (this.backupPopulation != null)) { this.recentFunctionCalls += this.backupPopulation.getFunctionCalls(); this.optimizationParameters.getOptimizer().getProblem().initializeProblem(); this.optimizationParameters.getOptimizer().addPopulationChangedEventListener(null); this.optimizationParameters.getOptimizer().setPopulation(this.backupPopulation); this.optimizationParameters .getOptimizer() .getProblem() .evaluate(this.optimizationParameters.getOptimizer().getPopulation()); this.optimizationParameters .getOptimizer() .getProblem() .evaluate(this.optimizationParameters.getOptimizer().getPopulation().getArchive()); this.optimizationParameters .getOptimizer() .initializeByPopulation(this.backupPopulation, false); this.optimizationParameters.getOptimizer().getPopulation().setFunctionCalls(0); this.optimizationParameters.addPopulationChangedEventListener(this); } else { this.recentFunctionCalls = 0; this.optimizationParameters.getOptimizer().initialize(); } // while (this.optimizationParameters.getOptimizer().getPopulation().getFunctionCalls() < // this.functionCalls) { while (!this.optimizationParameters .getTerminator() .isTerminated(this.optimizationParameters.getOptimizer().getPopulation())) { // System.out.println("Simulated Function calls "+ // this.optimizer.getPopulation().getFunctionCalls()); if (Thread.interrupted()) { throw new InterruptedException(); } optimizationParameters.getOptimizer().optimize(); } System.gc(); // @TODO if you want the final report include this // this.writeToFile(this.optimizationParameters.getProblem().getStringRepresentationForProblem(this.optimizationParameters.getOptimizer())); tmpMultiRun.add(this.tmpData); } if (this.show) { this.plot.setInfoString(this.currentExperiment, this.experimentName, 0.5f); } if (this.show) { this.draw(); } this.experimentName = this.optimizationParameters.getOptimizer().getName() + "-" + this.performedRuns.size(); } catch (InterruptedException e) { updateStatus(0); if (this.show) { this.statusField.setText("Interrupted..."); } return "Interrupted"; } if (this.outputFile != null) { try { this.outputFile.close(); } catch (IOException e) { System.out.println("Failed to close output file!"); } } if (this.show) { for (int i = 0; i < this.multiRuns; i++) { this.plot.clearGraph(1000 + i); } } updateStatus(0); if (this.show) { this.statusField.setText("Finished..."); } return "All Done"; }
private void execute() { gResult.clear(); String sCmd = null; if (4096 <= ifHuge.length()) { sCmd = ifHuge; } else { sCmd = txtCommand.getText(); } if (sCmd.startsWith("-->>>TEST<<<--")) { testPerformance(); return; } String g[] = new String[1]; try { lTime = System.currentTimeMillis(); sStatement.execute(sCmd); int r = sStatement.getUpdateCount(); if (r == -1) { formatResultSet(sStatement.getResultSet()); } else { g[0] = "update count"; gResult.setHead(g); g[0] = "" + r; gResult.addRow(g); } lTime = System.currentTimeMillis() - lTime; addToRecent(txtCommand.getText()); gResult.fireTableChanged(null); } catch (SQLException e) { lTime = System.currentTimeMillis() - lTime; g[0] = "SQL Error"; gResult.setHead(g); String s = e.getMessage(); s += " / Error Code: " + e.getErrorCode(); s += " / State: " + e.getSQLState(); g[0] = s; gResult.addRow(g); gResult.fireTableChanged(null); } updateResult(); System.gc(); }
/** * This method is required if the AlgorithmPerformed interface is implemented. It is called by the * algorithms when it has completed or failed to to complete, so that the dialog can be display * the result image and/or clean up. * * @param algorithm Algorithm that caused the event. */ public void algorithmPerformed(AlgorithmBase algorithm) { ViewJFrameImage imageFrame = null; if (algorithm instanceof AlgorithmMosaicToSlices) { if ((mathAlgo.isCompleted() == true) && (mathAlgo.getResultImage() != null)) { // The algorithm has completed and produced a new image to be displayed. if (displayLoc == NEW) { try { resultImage = mathAlgo.getResultImage(); new ViewJFrameImage(resultImage, null, new Dimension(610, 200)); } catch (OutOfMemoryError error) { System.gc(); MipavUtil.displayError("Out of memory: unable to open new frame"); } } else { // These next lines set the titles in all frames where the source image is displayed to // image name so as to indicate that the image is now unlocked! // The image frames are enabled and then registed to the userinterface. resultImage = mathAlgo.getResultImage(); Vector<ViewImageUpdateInterface> imageFrames = image.getImageFrameVector(); for (int i = 0; i < imageFrames.size(); i++) { ((Frame) (imageFrames.elementAt(i))).setTitle(titles[i]); ((Frame) (imageFrames.elementAt(i))).setEnabled(true); if ((((Frame) (imageFrames.elementAt(i))) != parentFrame) && (parentFrame != null)) { userInterface.registerFrame((Frame) (imageFrames.elementAt(i))); } } Point pt; if (parentFrame != null) { pt = ((ViewJFrameBase) parentFrame).getLocation(); } else { pt = new Point( Toolkit.getDefaultToolkit().getScreenSize().width / 2, Toolkit.getDefaultToolkit().getScreenSize().height / 2); } imageFrame = new ViewJFrameImage(resultImage, null, new Dimension(pt.x, pt.y)); if (parentFrame != null) { ((ViewJFrameBase) parentFrame).close(); } else { ((ViewJFrameBase) image.getParentFrame()).close(); } // Not so sure about this. if (image.getLightBoxFrame() != null) { try { pt = image.getLightBoxFrame().getLocation(); image.getLightBoxFrame().close(); new ViewJFrameLightBox( imageFrame, "LightBox", resultImage, imageFrame.getComponentImage().getLUTa(), imageFrame.getComponentImage().getImageB(), imageFrame.getComponentImage().getLUTb(), imageFrame.getComponentImage().getResolutionX(), imageFrame.getComponentImage().getResolutionY(), new Dimension(pt.x, pt.y), imageFrame.getControls(), imageFrame.getVOIManager()); } catch (OutOfMemoryError error) { MipavUtil.displayError("Out of memory: unable to open new frame"); } } } } else if (resultImage == null) { // These next lines set the titles in all frames where the source image is displayed to // image name so as to indicate that the image is now unlocked! // The image frames are enabled and then registered to the userinterface. /*Vector imageFrames = imageA.getImageFrameVector(); for (int i = 0; i < imageFrames.size(); i++) { ((Frame) (imageFrames.elementAt(i))).setTitle(titles[i]); ((Frame) (imageFrames.elementAt(i))).setEnabled(true); if (((Frame) (imageFrames.elementAt(i))) != parentFrame) { userInterface.registerFrame((Frame) (imageFrames.elementAt(i))); } }*/ if (parentFrame != null) { userInterface.registerFrame(parentFrame); } image.notifyImageDisplayListeners(null, true); } else if (resultImage != null) { // algorithm failed but result image still has garbage resultImage.disposeLocal(); // clean up memory System.gc(); } } if (algorithm.isCompleted()) { insertScriptLine(); } mathAlgo.finalize(); mathAlgo = null; dispose(); }
/** * Use the GUI results to set up the variables needed to run the algorithm. * * @return <code>true</code> if parameters set successfully, <code>false</code> otherwise. */ private boolean setVariables() { String tmpStr; System.gc(); if (replaceImage.isSelected()) { displayLoc = REPLACE; } else if (newImage.isSelected()) { displayLoc = NEW; } tmpStr = textSearchWindowSide.getText(); if (testParameter(tmpStr, 5, 101)) { searchWindowSide = Integer.valueOf(tmpStr).intValue(); } else { MipavUtil.displayError("Search window side must be between 5 and 101"); textSearchWindowSide.requestFocus(); textSearchWindowSide.selectAll(); return false; } if ((searchWindowSide % 2) == 0) { MipavUtil.displayError("Search window side must be an odd number"); textSearchWindowSide.requestFocus(); textSearchWindowSide.selectAll(); return false; } tmpStr = textSimilarityWindowSide.getText(); if (testParameter(tmpStr, 3, 99)) { similarityWindowSide = Integer.valueOf(tmpStr).intValue(); } else { MipavUtil.displayError("Similarity window side must be between 3 and 99"); textSimilarityWindowSide.requestFocus(); textSimilarityWindowSide.selectAll(); return false; } if ((similarityWindowSide % 2) == 0) { MipavUtil.displayError("Similarity window side must be an odd number"); textSimilarityWindowSide.requestFocus(); textSimilarityWindowSide.selectAll(); return false; } if (similarityWindowSide >= searchWindowSide) { MipavUtil.displayError("Similarity window side must be less than search window side"); textSimilarityWindowSide.requestFocus(); textSimilarityWindowSide.selectAll(); return false; } tmpStr = textNoiseStandardDeviation.getText(); if (testParameter(tmpStr, 0.001, 1000.0)) { noiseStandardDeviation = Float.valueOf(tmpStr).floatValue(); } else { MipavUtil.displayError("Radius must be between 0.001 and 1000.0"); textNoiseStandardDeviation.requestFocus(); textNoiseStandardDeviation.selectAll(); return false; } doRician = doRicianCheckBox.isSelected(); if (doRician) { tmpStr = textDegree.getText(); if (testParameter(tmpStr, 1.0, 10.0)) { degreeOfFiltering = Float.valueOf(tmpStr).floatValue(); } else { MipavUtil.displayError("Degree of filtering must be between 1.0 and 10.0"); textDegree.requestFocus(); textDegree.selectAll(); } } if (image.getNDims() > 2) { image25D = image25DCheckBox.isSelected(); } return true; }
