// type 'java Parallel' to run this application public static void main(String args[]) throws VisADException, RemoteException, IOException { RealType index = RealType.getRealType("index"); RealType[] coords = new RealType[NCOORDS]; for (int i = 0; i < NCOORDS; i++) { coords[i] = RealType.getRealType("coord" + i); } RealTupleType range = new RealTupleType(coords); FunctionType ftype = new FunctionType(index, range); Integer1DSet index_set = new Integer1DSet(NROWS); float[][] samples = new float[NCOORDS][NROWS]; for (int i = 0; i < NCOORDS; i++) { for (int j = 0; j < NROWS; j++) { samples[i][j] = (float) Math.random(); } } FlatField data = new FlatField(ftype, index_set); data.setSamples(samples, false); // create a 2-D Display using Java3D DisplayImpl display = new DisplayImplJ3D("display", new TwoDDisplayRendererJ3D()); parallel(display, data); // create JFrame (i.e., a window) for display and slider JFrame frame = new JFrame("Parallel Coordinates VisAD Application"); frame.addWindowListener( new WindowAdapter() { public void windowClosing(WindowEvent e) { System.exit(0); } }); // create JPanel in JFrame JPanel panel = new JPanel(); panel.setLayout(new BoxLayout(panel, BoxLayout.Y_AXIS)); panel.setAlignmentY(JPanel.TOP_ALIGNMENT); panel.setAlignmentX(JPanel.LEFT_ALIGNMENT); frame.getContentPane().add(panel); // add display to JPanel panel.add(display.getComponent()); // set size of JFrame and make it visible frame.setSize(500, 500); frame.setVisible(true); }
public static void main(String[] args) throws Exception { DisplayImpl display = new DisplayImplJ2D("display"); display.getDisplayRenderer().setBoxOn(false); double[] matrix = display.getProjectionControl().getMatrix(); matrix[0] = 1.25; matrix[3] = -1.25; display.getProjectionControl().setMatrix(matrix); display.addMap(new ScalarMap(RealType.YAxis, Display.YAxis)); display.addMap(new ScalarMap(RealType.XAxis, Display.XAxis)); float[][] values = new float[3][220]; int l = 0; for (int x = 0; x < 11; x++) { for (int y = 0; y < 20; y++) { values[0][l] = -1.f + y / 10.f; values[1][l] = 1.f - x / 4.f; values[2][l] = l++; } } Gridded3DSet set = new Gridded3DSet(RealTupleType.SpatialCartesian3DTuple, values, l); ScalarMap shapeMap = new ScalarMap(RealType.ZAxis, Display.Shape); display.addMap(shapeMap); ShapeControl sc = (ShapeControl) shapeMap.getControl(); sc.setShapeSet(new Integer1DSet(l)); sc.setShapes(WeatherSymbols.getAllMetSymbols()); sc.setScale(0.1f); DataReference ref = new DataReferenceImpl("ref"); ref.setData(set); display.addReference(ref); JFrame frame = new JFrame("Weather Symbol Plot Test"); frame.addWindowListener( new WindowAdapter() { public void windowClosing(WindowEvent e) { System.exit(0); } }); frame.getContentPane().add(display.getComponent()); frame.pack(); frame.setSize(500, 500); frame.setVisible(true); }
/** test BarbManipulationRendererJ3D */ public static void main(String args[]) throws VisADException, RemoteException { System.out.println("BMR.main()"); // construct RealTypes for wind record components RealType lat = RealType.Latitude; RealType lon = RealType.Longitude; RealType windx = RealType.getRealType("windx", CommonUnit.meterPerSecond); RealType windy = RealType.getRealType("windy", CommonUnit.meterPerSecond); RealType red = RealType.getRealType("red"); RealType green = RealType.getRealType("green"); // EarthVectorType extends RealTupleType and says that its // components are vectors in m/s with components parallel // to Longitude (positive east) and Latitude (positive north) EarthVectorType windxy = new EarthVectorType(windx, windy); RealType wind_dir = RealType.getRealType("wind_dir", CommonUnit.degree); RealType wind_speed = RealType.getRealType("wind_speed", CommonUnit.meterPerSecond); RealTupleType windds = null; if (args.length > 0) { System.out.println("polar winds"); windds = new RealTupleType( new RealType[] {wind_dir, wind_speed}, new WindPolarCoordinateSystem(windxy), null); } // construct Java3D display and mappings that govern // how wind records are displayed DisplayImpl display = new DisplayImplJ3D("display1", new TwoDDisplayRendererJ3D()); ScalarMap lonmap = new ScalarMap(lon, Display.XAxis); display.addMap(lonmap); ScalarMap latmap = new ScalarMap(lat, Display.YAxis); display.addMap(latmap); FlowControl flow_control; if (args.length > 0) { ScalarMap winds_map = new ScalarMap(wind_speed, Display.Flow1Radial); display.addMap(winds_map); winds_map.setRange(0.0, 1.0); // do this for barb rendering ScalarMap windd_map = new ScalarMap(wind_dir, Display.Flow1Azimuth); display.addMap(windd_map); windd_map.setRange(0.0, 360.0); // do this for barb rendering flow_control = (FlowControl) windd_map.getControl(); flow_control.setFlowScale(0.15f); // this controls size of barbs } else { ScalarMap windx_map = new ScalarMap(windx, Display.Flow1X); display.addMap(windx_map); windx_map.setRange(-1.0, 1.0); // do this for barb rendering ScalarMap windy_map = new ScalarMap(windy, Display.Flow1Y); display.addMap(windy_map); windy_map.setRange(-1.0, 1.0); // do this for barb rendering flow_control = (FlowControl) windy_map.getControl(); flow_control.setFlowScale(0.15f); // this controls size of barbs } display.addMap(new ScalarMap(red, Display.Red)); display.addMap(new ScalarMap(green, Display.Green)); display.addMap(new ConstantMap(1.0, Display.Blue)); DataReferenceImpl[] refs = new DataReferenceImpl[N * N]; int k = 0; // create an array of N by N winds for (int i = 0; i < N; i++) { for (int j = 0; j < N; j++) { double u = 2.0 * i / (N - 1.0) - 1.0; double v = 2.0 * j / (N - 1.0) - 1.0; // each wind record is a Tuple (lon, lat, (windx, windy), red, green) // set colors by wind components, just for grins Tuple tuple; double fx = 30.0 * u; double fy = 30.0 * v; if (args.length > 0) { double fd = Data.RADIANS_TO_DEGREES * Math.atan2(-fx, -fy); double fs = Math.sqrt(fx * fx + fy * fy); tuple = new Tuple( new Data[] { new Real(lon, 10.0 * u), new Real(lat, 10.0 * v - 40.0), new RealTuple(windds, new double[] {fd, fs}), new Real(red, u), new Real(green, v) }); } else { tuple = new Tuple( new Data[] { new Real(lon, 10.0 * u), new Real(lat, 10.0 * v - 40.0), new RealTuple(windxy, new double[] {fx, fy}), new Real(red, u), new Real(green, v) }); } // construct reference for wind record refs[k] = new DataReferenceImpl("ref_" + k); refs[k].setData(tuple); // link wind record to display via BarbManipulationRendererJ3D // so user can change barb by dragging it // drag with right mouse button and shift to change direction // drag with right mouse button and no shift to change speed BarbManipulationRendererJ3D renderer = new BarbManipulationRendererJ3D(); renderer.setKnotsConvert(true); display.addReferences(renderer, refs[k]); // link wind record to a CellImpl that will listen for changes // and print them WindGetterJ3D cell = new WindGetterJ3D(flow_control, refs[k]); cell.addReference(refs[k]); k++; } } // instead of linking the wind record "DataReferenceImpl refs" to // the WindGetterJ3Ds, you can have some user interface event (e.g., // the user clicks on "DONE") trigger code that does a getData() on // all the refs and stores the records in a file. // create JFrame (i.e., a window) for display and slider JFrame frame = new JFrame("test BarbManipulationRendererJ3D"); frame.addWindowListener( new WindowAdapter() { public void windowClosing(WindowEvent e) { System.exit(0); } }); // create JPanel in JFrame JPanel panel = new JPanel(); panel.setLayout(new BoxLayout(panel, BoxLayout.Y_AXIS)); panel.setAlignmentY(JPanel.TOP_ALIGNMENT); panel.setAlignmentX(JPanel.LEFT_ALIGNMENT); frame.getContentPane().add(panel); // add display to JPanel panel.add(display.getComponent()); // set size of JFrame and make it visible frame.setSize(500, 500); frame.setVisible(true); }