/** * Initializes the GUI by creating the components, placing them in the dialog, and displaying * them. */ private void init() { setForeground(Color.black); setTitle("Nonlocal Means Filter"); JPanel mainPanel; mainPanel = new JPanel(); mainPanel.setBorder(BorderFactory.createEmptyBorder(3, 3, 3, 3)); mainPanel.setLayout(new GridBagLayout()); GridBagConstraints gbc = new GridBagConstraints(); gbc.gridwidth = 1; gbc.gridheight = 1; gbc.anchor = GridBagConstraints.WEST; gbc.weightx = 1; gbc.insets = new Insets(3, 3, 3, 3); gbc.gridx = 0; gbc.gridy = 0; gbc.fill = GridBagConstraints.HORIZONTAL; paramPanel = new JPanel(new GridBagLayout()); paramPanel.setForeground(Color.black); paramPanel.setBorder(buildTitledBorder("Parameters")); mainPanel.add(paramPanel, gbc); GridBagConstraints gbc2 = new GridBagConstraints(); gbc2.gridwidth = 1; gbc2.gridheight = 1; gbc2.anchor = GridBagConstraints.WEST; gbc2.weightx = 1; gbc2.insets = new Insets(3, 3, 3, 3); gbc2.gridx = 0; gbc2.gridy = 0; gbc2.fill = GridBagConstraints.HORIZONTAL; labelSearchWindowSide = createLabel("Search window side (odd)"); paramPanel.add(labelSearchWindowSide, gbc2); gbc2.gridx = 1; textSearchWindowSide = createTextField("15"); paramPanel.add(textSearchWindowSide, gbc2); gbc2.gridx = 0; gbc2.gridy = 1; labelSimilarityWindowSide = createLabel("Similarity window side (odd) "); paramPanel.add(labelSimilarityWindowSide, gbc2); gbc2.gridx = 1; textSimilarityWindowSide = createTextField("7"); paramPanel.add(textSimilarityWindowSide, gbc2); gbc2.gridx = 0; gbc2.gridy = 2; labelNoiseStandardDeviation = createLabel("Noise standard deviation "); paramPanel.add(labelNoiseStandardDeviation, gbc2); gbc2.gridx = 1; textNoiseStandardDeviation = createTextField("10.0"); paramPanel.add(textNoiseStandardDeviation, gbc2); gbc2.gridx = 0; gbc2.gridy = 3; labelDegree = createLabel("Degree of filtering "); labelDegree.setEnabled(doRician); paramPanel.add(labelDegree, gbc2); gbc2.gridx = 1; textDegree = createTextField("1.414"); textDegree.setEnabled(doRician); paramPanel.add(textDegree, gbc2); gbc2.gridx = 0; gbc2.gridy = 4; doRicianCheckBox = new JCheckBox("Deal with Rician noise in MRI"); doRicianCheckBox.setFont(serif12); doRicianCheckBox.setSelected(false); doRicianCheckBox.addActionListener(this); paramPanel.add(doRicianCheckBox, gbc2); if (image.getNDims() > 2) { gbc2.gridx = 0; gbc2.gridy = 5; gbc2.gridwidth = 2; image25DCheckBox = new JCheckBox("Process each slice independently (2.5D)"); image25DCheckBox.setFont(serif12); paramPanel.add(image25DCheckBox, gbc2); image25DCheckBox.setSelected(false); } // if (image.getNDims > 2) JPanel outputOptPanel = new JPanel(new GridLayout(1, 2)); destinationPanel = new JPanel(new BorderLayout()); destinationPanel.setForeground(Color.black); destinationPanel.setBorder(buildTitledBorder("Destination")); outputOptPanel.add(destinationPanel); destinationGroup = new ButtonGroup(); newImage = new JRadioButton("New image", true); newImage.setBounds(10, 16, 120, 25); newImage.setFont(serif12); destinationGroup.add(newImage); destinationPanel.add(newImage, BorderLayout.NORTH); replaceImage = new JRadioButton("Replace image", false); replaceImage.setFont(serif12); destinationGroup.add(replaceImage); destinationPanel.add(replaceImage, BorderLayout.CENTER); // Only if the image is unlocked can it be replaced. if (image.getLockStatus() == ModelStorageBase.UNLOCKED) { replaceImage.setEnabled(true); } else { replaceImage.setEnabled(false); } gbc.gridx = 0; gbc.gridy = 1; mainPanel.add(outputOptPanel, gbc); mainDialogPanel.add(mainPanel, BorderLayout.CENTER); mainDialogPanel.add(buildButtons(), BorderLayout.SOUTH); getContentPane().add(mainDialogPanel); pack(); setResizable(true); // setVisible(true); System.gc(); }
/** * Once all the necessary variables are set, call the Concat algorithm based on what type of image * this is and whether or not there is a separate destination image. */ protected void callAlgorithm() { int destExtents[] = new int[3]; ModelImage destImage = null; destExtents[0] = subXDim; destExtents[1] = subYDim; destExtents[2] = numberOfImagesInMosaic; destImage = new ModelImage( image.getType(), destExtents, makeImageName(image.getImageName(), "_mosaic_to_slices")); try { // Make algorithm mathAlgo = new AlgorithmMosaicToSlices(image, destImage); // This is very important. Adding this object as a listener allows the algorithm to // notify this object when it has completed of failed. See algorithm performed event. // This is made possible by implementing AlgorithmedPerformed interface mathAlgo.addListener(this); createProgressBar(image.getImageName(), mathAlgo); // Hide dialog setVisible(false); if (displayLoc == REPLACE) { // These next lines set the titles in all frames where the source image is displayed to // "locked - " image name so as to indicate that the image is now read/write locked! // The image frames are disabled and then unregisted from the userinterface until the // algorithm has completed. Vector<ViewImageUpdateInterface> imageFrames = image.getImageFrameVector(); titles = new String[imageFrames.size()]; for (int i = 0; i < imageFrames.size(); i++) { titles[i] = ((Frame) (imageFrames.elementAt(i))).getTitle(); ((Frame) (imageFrames.elementAt(i))).setTitle("Locked: " + titles[i]); ((Frame) (imageFrames.elementAt(i))).setEnabled(false); userInterface.unregisterFrame((Frame) (imageFrames.elementAt(i))); } } if (isRunInSeparateThread()) { // Start the thread as a low priority because we wish to still have user interface work // fast. if (mathAlgo.startMethod(Thread.MIN_PRIORITY) == false) { MipavUtil.displayError("A thread is already running on this object"); } } else { mathAlgo.run(); } } catch (OutOfMemoryError x) { System.gc(); MipavUtil.displayError("Dialog Concatenation: unable to allocate enough memory"); return; } }
protected void process() { int i, j, len, ch, chunkLength; long progOff, progLen; float f1; // io AudioFile inF = null; AudioFile outF = null; AudioFileDescr inStream; AudioFileDescr outStream; FloatFile[] floatF = null; File tempFile[] = null; // buffers float[][] inBuf, outBuf; float[] win; float[] convBuf1, convBuf2; float[] tempFlt; int inChanNum, inLength, inputStep, outputStep, winSize; int transLen, skip, inputLen, outputLen, fltLen; int framesRead, framesWritten; float warp, a1, b0, b1, x0, x1, y0, y1, b0init; Param ampRef = new Param(1.0, Param.ABS_AMP); // transform-Referenz Param peakGain; float gain = 1.0f; // gain abs amp float maxAmp = 0.0f; PathField ggOutput; topLevel: try { // ---- open input, output ---- // input inF = AudioFile.openAsRead(new File(pr.text[PR_INPUTFILE])); inStream = inF.getDescr(); inChanNum = inStream.channels; inLength = (int) inStream.length; // this helps to prevent errors from empty files! if ((inLength * inChanNum) < 1) throw new EOFException(ERR_EMPTY); // .... check running .... if (!threadRunning) break topLevel; // output ggOutput = (PathField) gui.getItemObj(GG_OUTPUTFILE); if (ggOutput == null) throw new IOException(ERR_MISSINGPROP); outStream = new AudioFileDescr(inStream); ggOutput.fillStream(outStream); outF = AudioFile.openAsWrite(outStream); // .... check running .... if (!threadRunning) break topLevel; // ---- parameter inits ---- warp = Math.max(-0.98f, Math.min(0.98f, (float) (pr.para[PR_WARP].val / 100))); // DAFx2000 'b' f1 = (1.0f - warp) / (1.0f + warp); // DAFx2000 (25) winSize = 32 << pr.intg[PR_FRAMESIZE]; // DAFx2000 'N' j = winSize >> 1; transLen = (int) (f1 * winSize + 0.5f); // DAFx2000 'P' (26) i = pr.intg[PR_OVERLAP] + 1; while (((float) transLen / (float) i) > j) i++; inputStep = (int) (((float) transLen / (float) i) + 0.5f); // DAFx2000 'L' fltLen = Math.max(winSize, transLen); // System.out.println( "inputStep "+inputStep+"; winSize "+winSize+"; transLen "+transLen+"; // fltLen "+fltLen+"; warp "+warp+"; � "+f1 ); win = Filter.createFullWindow(winSize, Filter.WIN_HANNING); // DAFx2000 (27) outputStep = inputStep; b0init = (float) Math.sqrt(1.0f - warp * warp); progOff = 0; progLen = (long) inLength * (2 + inChanNum); // + winSize; tempFlt = new float[fltLen]; inputLen = winSize + inputStep; inBuf = new float[inChanNum][inputLen]; outputLen = transLen + outputStep; outBuf = new float[inChanNum][outputLen]; // normalization requires temp files if (pr.intg[PR_GAINTYPE] == GAIN_UNITY) { tempFile = new File[inChanNum]; floatF = new FloatFile[inChanNum]; for (ch = 0; ch < inChanNum; ch++) { // first zero them because an exception might be thrown tempFile[ch] = null; floatF[ch] = null; } for (ch = 0; ch < inChanNum; ch++) { tempFile[ch] = IOUtil.createTempFile(); floatF[ch] = new FloatFile(tempFile[ch], GenericFile.MODE_OUTPUT); } progLen += (long) inLength; } else { gain = (float) ((Param.transform(pr.para[PR_GAIN], Param.ABS_AMP, ampRef, null)).val); } // .... check running .... if (!threadRunning) break topLevel; // ----==================== the real stuff ====================---- framesRead = 0; framesWritten = 0; skip = 0; while (threadRunning && (framesWritten < inLength)) { chunkLength = Math.min(inputLen, inLength - framesRead + skip); // ---- read input chunk ---- len = Math.max(0, chunkLength - skip); inF.readFrames(inBuf, skip, len); framesRead += len; progOff += len; // off += len; // .... progress .... setProgression((float) progOff / (float) progLen); // .... check running .... if (!threadRunning) break topLevel; // zero padding if (chunkLength < inputLen) { for (ch = 0; ch < inChanNum; ch++) { convBuf1 = inBuf[ch]; for (i = chunkLength; i < convBuf1.length; i++) { convBuf1[i] = 0.0f; } } } for (ch = 0; threadRunning && (ch < inChanNum); ch++) { convBuf1 = inBuf[ch]; convBuf2 = outBuf[ch]; for (i = 0, j = fltLen; i < winSize; i++) { tempFlt[--j] = convBuf1[i] * win[i]; } while (j > 0) { tempFlt[--j] = 0.0f; } a1 = -warp; // inital allpass b0 = b0init; b1 = 0.0f; for (j = 0; j < transLen; j++) { x1 = 0.0f; y1 = 0.0f; // for( i = 0; i < transLen; i++ ) { // DAFx2000 (2 resp. 3) for (i = 0; i < fltLen; i++) { // DAFx2000 (2 resp. 3) x0 = tempFlt[i]; y0 = b0 * x0 + b1 * x1 - a1 * y1; tempFlt[i] = y0; // (work with double precision while computing cascades) y1 = y0; x1 = x0; } a1 = -warp; // cascaded allpasses b0 = -warp; b1 = 1.0f; convBuf2[j] += (float) y1; } // .... progress .... progOff += chunkLength - skip; setProgression((float) progOff / (float) progLen); } // for channels // .... check running .... if (!threadRunning) break topLevel; chunkLength = Math.min(outputStep, inLength - framesWritten); // ---- write output chunk ---- if (floatF != null) { for (ch = 0; ch < inChanNum; ch++) { floatF[ch].writeFloats(outBuf[ch], 0, chunkLength); } progOff += chunkLength; // off += len; framesWritten += chunkLength; // .... progress .... setProgression((float) progOff / (float) progLen); } else { for (ch = 0; ch < inChanNum; ch++) { Util.mult(outBuf[ch], 0, chunkLength, gain); } outF.writeFrames(outBuf, 0, chunkLength); progOff += chunkLength; // off += len; framesWritten += chunkLength; // .... progress .... setProgression((float) progOff / (float) progLen); } // .... check running .... if (!threadRunning) break topLevel; // check max amp for (ch = 0; ch < inChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { f1 = Math.abs(convBuf1[i]); if (f1 > maxAmp) { maxAmp = f1; } } } // overlaps skip = winSize; for (ch = 0; ch < inChanNum; ch++) { System.arraycopy(inBuf[ch], inputStep, inBuf[ch], 0, winSize); convBuf1 = outBuf[ch]; System.arraycopy(convBuf1, outputStep, convBuf1, 0, transLen); for (i = transLen; i < outputLen; ) { convBuf1[i++] = 0.0f; } } } // until framesWritten == outLength // .... check running .... if (!threadRunning) break topLevel; // ----==================== normalize output ====================---- if (pr.intg[PR_GAINTYPE] == GAIN_UNITY) { peakGain = new Param((double) maxAmp, Param.ABS_AMP); gain = (float) (Param.transform( pr.para[PR_GAIN], Param.ABS_AMP, new Param(1.0 / peakGain.val, peakGain.unit), null)) .val; normalizeAudioFile(floatF, outF, inBuf, gain, 1.0f); maxAmp *= gain; for (ch = 0; ch < inChanNum; ch++) { floatF[ch].cleanUp(); floatF[ch] = null; tempFile[ch].delete(); tempFile[ch] = null; } } // .... check running .... if (!threadRunning) break topLevel; // ---- Finish ---- outF.close(); outF = null; outStream = null; inF.close(); inF = null; inStream = null; inBuf = null; // inform about clipping/ low level handleClipping(maxAmp); } catch (IOException e1) { setError(e1); } catch (OutOfMemoryError e2) { inStream = null; outStream = null; inBuf = null; convBuf1 = null; convBuf2 = null; System.gc(); setError(new Exception(ERR_MEMORY)); ; } // ---- cleanup (topLevel) ---- if (inF != null) { inF.cleanUp(); inF = null; } if (outF != null) { outF.cleanUp(); outF = null; } if (floatF != null) { for (ch = 0; ch < floatF.length; ch++) { if (floatF[ch] != null) { floatF[ch].cleanUp(); floatF[ch] = null; } if (tempFile[ch] != null) { tempFile[ch].delete(); tempFile[ch] = null; } } } } // process()
/** Sets up the GUI (panels, buttons, etc) and displays it on the screen. */ private void init() { DecimalFormat df; int xUnits; String unitStr; String distStr; setForeground(Color.black); setTitle("Center Distances version 2 07/14/08"); df = new DecimalFormat("0.000E0"); GridBagConstraints gbc = new GridBagConstraints(); int yPos = 0; gbc.gridwidth = 1; gbc.gridheight = 1; gbc.anchor = GridBagConstraints.WEST; gbc.weightx = 1; gbc.insets = new Insets(3, 3, 3, 3); gbc.fill = GridBagConstraints.HORIZONTAL; gbc.gridx = 0; gbc.gridy = yPos++; JPanel mainPanel = new JPanel(new GridBagLayout()); mainPanel.setForeground(Color.black); mainPanel.setBorder(buildTitledBorder("Input parameters")); blueMinLabel = new JLabel("Minimum number of blue pixels per nucleus"); blueMinLabel.setForeground(Color.black); blueMinLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(blueMinLabel, gbc); blueMinText = new JTextField(5); if (image.getNDims() == 2) { blueMinText.setText("1000"); } else { blueMinText.setText("20000"); } blueMinText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(blueMinText, gbc); redMinLabel = new JLabel("Minimum red pixel count"); redMinLabel.setForeground(Color.black); redMinLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(redMinLabel, gbc); redMinText = new JTextField(5); redMinText.setText("50"); redMinText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(redMinText, gbc); redFractionLabel = new JLabel("Fraction of red pixels to consider"); redFractionLabel.setForeground(Color.black); redFractionLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(redFractionLabel, gbc); redFractionText = new JTextField(5); redFractionText.setText("0.15"); redFractionText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(redFractionText, gbc); xUnits = image.getFileInfo(0).getUnitsOfMeasure()[0]; if (xUnits != Unit.UNKNOWN_MEASURE.getLegacyNum()) { unitStr = (Unit.getUnitFromLegacyNum(xUnits)).toString(); greenMergingLabel = new JLabel("Green merging radius around peak (" + unitStr + ")"); } else { greenMergingLabel = new JLabel("Green merging radius around peak"); } greenMergingLabel.setForeground(Color.black); greenMergingLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(greenMergingLabel, gbc); if (image.getNDims() == 2) { // mergingDistance = 8.0f * image.getFileInfo(0).getResolutions()[0]; mergingDistance = 0.0f; } else { // mergingDistance = 4.0f * image.getFileInfo(0).getResolutions()[0]; mergingDistance = 0.0f; } distStr = df.format(mergingDistance); greenMergingText = new JTextField(10); greenMergingText.setText(distStr); greenMergingText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(greenMergingText, gbc); greenMinLabel = new JLabel("Minimum green pixel count"); greenMinLabel.setForeground(Color.black); greenMinLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(greenMinLabel, gbc); greenMinText = new JTextField(5); greenMinText.setText("10"); greenMinText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(greenMinText, gbc); greenFractionLabel = new JLabel("Fraction of green pixels to consider"); greenFractionLabel.setForeground(Color.black); greenFractionLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(greenFractionLabel, gbc); greenFractionText = new JTextField(5); greenFractionText.setText("0.01"); greenFractionText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(greenFractionText, gbc); greenRegionsLabel = new JLabel("Green regions per cell"); greenRegionsLabel.setForeground(Color.black); greenRegionsLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(greenRegionsLabel, gbc); JPanel buttonPanel = new JPanel(new GridBagLayout()); greenGroup = new ButtonGroup(); oneButton = new JRadioButton("1", false); oneButton.setForeground(Color.black); oneButton.setFont(serif12); greenGroup.add(oneButton); gbc.gridx = 0; gbc.gridy = 0; buttonPanel.add(oneButton, gbc); twoButton = new JRadioButton("2", true); twoButton.setForeground(Color.black); twoButton.setFont(serif12); greenGroup.add(twoButton); gbc.gridx = 1; gbc.gridy = 0; buttonPanel.add(twoButton, gbc); threeButton = new JRadioButton("3", false); threeButton.setForeground(Color.black); threeButton.setFont(serif12); greenGroup.add(threeButton); gbc.gridx = 2; gbc.gridy = 0; buttonPanel.add(threeButton, gbc); fourButton = new JRadioButton("4", false); fourButton.setForeground(Color.black); fourButton.setFont(serif12); greenGroup.add(fourButton); gbc.gridx = 3; gbc.gridy = 0; buttonPanel.add(fourButton, gbc); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(buttonPanel, gbc); twoBox = new JCheckBox("Use 2 top gray levels in green segmentation", true); twoBox.setForeground(Color.black); twoBox.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos++; mainPanel.add(twoBox, gbc); blueValueLabel = new JLabel("Fraction of blue transition from image min to max at nucleus boundary"); blueValueLabel.setForeground(Color.black); blueValueLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(blueValueLabel, gbc); blueValueText = new JTextField(5); blueValueText.setText("0.15"); blueValueText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(blueValueText, gbc); blueSmoothBox = new JCheckBox("Smooth blue VOI contours with AlgorithmBSmooth", true); blueSmoothBox.setForeground(Color.black); blueSmoothBox.setFont(serif12); blueSmoothBox.addActionListener(this); gbc.gridx = 0; gbc.gridy = yPos++; mainPanel.add(blueSmoothBox, gbc); interpolationLabel = new JLabel("Number of interpolation points determined by divisor (> 1.0)"); interpolationLabel.setForeground(Color.black); interpolationLabel.setFont(serif12); gbc.gridx = 0; gbc.gridy = yPos; mainPanel.add(interpolationLabel, gbc); interpolationText = new JTextField(5); interpolationText.setText("24.0"); interpolationText.setFont(serif12); gbc.gridx = 1; gbc.gridy = yPos++; mainPanel.add(interpolationText, gbc); getContentPane().add(mainPanel, BorderLayout.CENTER); getContentPane().add(buildButtons(), BorderLayout.SOUTH); pack(); setVisible(true); setResizable(false); System.gc(); } // end init()
protected void process() { int i, j, ch, len, off, chunkLength; long progOff, progLen; float f1, f2; double d1; boolean extraAudioFile; // io AudioFile inF = null; AudioFile outF = null; AudioFile envInF = null; AudioFile envOutF = null; AudioFileDescr inStream = null; AudioFileDescr outStream = null; AudioFileDescr envInStream = null; AudioFileDescr envOutStream = null; FloatFile[] outFloatF = null; FloatFile[] envFloatF = null; File outTempFile[] = null; File envTempFile[] = null; int inChanNum, outChanNum, envInChanNum, envOutChanNum, shapeChanNum; int[][] shapeChan = null; int[][] inChan = null; float[][] shapeChanWeight = null; float[][] inChanWeight = null; // buffers float[][] inBuf = null; // Sound-In float[][] outBuf = null; // Sound-Out float[][] inEnvBuf = null; // Envelope of Input float[][] shapeEnvBuf = null; // Envelope of Shaper float[][] envInBuf = null; // Direct-In of Shaper-File float[] convBuf1, convBuf2; int inLength, outLength, envInLength, envOutLength; int framesRead, framesWritten; // re sound-files int framesRead2, framesWritten2; // re env-files Param ampRef = new Param(1.0, Param.ABS_AMP); // transform-Referenz Param peakGain; float gain = 1.0f; // gain abs amp float envGain = 1.0f; // gain abs amp float maxAmp = 0.0f; float envMaxAmp = 0.0f; float maxChange; int average, avrOff; double[] inEnergy, envInEnergy; PathField ggOutput; topLevel: try { // ---- open input, output; init ---- // input inF = AudioFile.openAsRead(new File(pr.text[PR_INPUTFILE])); inStream = inF.getDescr(); inChanNum = inStream.channels; inLength = (int) inStream.length; // this helps to prevent errors from empty files! if ((inLength < 1) || (inChanNum < 1)) throw new EOFException(ERR_EMPTY); // .... check running .... if (!threadRunning) break topLevel; envInLength = 0; envInChanNum = inChanNum; shapeChanNum = 0; // shape input switch (pr.intg[PR_ENVSOURCE]) { case SRC_SOUNDFILE: case SRC_ENVFILE: envInF = AudioFile.openAsRead(new File(pr.text[PR_ENVINFILE])); envInStream = envInF.getDescr(); envInChanNum = envInStream.channels; shapeChanNum = envInChanNum; envInLength = (int) envInStream.length; // this helps to prevent errors from empty files! if ((envInLength < 1) || (envInChanNum < 1)) throw new EOFException(ERR_EMPTY); i = Math.min(inLength, envInLength); inLength = i; envInLength = i; break; case SRC_ENV: if (pr.bool[PR_RIGHTCHAN]) { shapeChanNum = 2; envInChanNum = Math.max(envInChanNum, shapeChanNum); // ggf. mono => stereo } else { shapeChanNum = 1; } break; case SRC_INPUT: shapeChanNum = inChanNum; break; } // .... check running .... if (!threadRunning) break topLevel; outChanNum = Math.max(inChanNum, envInChanNum); outLength = inLength; shapeChan = new int[outChanNum][2]; shapeChanWeight = new float[outChanNum][2]; inChan = new int[outChanNum][2]; inChanWeight = new float[outChanNum][2]; extraAudioFile = (envInF != null) && (pr.intg[PR_ENVSOURCE] == SRC_SOUNDFILE); // not if SRC_ENVFILE!!! // calc weights for (ch = 0; ch < outChanNum; ch++) { if (shapeChanNum == 1) { shapeChan[ch][0] = 0; shapeChan[ch][1] = 0; shapeChanWeight[ch][0] = 1.0f; shapeChanWeight[ch][1] = 0.0f; } else { f1 = ((float) ch / (float) (outChanNum - 1)) * (float) (shapeChanNum - 1); shapeChan[ch][0] = (int) f1; // Math.max verhindert ArrayIndex-Fehler shapeChan[ch][1] = Math.min((int) f1 + 1, shapeChanNum - 1); // (Weight ist dabei eh Null) f1 %= 1.0f; shapeChanWeight[ch][0] = 1.0f - f1; shapeChanWeight[ch][1] = f1; } if (inChanNum == 1) { inChan[ch][0] = 0; inChan[ch][1] = 0; inChanWeight[ch][0] = 1.0f; inChanWeight[ch][1] = 0.0f; } else { f1 = ((float) ch / (float) (outChanNum - 1)) * (float) (inChanNum - 1); inChan[ch][0] = (int) f1; inChan[ch][1] = Math.min((int) f1 + 1, inChanNum - 1); f1 %= 1.0f; inChanWeight[ch][0] = 1.0f - f1; inChanWeight[ch][1] = f1; } /* for( i = 0; i < 2; i++ ) { System.out.println( "shapeChan["+ch+"]["+i+"] = "+shapeChan[ch][i] ); System.out.println( "shapeWeig["+ch+"]["+i+"] = "+shapeChanWeight[ch][i] ); System.out.println( "inputChan["+ch+"]["+i+"] = "+inChan[ch][i] ); System.out.println( "inputWeig["+ch+"]["+i+"] = "+inChanWeight[ch][i] ); } */ } // output ggOutput = (PathField) gui.getItemObj(GG_OUTPUTFILE); if (ggOutput == null) throw new IOException(ERR_MISSINGPROP); outStream = new AudioFileDescr(inStream); ggOutput.fillStream(outStream); outStream.channels = outChanNum; outF = AudioFile.openAsWrite(outStream); // .... check running .... if (!threadRunning) break topLevel; envOutLength = 0; envOutChanNum = 0; // envelope output if (pr.bool[PR_ENVOUTPUT]) { ggOutput = (PathField) gui.getItemObj(GG_ENVOUTFILE); if (ggOutput == null) throw new IOException(ERR_MISSINGPROP); envOutStream = new AudioFileDescr(inStream); ggOutput.fillStream(envOutStream); envOutStream.file = new File(pr.text[PR_ENVOUTFILE]); envOutF = AudioFile.openAsWrite(envOutStream); envOutLength = inLength; envOutChanNum = inChanNum; } // .... check running .... if (!threadRunning) break topLevel; // average buffer size d1 = Param.transform( pr.para[PR_AVERAGE], Param.ABS_MS, new Param(AudioFileDescr.samplesToMillis(inStream, inLength), Param.ABS_MS), null) .val; // average in millis average = ((int) (AudioFileDescr.millisToSamples(inStream, d1) + 0.5) & ~1) + 1; // always odd avrOff = (average >> 1) + 1; // first element needed for subtraction (see calcEnv()) progOff = 0; progLen = (long) Math.max(average - avrOff, inLength) + (long) (extraAudioFile ? Math.max(average - avrOff, envInLength) : envInLength) + (long) outLength + (long) envOutLength; // normalization requires temp files if (pr.intg[PR_GAINTYPE] == GAIN_UNITY) { outTempFile = new File[outChanNum]; outFloatF = new FloatFile[outChanNum]; for (ch = 0; ch < outChanNum; ch++) { // first zero them because an exception might be thrown outTempFile[ch] = null; outFloatF[ch] = null; } for (ch = 0; ch < outChanNum; ch++) { outTempFile[ch] = IOUtil.createTempFile(); outFloatF[ch] = new FloatFile(outTempFile[ch], GenericFile.MODE_OUTPUT); } progLen += (long) outLength; } else { gain = (float) (Param.transform(pr.para[PR_GAIN], Param.ABS_AMP, ampRef, null)).val; } // .... check running .... if (!threadRunning) break topLevel; // normalization requires temp files if (pr.intg[PR_ENVGAINTYPE] == GAIN_UNITY) { envTempFile = new File[envOutChanNum]; envFloatF = new FloatFile[envOutChanNum]; for (ch = 0; ch < envOutChanNum; ch++) { // first zero them because an exception might be thrown envTempFile[ch] = null; envFloatF[ch] = null; } for (ch = 0; ch < envOutChanNum; ch++) { envTempFile[ch] = IOUtil.createTempFile(); envFloatF[ch] = new FloatFile(envTempFile[ch], GenericFile.MODE_OUTPUT); } progLen += (long) envOutLength; } else { envGain = (float) (Param.transform(pr.para[PR_ENVGAIN], Param.ABS_AMP, ampRef, null)).val; } // .... check running .... if (!threadRunning) break topLevel; // ---- further inits ---- maxChange = (float) (Param.transform(pr.para[PR_MAXCHANGE], Param.ABS_AMP, ampRef, null)).val; inBuf = new float[inChanNum][8192 + average]; Util.clear(inBuf); outBuf = new float[outChanNum][8192]; Util.clear(outBuf); if (extraAudioFile) { envInBuf = new float[envInChanNum][8192 + average]; Util.clear(envInBuf); } inEnvBuf = new float[inChanNum][8192]; // = envOutBuf Util.clear(inEnvBuf); shapeEnvBuf = new float[envInChanNum][8192]; Util.clear(shapeEnvBuf); inEnergy = new double[inChanNum]; for (ch = 0; ch < inChanNum; ch++) { inEnergy[ch] = 0.0; } envInEnergy = new double[envInChanNum]; for (ch = 0; ch < envInChanNum; ch++) { envInEnergy[ch] = 0.0; } // System.out.println( "inLength "+inLength+"; envInLength "+envInLength+"; envOutLength // "+envOutLength+"; outLength "+outLength ); // System.out.println( "average "+average+"; avrOff "+avrOff ); // ----==================== buffer init ====================---- framesRead = 0; // re inF framesRead2 = 0; // re envInF // ---- init buffers ---- for (off = avrOff; threadRunning && (off < average); ) { len = Math.min(inLength - framesRead, Math.min(8192, average - off)); if (len == 0) break; inF.readFrames(inBuf, off, len); // calc initial energy per channel (see calcEnv()) for (ch = 0; ch < inChanNum; ch++) { convBuf1 = inBuf[ch]; d1 = 0.0; for (i = 0, j = off; i < len; i++) { f1 = convBuf1[j++]; d1 += f1 * f1; } inEnergy[ch] += d1; } framesRead += len; off += len; progOff += len; // .... progress .... setProgression((float) progOff / (float) progLen); } // zero padding bereits durch initialisierung mit Util.clear() passiert! if (extraAudioFile) { for (off = avrOff; threadRunning && (off < average); ) { len = Math.min(envInLength - framesRead2, Math.min(8192, average - off)); if (len == 0) break; envInF.readFrames(envInBuf, off, len); // calc initial energy per channel (see calcEnv()) for (ch = 0; ch < envInChanNum; ch++) { convBuf1 = envInBuf[ch]; d1 = 0.0; for (i = 0, j = off; i < len; i++) { f1 = convBuf1[j++]; d1 += f1 * f1; } envInEnergy[ch] += d1; } framesRead2 += len; off += len; progOff += len; // .... progress .... setProgression((float) progOff / (float) progLen); } // zero padding bereits durch initialisierung mit Util.clear() passiert! } // .... check running .... if (!threadRunning) break topLevel; // ----==================== the real stuff ====================---- framesWritten = 0; // re OutF framesWritten2 = 0; // re envOutF while (threadRunning && (framesWritten < outLength)) { chunkLength = Math.min(8192, outLength - framesWritten); // ---- read input chunk ---- len = Math.min(inLength - framesRead, chunkLength); inF.readFrames(inBuf, average, len); // zero padding for (ch = 0; ch < inChanNum; ch++) { convBuf1 = inBuf[ch]; for (i = len, j = len + average; i < chunkLength; i++) { convBuf1[j++] = 0.0f; } } framesRead += len; progOff += len; // .... progress .... setProgression((float) progOff / (float) progLen); // .... check running .... if (!threadRunning) break topLevel; // ---- read input env chunk ---- if (envInF != null) { len = Math.min(envInLength - framesRead2, chunkLength); if (extraAudioFile) { // ........ needs averaging ........ envInF.readFrames(envInBuf, average, len); // zero padding for (ch = 0; ch < envInChanNum; ch++) { convBuf1 = envInBuf[ch]; for (i = len, j = len + average; i < chunkLength; i++) { convBuf1[j++] = 0.0f; } } } else { // ........ is already env ........ envInF.readFrames(shapeEnvBuf, 0, len); // zero padding for (ch = 0; ch < envInChanNum; ch++) { convBuf1 = shapeEnvBuf[ch]; for (i = len; i < chunkLength; i++) { convBuf1[i] = 0.0f; } } } framesRead2 += len; progOff += len; // .... progress .... setProgression((float) progOff / (float) progLen); } // .... check running .... if (!threadRunning) break topLevel; // ---- calc input envelope ---- for (ch = 0; ch < inChanNum; ch++) { inEnergy[ch] = calcEnv(inBuf[ch], inEnvBuf[ch], average, chunkLength, inEnergy[ch]); } // ---- write output env file ---- if (pr.bool[PR_ENVOUTPUT]) { if (envFloatF != null) { // i.e. unity gain for (ch = 0; ch < envOutChanNum; ch++) { convBuf1 = inEnvBuf[ch]; for (i = 0; i < chunkLength; i++) { // measure max amp f1 = Math.abs(convBuf1[i]); if (f1 > envMaxAmp) { envMaxAmp = f1; } } envFloatF[ch].writeFloats(convBuf1, 0, chunkLength); } } else { // i.e. abs gain for (ch = 0; ch < envOutChanNum; ch++) { convBuf1 = inEnvBuf[ch]; for (i = 0; i < chunkLength; i++) { // measure max amp + adjust gain f1 = Math.abs(convBuf1[i]); convBuf1[i] *= envGain; if (f1 > envMaxAmp) { envMaxAmp = f1; } } } envOutF.writeFrames(inEnvBuf, 0, chunkLength); } framesWritten2 += chunkLength; progOff += chunkLength; // .... progress .... setProgression((float) progOff / (float) progLen); } // .... check running .... if (!threadRunning) break topLevel; // ---- calc shape envelope ---- switch (pr.intg[PR_ENVSOURCE]) { case SRC_INPUT: // shape env = input env for (ch = 0; ch < inChanNum; ch++) { System.arraycopy(inEnvBuf[ch], 0, shapeEnvBuf[ch], 0, chunkLength); } break; case SRC_SOUNDFILE: // calc shape env from envInBuf for (ch = 0; ch < envInChanNum; ch++) { envInEnergy[ch] = calcEnv(envInBuf[ch], shapeEnvBuf[ch], average, chunkLength, envInEnergy[ch]); } break; case SRC_ENVFILE: // nothing to do, we have already loaded the env break; // in the correct buffer case SRC_ENV: throw new IOException("Graphic env not yet supported"); } // ---- calc output ---- // first generate output envelope switch (pr.intg[PR_MODE]) { case MODE_SUPERPOSE: if (!pr.bool[PR_INVERT]) { // multiply by shape for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { f1 = shapeEnvBuf[shapeChan[ch][0]][i] * shapeChanWeight[ch][0] + shapeEnvBuf[shapeChan[ch][1]][i] * shapeChanWeight[ch][1]; convBuf1[i] = Math.min(maxChange, f1); } } } else { // divide by shape for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { f1 = shapeEnvBuf[shapeChan[ch][0]][i] * shapeChanWeight[ch][0] + shapeEnvBuf[shapeChan[ch][1]][i] * shapeChanWeight[ch][1]; if (f1 > 0.0f) { convBuf1[i] = Math.min(maxChange, 1.0f / f1); } else { convBuf1[i] = maxChange; } } } } break; case MODE_REPLACE: if (!pr.bool[PR_INVERT]) { // shape / input for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { f1 = shapeEnvBuf[shapeChan[ch][0]][i] * shapeChanWeight[ch][0] + shapeEnvBuf[shapeChan[ch][1]][i] * shapeChanWeight[ch][1]; f2 = inEnvBuf[inChan[ch][0]][i] * inChanWeight[ch][0] + inEnvBuf[inChan[ch][1]][i] * inChanWeight[ch][1]; if (f2 > 0.0f) { convBuf1[i] = Math.min(maxChange, f1 / f2); } else { convBuf1[i] = 0.0f; // input ist eh ueberall null, somit unveraenderlich } } } } else { // 1 / (shape * input) for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { f1 = shapeEnvBuf[shapeChan[ch][0]][i] * shapeChanWeight[ch][0] + shapeEnvBuf[shapeChan[ch][1]][i] * shapeChanWeight[ch][1]; f1 *= inEnvBuf[inChan[ch][0]][i] * inChanWeight[ch][0] + inEnvBuf[inChan[ch][1]][i] * inChanWeight[ch][1]; if (f1 > 0.0f) { convBuf1[i] = Math.min(maxChange, 1.0f / f1); } else { convBuf1[i] = maxChange; } } } } break; } // then multiply input bites if (inChanNum == outChanNum) { // no weighting - use faster routine for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; convBuf2 = inBuf[ch]; for (i = 0, j = avrOff; i < chunkLength; i++, j++) { convBuf1[i] *= convBuf2[j]; } } } else { for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0, j = avrOff; i < chunkLength; i++, j++) { f1 = inBuf[inChan[ch][0]][j] * inChanWeight[ch][0] + inBuf[inChan[ch][1]][j] * inChanWeight[ch][1]; convBuf1[i] *= f1; } } } // ---- write output sound file ---- if (outFloatF != null) { // i.e. unity gain for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { // measure max amp f1 = Math.abs(convBuf1[i]); if (f1 > maxAmp) { maxAmp = f1; } } outFloatF[ch].writeFloats(convBuf1, 0, chunkLength); } } else { // i.e. abs gain for (ch = 0; ch < outChanNum; ch++) { convBuf1 = outBuf[ch]; for (i = 0; i < chunkLength; i++) { // measure max amp + adjust gain f1 = Math.abs(convBuf1[i]); convBuf1[i] *= gain; if (f1 > maxAmp) { maxAmp = f1; } } } outF.writeFrames(outBuf, 0, chunkLength); } framesWritten += chunkLength; progOff += chunkLength; // .... progress .... setProgression((float) progOff / (float) progLen); // ---- shift buffers ---- for (ch = 0; ch < inChanNum; ch++) { // zero padding is performed after AudioFile.readFrames()! System.arraycopy(inBuf[ch], chunkLength, inBuf[ch], 0, average); } if (extraAudioFile) { for (ch = 0; ch < envInChanNum; ch++) { // zero padding is performed after AudioFile.readFrames()! System.arraycopy(envInBuf[ch], chunkLength, envInBuf[ch], 0, average); } } } // until framesWritten == outLength // .... check running .... if (!threadRunning) break topLevel; // ---- normalize output ---- // sound file if (pr.intg[PR_GAINTYPE] == GAIN_UNITY) { peakGain = new Param((double) maxAmp, Param.ABS_AMP); gain = (float) (Param.transform( pr.para[PR_GAIN], Param.ABS_AMP, new Param(1.0 / peakGain.val, peakGain.unit), null)) .val; f1 = 1.0f; if ((envOutF != null) && (pr.intg[PR_ENVGAINTYPE] == GAIN_UNITY)) { // leave prog space f1 = (1.0f + getProgression()) / 2; } normalizeAudioFile(outFloatF, outF, outBuf, gain, f1); for (ch = 0; ch < outChanNum; ch++) { outFloatF[ch].cleanUp(); outFloatF[ch] = null; outTempFile[ch].delete(); outTempFile[ch] = null; } } // .... check running .... if (!threadRunning) break topLevel; // envelope file if ((envOutF != null) && (pr.intg[PR_ENVGAINTYPE] == GAIN_UNITY)) { peakGain = new Param((double) envMaxAmp, Param.ABS_AMP); envGain = (float) (Param.transform( pr.para[PR_ENVGAIN], Param.ABS_AMP, new Param(1.0 / peakGain.val, peakGain.unit), null)) .val; normalizeAudioFile(envFloatF, envOutF, inEnvBuf, envGain, 1.0f); for (ch = 0; ch < envOutChanNum; ch++) { envFloatF[ch].cleanUp(); envFloatF[ch] = null; envTempFile[ch].delete(); envTempFile[ch] = null; } } // .... check running .... if (!threadRunning) break topLevel; // ---- Finish ---- outF.close(); outF = null; outStream = null; if (envOutF != null) { envOutF.close(); envOutF = null; envOutStream = null; } if (envInF != null) { envInF.close(); envInF = null; envInStream = null; } inF.close(); inF = null; inStream = null; outBuf = null; inBuf = null; inEnvBuf = null; envInBuf = null; shapeEnvBuf = null; // inform about clipping/ low level maxAmp *= gain; handleClipping(maxAmp); envMaxAmp *= envGain; // handleClipping( envMaxAmp ); // ;( routine nicht flexibel genug! } catch (IOException e1) { setError(e1); } catch (OutOfMemoryError e2) { inStream = null; outStream = null; envInStream = null; envOutStream = null; inBuf = null; outBuf = null; inEnvBuf = null; envInBuf = null; shapeEnvBuf = null; convBuf1 = null; convBuf2 = null; System.gc(); setError(new Exception(ERR_MEMORY)); ; } // ---- cleanup (topLevel) ---- if (inF != null) { inF.cleanUp(); inF = null; } if (outF != null) { outF.cleanUp(); outF = null; } if (envInF != null) { envInF.cleanUp(); envInF = null; } if (envOutF != null) { envOutF.cleanUp(); envOutF = null; } if (outFloatF != null) { for (ch = 0; ch < outFloatF.length; ch++) { if (outFloatF[ch] != null) outFloatF[ch].cleanUp(); if (outTempFile[ch] != null) outTempFile[ch].delete(); } } if (envFloatF != null) { for (ch = 0; ch < envFloatF.length; ch++) { if (envFloatF[ch] != null) envFloatF[ch].cleanUp(); if (envTempFile[ch] != null) envTempFile[ch].delete(); } } } // process()
public void assertTiming() { assert expectedMs != 0 : "Must call .expect() before run test"; if (COVERAGE_ENABLED_BUILD) return; while (true) { attempts--; long start; try { if (setup != null) setup.run(); start = System.currentTimeMillis(); test.run(); } catch (Throwable throwable) { throw new RuntimeException(throwable); } long finish = System.currentTimeMillis(); long duration = finish - start; int expectedOnMyMachine = expectedMs; if (adjustForCPU) { expectedOnMyMachine = adjust(expectedOnMyMachine, Timings.CPU_TIMING, Timings.ETALON_CPU_TIMING); expectedOnMyMachine = usesAllCPUCores ? expectedOnMyMachine * 8 / JobSchedulerImpl.CORES_COUNT : expectedOnMyMachine; } if (adjustForIO) { expectedOnMyMachine = adjust(expectedOnMyMachine, Timings.IO_TIMING, Timings.ETALON_IO_TIMING); } // Allow 10% more in case of test machine is busy. String logMessage = message; if (duration > expectedOnMyMachine) { int percentage = (int) (100.0 * (duration - expectedOnMyMachine) / expectedOnMyMachine); logMessage += ": " + percentage + "% longer"; } logMessage += ". Expected: " + formatTime(expectedOnMyMachine) + ". Actual: " + formatTime(duration) + "." + Timings.getStatistics(); final double acceptableChangeFactor = 1.1; if (duration < expectedOnMyMachine) { int percentage = (int) (100.0 * (expectedOnMyMachine - duration) / expectedOnMyMachine); logMessage = percentage + "% faster. " + logMessage; TeamCityLogger.info(logMessage); System.out.println("SUCCESS: " + logMessage); } else if (duration < expectedOnMyMachine * acceptableChangeFactor) { TeamCityLogger.warning(logMessage, null); System.out.println("WARNING: " + logMessage); } else { // try one more time if (attempts == 0) { // try { // Object result = // Class.forName("com.intellij.util.ProfilingUtil").getMethod("captureCPUSnapshot").invoke(null); // System.err.println("CPU snapshot captured in '"+result+"'"); // } // catch (Exception e) { // } throw new AssertionFailedError(logMessage); } System.gc(); System.gc(); System.gc(); String s = "Another epic fail (remaining attempts: " + attempts + "): " + logMessage; TeamCityLogger.warning(s, null); System.err.println(s); // if (attempts == 1) { // try { // // Class.forName("com.intellij.util.ProfilingUtil").getMethod("startCPUProfiling").invoke(null); // } // catch (Exception e) { // } // } continue; } break; } }
public int print(java.awt.Graphics pg, java.awt.print.PageFormat pageFormat, int pageIndex) throws java.awt.print.PrinterException { if (pageIndex >= m_maxNumPage || m_bi == null) { return NO_SUCH_PAGE; } pg.translate((int) pageFormat.getImageableX() + 1, (int) pageFormat.getImageableY() + 1); int wPage = (int) pageFormat.getImageableWidth() + 1; int hPage = (int) pageFormat.getImageableHeight() + 1; double scale = percentSize / 100.0; wPage = (int) (wPage / scale); hPage = (int) (hPage / scale); /* int wPage = (int)pageFormat.getImageableWidth(); int hPage = (int)pageFormat.getImageableHeight(); int w = m_bi.getWidth(this); int h = m_bi.getHeight(this); if (w == 0 || h == 0) return NO_SUCH_PAGE; int nCol = Math.max((int)Math.ceil((double)w/wPage), 1); int nRow = Math.max((int)Math.ceil((double)h/hPage), 1); m_maxNumPage = nCol*nRow; int iCol = pageIndex % nCol; int iRow = pageIndex / nCol; int x = iCol*wPage; int y = iRow*hPage; int wImage = Math.min(wPage, w-x); int hImage = Math.min(hPage, h-y); */ int w = m_bi.getWidth(this); int h = m_bi.getHeight(this); // int resizedw = (int)(w*(percentSize/100.0)); // int resizedh = (int)(h*(percentSize/100.0)); java.awt.Graphics2D g2d = (java.awt.Graphics2D) pg; g2d.scale(percentSize / 100.0, percentSize / 100.0); if (w == 0 || h == 0) { return NO_SUCH_PAGE; } int nCol = Math.max((int) Math.ceil((double) w / wPage), 1); int nRow = Math.max((int) Math.ceil((double) h / hPage), 1); m_maxNumPage = nCol * nRow; int iCol = pageIndex % nCol; int iRow = pageIndex / nCol; int x = iCol * wPage; int y = iRow * hPage; int wImage = Math.min(wPage, w - x); int hImage = Math.min(hPage, h - y); g2d.drawImage(m_bi, 0, 0, wImage, hImage, x, y, x + wImage, y + hImage, this); // pg.drawImage(m_bi, 0, 0, 40, 40, x, y, x+wImage, y+hImage, this); System.gc(); return PAGE_EXISTS; }
/** Translation durchfuehren */ public void process() { int i, j, k; int ch, len; float f1; double d1, d2, d3, d4, d5; long progOff, progLen, lo; // io AudioFile reInF = null; AudioFile imInF = null; AudioFile reOutF = null; AudioFile imOutF = null; AudioFileDescr reInStream = null; AudioFileDescr imInStream = null; AudioFileDescr reOutStream = null; AudioFileDescr imOutStream = null; FloatFile reFloatF[] = null; FloatFile imFloatF[] = null; File reTempFile[] = null; File imTempFile[] = null; int outChanNum; float[][] reInBuf; // [ch][i] float[][] imInBuf; // [ch][i] float[][] reOutBuf = null; // [ch][i] float[][] imOutBuf = null; // [ch][i] float[] convBuf1, convBuf2; boolean complex; PathField ggOutput; // Synthesize Param ampRef = new Param(1.0, Param.ABS_AMP); // transform-Referenz float gain; // gain abs amp float dryGain, wetGain; float inGain; float maxAmp = 0.0f; Param peakGain; int inLength, inOff; int pre; int post; int length; int framesRead, framesWritten, outLength; boolean polarIn, polarOut; // phase unwrapping double[] phi; int[] wrap; double[] carry; Param lenRef; topLevel: try { complex = pr.bool[PR_HASIMINPUT] || pr.bool[PR_HASIMOUTPUT]; polarIn = pr.intg[PR_OPERATOR] == OP_POLAR2RECT; polarOut = pr.intg[PR_OPERATOR] == OP_RECT2POLAR; if ((polarIn || polarOut) && !complex) throw new IOException(ERR_NOTCOMPLEX); // ---- open input ---- reInF = AudioFile.openAsRead(new File(pr.text[PR_REINPUTFILE])); reInStream = reInF.getDescr(); inLength = (int) reInStream.length; reInBuf = new float[reInStream.channels][8192]; imInBuf = new float[reInStream.channels][8192]; if (pr.bool[PR_HASIMINPUT]) { imInF = AudioFile.openAsRead(new File(pr.text[PR_IMINPUTFILE])); imInStream = imInF.getDescr(); if (imInStream.channels != reInStream.channels) throw new IOException(ERR_COMPLEX); inLength = (int) Math.min(inLength, imInStream.length); } lenRef = new Param(AudioFileDescr.samplesToMillis(reInStream, inLength), Param.ABS_MS); d1 = AudioFileDescr.millisToSamples( reInStream, (Param.transform(pr.para[PR_OFFSET], Param.ABS_MS, lenRef, null).value)); j = (int) (d1 >= 0.0 ? (d1 + 0.5) : (d1 - 0.5)); // correct rounding for negative values! length = (int) (AudioFileDescr.millisToSamples( reInStream, (Param.transform(pr.para[PR_LENGTH], Param.ABS_MS, lenRef, null)).value) + 0.5); // System.err.println( "offset = "+j ); if (j >= 0) { inOff = Math.min(j, inLength); if (!pr.bool[PR_REVERSE]) { reInF.seekFrame(inOff); if (pr.bool[PR_HASIMINPUT]) { imInF.seekFrame(inOff); } } inLength -= inOff; pre = 0; } else { inOff = 0; pre = Math.min(-j, length); } inLength = Math.min(inLength, length - pre); post = length - pre - inLength; if (pr.bool[PR_REVERSE]) { i = pre; pre = post; post = i; inOff += inLength; } // .... check running .... if (!threadRunning) break topLevel; // for( op = 0; op < 2; op++ ) { // System.out.println( op +": pre "+pre[op]+" / len "+inLength[op]+" / post "+post[op] ); // } // System.out.println( "tot "+length[0]); outLength = length; outChanNum = reInStream.channels; // ---- open output ---- ggOutput = (PathField) gui.getItemObj(GG_REOUTPUTFILE); if (ggOutput == null) throw new IOException(ERR_MISSINGPROP); reOutStream = new AudioFileDescr(reInStream); ggOutput.fillStream(reOutStream); reOutStream.channels = outChanNum; // well, more sophisticated code would // move and truncate the markers... if ((pre == 0) /* && (post == 0) */) { reInF.readMarkers(); reOutStream.setProperty( AudioFileDescr.KEY_MARKERS, reInStream.getProperty(AudioFileDescr.KEY_MARKERS)); } reOutF = AudioFile.openAsWrite(reOutStream); reOutBuf = new float[outChanNum][8192]; imOutBuf = new float[outChanNum][8192]; if (pr.bool[PR_HASIMOUTPUT]) { imOutStream = new AudioFileDescr(reInStream); ggOutput.fillStream(imOutStream); imOutStream.channels = outChanNum; imOutStream.file = new File(pr.text[PR_IMOUTPUTFILE]); imOutF = AudioFile.openAsWrite(imOutStream); } // .... check running .... if (!threadRunning) break topLevel; // ---- Further inits ---- phi = new double[outChanNum]; wrap = new int[outChanNum]; carry = new double[outChanNum]; for (ch = 0; ch < outChanNum; ch++) { phi[ch] = 0.0; wrap[ch] = 0; carry[ch] = Double.NEGATIVE_INFINITY; } progOff = 0; // read, transform, write progLen = (long) outLength * 3; wetGain = (float) (Param.transform(pr.para[PR_WETMIX], Param.ABS_AMP, ampRef, null)).value; dryGain = (float) (Param.transform(pr.para[PR_DRYMIX], Param.ABS_AMP, ampRef, null)).value; if (pr.bool[PR_DRYINVERT]) { dryGain = -dryGain; } inGain = (float) (Param.transform(pr.para[PR_INPUTGAIN], Param.ABS_AMP, ampRef, null)).value; if (pr.bool[PR_INVERT]) { inGain = -inGain; } // normalization requires temp files if (pr.intg[PR_GAINTYPE] == GAIN_UNITY) { reTempFile = new File[outChanNum]; reFloatF = new FloatFile[outChanNum]; for (ch = 0; ch < outChanNum; ch++) { // first zero them because an exception might be thrown reTempFile[ch] = null; reFloatF[ch] = null; } for (ch = 0; ch < outChanNum; ch++) { reTempFile[ch] = IOUtil.createTempFile(); reFloatF[ch] = new FloatFile(reTempFile[ch], GenericFile.MODE_OUTPUT); } if (pr.bool[PR_HASIMOUTPUT]) { imTempFile = new File[outChanNum]; imFloatF = new FloatFile[outChanNum]; for (ch = 0; ch < outChanNum; ch++) { // first zero them because an exception might be thrown imTempFile[ch] = null; imFloatF[ch] = null; } for (ch = 0; ch < outChanNum; ch++) { imTempFile[ch] = IOUtil.createTempFile(); imFloatF[ch] = new FloatFile(imTempFile[ch], GenericFile.MODE_OUTPUT); } } progLen += outLength; } else { gain = (float) (Param.transform(pr.para[PR_GAIN], Param.ABS_AMP, ampRef, null)).value; wetGain *= gain; dryGain *= gain; } // .... check running .... if (!threadRunning) break topLevel; // ----==================== the real stuff ====================---- framesRead = 0; framesWritten = 0; while (threadRunning && (framesWritten < outLength)) { // ---- choose chunk len ---- len = Math.min(8192, outLength - framesWritten); if (pre > 0) { len = Math.min(len, pre); } else if (inLength > 0) { len = Math.min(len, inLength); } else { len = Math.min(len, post); } // ---- read input chunks ---- if (pre > 0) { Util.clear(reInBuf); if (complex) { Util.clear(imInBuf); } pre -= len; } else if (inLength > 0) { if (pr.bool[PR_REVERSE]) { // ---- read reversed ---- reInF.seekFrame(inOff - framesRead - len); reInF.readFrames(reInBuf, 0, len); for (ch = 0; ch < reInStream.channels; ch++) { convBuf1 = reInBuf[ch]; for (i = 0, j = len - 1; i < j; i++, j--) { f1 = convBuf1[j]; convBuf1[j] = convBuf1[i]; convBuf1[i] = f1; } } if (pr.bool[PR_HASIMINPUT]) { imInF.seekFrame(inOff - framesRead - len); imInF.readFrames(imInBuf, 0, len); for (ch = 0; ch < imInStream.channels; ch++) { convBuf1 = imInBuf[ch]; for (i = 0, j = len - 1; i < j; i++, j--) { f1 = convBuf1[j]; convBuf1[j] = convBuf1[i]; convBuf1[i] = f1; } } } else if (complex) { Util.clear(imInBuf); } } else { // ---- read normal ---- reInF.readFrames(reInBuf, 0, len); if (pr.bool[PR_HASIMINPUT]) { imInF.readFrames(imInBuf, 0, len); } else if (complex) { Util.clear(imInBuf); } } inLength -= len; framesRead += len; } else { Util.clear(reInBuf); if (complex) { Util.clear(imInBuf); } post -= len; } progOff += len; // .... progress .... setProgression((float) progOff / (float) progLen); // .... check running .... if (!threadRunning) break topLevel; // ---- save dry signal ---- for (ch = 0; ch < outChanNum; ch++) { convBuf1 = reInBuf[ch]; convBuf2 = reOutBuf[ch]; for (i = 0; i < len; i++) { convBuf2[i] = convBuf1[i] * dryGain; } if (complex) { convBuf1 = imInBuf[ch]; convBuf2 = imOutBuf[ch]; for (i = 0; i < len; i++) { convBuf2[i] = convBuf1[i] * dryGain; } } } // ---- rectify + apply input gain ---- for (ch = 0; ch < reInStream.channels; ch++) { convBuf1 = reInBuf[ch]; convBuf2 = imInBuf[ch]; // ---- rectify ---- if (pr.bool[PR_RECTIFY]) { if (complex) { if (polarIn) { for (i = 0; i < len; i++) { convBuf2[i] = 0.0f; } } else { for (i = 0; i < len; i++) { d1 = convBuf1[i]; d2 = convBuf2[i]; convBuf1[i] = (float) Math.sqrt(d1 * d1 + d2 * d2); convBuf2[i] = 0.0f; } } } else { for (i = 0; i < len; i++) { convBuf1[i] = Math.abs(convBuf1[i]); } } } // ---- apply input gain ---- Util.mult(convBuf1, 0, len, inGain); if (complex & !polarIn) { Util.mult(convBuf2, 0, len, inGain); } } // ---- heart of the dragon ---- for (ch = 0; ch < outChanNum; ch++) { convBuf1 = reInBuf[ch]; convBuf2 = imInBuf[ch]; switch (pr.intg[PR_OPERATOR]) { case OP_NONE: // ================ None ================ for (i = 0; i < len; i++) { reOutBuf[ch][i] += wetGain * convBuf1[i]; } if (complex) { for (i = 0; i < len; i++) { imOutBuf[ch][i] += wetGain * convBuf2[i]; } } break; case OP_SIN: // ================ Cosinus ================ if (complex) { for (i = 0; i < len; i++) { reOutBuf[ch][i] += wetGain * (float) Math.sin(convBuf1[i] * Math.PI); imOutBuf[ch][i] += wetGain * (float) Math.sin(convBuf2[i] * Math.PI); } } else { for (i = 0; i < len; i++) { reOutBuf[ch][i] += wetGain * (float) Math.sin(convBuf1[i] * Math.PI); } } break; case OP_SQR: // ================ Square ================ if (complex) { for (i = 0; i < len; i++) { reOutBuf[ch][i] += wetGain * (convBuf1[i] * convBuf1[i] - convBuf2[i] * convBuf2[i]); imOutBuf[ch][i] -= wetGain * (convBuf1[i] * convBuf2[i] * 2); } } else { for (i = 0; i < len; i++) { reOutBuf[ch][i] += wetGain * (convBuf1[i] * convBuf1[i]); } } break; case OP_SQRT: // ================ Square root ================ if (complex) { d3 = phi[ch]; k = wrap[ch]; d4 = k * Constants.PI2; for (i = 0; i < len; i++) { d1 = wetGain * Math.pow(convBuf1[i] * convBuf1[i] + convBuf2[i] * convBuf2[i], 0.25); d2 = Math.atan2(convBuf2[i], convBuf1[i]); if (d2 - d3 > Math.PI) { k--; d4 = k * Constants.PI2; } else if (d3 - d2 > Math.PI) { k++; d4 = k * Constants.PI2; } d2 += d4; d3 = d2; d2 /= 2; reOutBuf[ch][i] += (float) (d1 * Math.cos(d2)); imOutBuf[ch][i] += (float) (d1 * Math.sin(d2)); } phi[ch] = d3; wrap[ch] = k; } else { for (i = 0; i < len; i++) { f1 = convBuf1[i]; if (f1 > 0) { reOutBuf[ch][i] += wetGain * (float) Math.sqrt(f1); } // else undefiniert } } break; case OP_RECT2POLARW: // ================ Rect->Polar (wrapped) ================ for (i = 0; i < len; i++) { d1 = wetGain * Math.sqrt(convBuf1[i] * convBuf1[i] + convBuf2[i] * convBuf2[i]); d2 = Math.atan2(convBuf2[i], convBuf1[i]); reOutBuf[ch][i] += (float) d1; imOutBuf[ch][i] += (float) d2; } break; case OP_RECT2POLAR: // ================ Rect->Polar ================ d3 = phi[ch]; k = wrap[ch]; d4 = k * Constants.PI2; for (i = 0; i < len; i++) { d1 = wetGain * Math.sqrt(convBuf1[i] * convBuf1[i] + convBuf2[i] * convBuf2[i]); d2 = Math.atan2(convBuf2[i], convBuf1[i]); if (d2 - d3 > Math.PI) { k--; d4 = k * Constants.PI2; } else if (d3 - d2 > Math.PI) { k++; d4 = k * Constants.PI2; } d2 += d4; reOutBuf[ch][i] += (float) d1; imOutBuf[ch][i] += (float) d2; d3 = d2; } phi[ch] = d3; wrap[ch] = k; break; case OP_POLAR2RECT: // ================ Polar->Rect ================ for (i = 0; i < len; i++) { f1 = wetGain * convBuf1[i]; reOutBuf[ch][i] += f1 * (float) Math.cos(convBuf2[i]); imOutBuf[ch][i] += f1 * (float) Math.sin(convBuf2[i]); } break; case OP_LOG: // ================ Log ================ if (complex) { d3 = phi[ch]; k = wrap[ch]; d4 = k * Constants.PI2; d5 = carry[ch]; for (i = 0; i < len; i++) { d1 = Math.sqrt(convBuf1[i] * convBuf1[i] + convBuf2[i] * convBuf2[i]); d2 = Math.atan2(convBuf2[i], convBuf1[i]); if (d2 - d3 > Math.PI) { k--; d4 = k * Constants.PI2; } else if (d3 - d2 > Math.PI) { k++; d4 = k * Constants.PI2; } if (d1 > 0.0) { d5 = Math.log(d1); } d2 += d4; reOutBuf[ch][i] += (float) d5; imOutBuf[ch][i] += (float) d2; d3 = d2; } phi[ch] = d3; wrap[ch] = k; carry[ch] = d5; } else { for (i = 0; i < len; i++) { f1 = convBuf1[i]; if (f1 > 0) { reOutBuf[ch][i] += wetGain * (float) Math.log(f1); } // else undefiniert } } break; case OP_EXP: // ================ Exp ================ if (complex) { for (i = 0; i < len; i++) { d1 = wetGain * Math.exp(convBuf1[i]); reOutBuf[ch][i] += (float) (d1 * Math.cos(convBuf2[i])); imOutBuf[ch][i] += (float) (d1 * Math.sin(convBuf2[i])); } } else { for (i = 0; i < len; i++) { reOutBuf[ch][i] += wetGain * (float) Math.exp(convBuf1[i]); } } break; case OP_NOT: // ================ NOT ================ for (i = 0; i < len; i++) { lo = ~((long) (convBuf1[i] * 2147483647.0)); reOutBuf[ch][i] += wetGain * (float) ((lo & 0xFFFFFFFFL) / 2147483647.0); } if (complex) { for (i = 0; i < len; i++) { lo = ~((long) (convBuf2[i] * 2147483647.0)); imOutBuf[ch][i] += wetGain * (float) ((lo & 0xFFFFFFFFL) / 2147483647.0); } } break; } } // for outChan progOff += len; // .... progress .... setProgression((float) progOff / (float) progLen); // .... check running .... if (!threadRunning) break topLevel; // ---- write output chunk ---- if (reFloatF != null) { for (ch = 0; ch < outChanNum; ch++) { reFloatF[ch].writeFloats(reOutBuf[ch], 0, len); if (pr.bool[PR_HASIMOUTPUT]) { imFloatF[ch].writeFloats(imOutBuf[ch], 0, len); } } } else { reOutF.writeFrames(reOutBuf, 0, len); if (pr.bool[PR_HASIMOUTPUT]) { imOutF.writeFrames(imOutBuf, 0, len); } } // check max amp for (ch = 0; ch < outChanNum; ch++) { convBuf1 = reOutBuf[ch]; for (i = 0; i < len; i++) { f1 = Math.abs(convBuf1[i]); if (f1 > maxAmp) { maxAmp = f1; } } if (pr.bool[PR_HASIMOUTPUT]) { convBuf1 = imOutBuf[ch]; for (i = 0; i < len; i++) { f1 = Math.abs(convBuf1[i]); if (f1 > maxAmp) { maxAmp = f1; } } } } progOff += len; framesWritten += len; // .... progress .... setProgression((float) progOff / (float) progLen); } // while not framesWritten // ----==================== normalize output ====================---- if (pr.intg[PR_GAINTYPE] == GAIN_UNITY) { peakGain = new Param(maxAmp, Param.ABS_AMP); gain = (float) (Param.transform( pr.para[PR_GAIN], Param.ABS_AMP, new Param(1.0 / peakGain.value, peakGain.unit), null)) .value; f1 = pr.bool[PR_HASIMOUTPUT] ? ((1.0f + getProgression()) / 2) : 1.0f; normalizeAudioFile(reFloatF, reOutF, reOutBuf, gain, f1); if (pr.bool[PR_HASIMOUTPUT]) { normalizeAudioFile(imFloatF, imOutF, imOutBuf, gain, 1.0f); } maxAmp *= gain; for (ch = 0; ch < outChanNum; ch++) { reFloatF[ch].cleanUp(); reFloatF[ch] = null; reTempFile[ch].delete(); reTempFile[ch] = null; if (pr.bool[PR_HASIMOUTPUT]) { imFloatF[ch].cleanUp(); imFloatF[ch] = null; imTempFile[ch].delete(); imTempFile[ch] = null; } } } // .... check running .... if (!threadRunning) break topLevel; // ---- Finish ---- reOutF.close(); reOutF = null; reOutStream = null; if (imOutF != null) { imOutF.close(); imOutF = null; imOutStream = null; } reInF.close(); reInF = null; reInStream = null; if (pr.bool[PR_HASIMINPUT]) { imInF.close(); imInF = null; imInStream = null; } reOutBuf = null; imOutBuf = null; reInBuf = null; imInBuf = null; // inform about clipping/ low level handleClipping(maxAmp); } catch (IOException e1) { setError(e1); } catch (OutOfMemoryError e2) { reOutBuf = null; imOutBuf = null; reInBuf = null; imInBuf = null; convBuf1 = null; convBuf2 = null; System.gc(); setError(new Exception(ERR_MEMORY)); } // ---- cleanup (topLevel) ---- convBuf1 = null; convBuf2 = null; if (reInF != null) { reInF.cleanUp(); reInF = null; } if (imInF != null) { imInF.cleanUp(); imInF = null; } if (reOutF != null) { reOutF.cleanUp(); reOutF = null; } if (imOutF != null) { imOutF.cleanUp(); imOutF = null; } if (reFloatF != null) { for (ch = 0; ch < reFloatF.length; ch++) { if (reFloatF[ch] != null) { reFloatF[ch].cleanUp(); reFloatF[ch] = null; } if (reTempFile[ch] != null) { reTempFile[ch].delete(); reTempFile[ch] = null; } } } if (imFloatF != null) { for (ch = 0; ch < imFloatF.length; ch++) { if (imFloatF[ch] != null) { imFloatF[ch].cleanUp(); imFloatF[ch] = null; } if (imTempFile[ch] != null) { imTempFile[ch].delete(); imTempFile[ch] = null; } } } } // process()
// create a new profile: read the script and possibly execute the queries, // save the stats (if 'import' == true, we assume the profile already exists // and don't run the queries) public void createWkld(String name, String scriptFile, boolean runQueries) { System.gc(); Workload wkld = new Workload(name); if (showCmdsItem.getState()) { consoleFrame.echoCmd((!runQueries ? "importprof " : "newwkld ") + name + " " + scriptFile); } // construct the Workload object from the script; // first, check if the file exists try { FileReader reader = new FileReader(scriptFile); reader.close(); } catch (FileNotFoundException e) { System.out.println("couldn't open " + scriptFile); return; } catch (IOException e) { System.out.println("couldn't close " + scriptFile); } // now, check if it contains only queries int scriptId = 0; try { scriptId = Libgist.openScript(scriptFile); } catch (LibgistException e) { System.out.println("couldn't open (C) " + scriptFile); return; } char[] arg1 = new char[64 * 1024]; StringBuffer arg1Buf = new StringBuffer(); char[] arg2 = new char[64 * 1024]; StringBuffer arg2Buf = new StringBuffer(); // for (;;) { // int cmd = Libgist.getCommand(scriptId, arg1, arg2); // if (cmd == Libgist.EOF) break; // if (cmd != Libgist.FETCH) { // there should only be queries // System.out.println("Script file contains non-SELECT command"); // return; // } // } if (runQueries) { // turn profiling on and execute queries // Libgist.setProfilingEnabled(true); Libgist.disableBps(true); // we don't want to stop at breakpoints // rescan queries try { scriptId = Libgist.openScript(scriptFile); } catch (LibgistException e) { System.out.println("couldn't open (C) " + scriptFile); return; } int cnt = 1; // for (;;) { // int cmd = Libgist.getCommand(scriptId, arg1, arg2); // if (cmd == Libgist.EOF) break; // arg1Buf.setLength(0); // arg1Buf.append(arg1, 0, strlen(arg1)); // arg2Buf.setLength(0); // arg2Buf.append(arg2, 0, strlen(arg2)); // OpThread.execCmd(LibgistCommand.FETCH, arg1Buf.toString(), // arg2Buf.toString(), false); // System.out.print(cnt + " "); // System.out.println(cnt + ": execute " + arg2Buf.toString() + " " // + arg1Buf.toString()); // cnt++; // } System.out.println(); Libgist.disableBps(false); // compute optimal clustering and some more statistics // Libgist.computeMetrics(wkld.filename); } // save profile try { // we're saving Java and C++ data in separate files (filename and filename.prof) // the profile object only contains the filename, the queries will be // read in from the file when the profile is opened (faster that way) ObjectOutputStream out = new ObjectOutputStream(new FileOutputStream(wkld.filename)); out.writeObject(wkld); out.close(); System.out.println("copy query file"); Runtime.getRuntime().exec("cp " + scriptFile + " " + wkld.filename + ".queries"); System.out.println("saving tree and profile"); Libgist.saveToFile(wkld.filename + ".idx"); if (runQueries) { // Libgist.saveProfile(wkld.filename + ".prof"); } } catch (Exception e) { System.out.println("Error saving profile: " + e); return; } if (runQueries) { // turn profiling off (after the metrics were computed and // the profile saved) // Libgist.setProfilingEnabled(false); } }
@Override public void run() { this.cardIndex = 0; File base = new File(Constants.IO.imageBaseDir); if (!base.exists()) { base.mkdir(); } Connection.ProxyType configProxyType = Connection.ProxyType.valueByText( PreferencesDialog.getCachedValue(PreferencesDialog.KEY_PROXY_TYPE, "None")); Proxy.Type type = Proxy.Type.DIRECT; switch (configProxyType) { case HTTP: type = Proxy.Type.HTTP; break; case SOCKS: type = Proxy.Type.SOCKS; break; case NONE: default: p = Proxy.NO_PROXY; break; } if (type != Proxy.Type.DIRECT) { try { String address = PreferencesDialog.getCachedValue(PreferencesDialog.KEY_PROXY_ADDRESS, ""); Integer port = Integer.parseInt( PreferencesDialog.getCachedValue(PreferencesDialog.KEY_PROXY_PORT, "80")); p = new Proxy(type, new InetSocketAddress(address, port)); } catch (Exception ex) { throw new RuntimeException("Gui_DownloadPictures : error 1 - " + ex); } } if (p != null) { HashSet<String> ignoreUrls = SettingsManager.getIntance().getIgnoreUrls(); ArrayList<CardDownloadData> cardsToDownload = this.checkBox.isSelected() ? type2cards : cards; update(0, cardsToDownload.size()); for (int i = 0; i < cardsToDownload.size() && !cancel; i++) { try { CardDownloadData card = cardsToDownload.get(i); log.info("Downloading card: " + card.getName() + " (" + card.getSet() + ")"); String url; if (ignoreUrls.contains(card.getSet()) || card.isToken()) { if (card.getCollectorId() != 0) { continue; } url = cardImageSource.generateTokenUrl(card); } else { url = cardImageSource.generateURL(card); } if (url != null) { Logger.getLogger(this.getClass()).info(url); Runnable task = new DownloadTask(card, new URL(url), cardsToDownload.size()); executor.execute(task); } else { synchronized (sync) { update(cardIndex + 1, cardsToDownload.size()); } } } catch (Exception ex) { log.error(ex, ex); } } executor.shutdown(); while (!executor.isTerminated()) { try { Thread.sleep(1000); } catch (InterruptedException ie) { } } } try { TVFS.umount(); } catch (FsSyncException e) { e.printStackTrace(); JOptionPane.showMessageDialog( null, "Couldn't unmount zip files", "Error", JOptionPane.ERROR_MESSAGE); } finally { System.gc(); } closeButton.setText("Close"); }
private void closeFile() { upperTabbedPane.remove(upperTabbedPane.getSelectedComponent()); menuBar.setFileOpen(upperTabbedPane.getComponentCount() > 0); System.gc(); }
private void refreshTableWithData(ArrayList<PasswordModel> models) { currentTableSelect = 0; // 重新默认选择第0行 currentListContent = models; // 设置最新的数据 listTable.setModel(new MainTableDataModel(models)); // 模型转换 System.gc(); }