/** * run 'java FlowTest middle_latitude' to test with (lat, lon) run 'java FlowTest middle_latitude * x' to test with (lon, lat) adjust middle_latitude for south or north */ public static void main(String args[]) throws VisADException, RemoteException { double mid_lat = -10.0; if (args.length > 0) { try { mid_lat = Double.valueOf(args[0]).doubleValue(); } catch (NumberFormatException e) { } } boolean swap = (args.length > 1); RealType lat = RealType.Latitude; RealType lon = RealType.Longitude; RealType[] types; if (swap) { types = new RealType[] {lon, lat}; } else { types = new RealType[] {lat, lon}; } RealTupleType earth_location = new RealTupleType(types); System.out.println("earth_location = " + earth_location + " mid_lat = " + mid_lat); RealType flowx = RealType.getRealType("flowx", CommonUnit.meterPerSecond); RealType flowy = RealType.getRealType("flowy", CommonUnit.meterPerSecond); RealType red = RealType.getRealType("red"); RealType green = RealType.getRealType("green"); EarthVectorType flowxy = new EarthVectorType(flowx, flowy); TupleType range = null; range = new TupleType(new MathType[] {flowxy, red, green}); FunctionType flow_field = new FunctionType(earth_location, range); DisplayImpl display = new DisplayImplJ3D("display1", new TwoDDisplayRendererJ3D()); ScalarMap xmap = new ScalarMap(lon, Display.XAxis); display.addMap(xmap); ScalarMap ymap = new ScalarMap(lat, Display.YAxis); display.addMap(ymap); ScalarMap flowx_map = new ScalarMap(flowx, Display.Flow1X); display.addMap(flowx_map); flowx_map.setRange(-10.0, 10.0); ScalarMap flowy_map = new ScalarMap(flowy, Display.Flow1Y); display.addMap(flowy_map); flowy_map.setRange(-10.0, 10.0); FlowControl flow_control = (FlowControl) flowy_map.getControl(); flow_control.setFlowScale(0.05f); display.addMap(new ScalarMap(red, Display.Red)); display.addMap(new ScalarMap(green, Display.Green)); display.addMap(new ConstantMap(1.0, Display.Blue)); double lonlow = -10.0; double lonhi = 10.0; double latlow = mid_lat - 10.0; double lathi = mid_lat + 10.0; Linear2DSet set; if (swap) { set = new Linear2DSet(earth_location, lonlow, lonhi, N, latlow, lathi, N); } else { set = new Linear2DSet(earth_location, latlow, lathi, N, lonlow, lonhi, N); } double[][] values = new double[4][N * N]; int m = 0; for (int i = 0; i < N; i++) { for (int j = 0; j < N; j++) { int k = i; int l = j; if (swap) { k = j; l = i; } double u = (N - 1.0) / 2.0 - l; double v = k - (N - 1.0) / 2.0; // double u = 2.0 * k / (N - 1.0) - 1.0; // double v = 2.0 * l / (N - 1.0); double fx = 6.0 * u; double fy = 6.0 * v; values[0][m] = fx; values[1][m] = fy; values[2][m] = u; values[3][m] = v; m++; } } FlatField field = new FlatField(flow_field, set); field.setSamples(values); DataReferenceImpl ref = new DataReferenceImpl("ref"); ref.setData(field); display.addReference(ref); // create JFrame (i.e., a window) for display and slider JFrame frame = new JFrame("test FlowTest"); frame.addWindowListener( new WindowAdapter() { public void windowClosing(WindowEvent e) { System.exit(0); } }); // create JPanel in JFrame JPanel panel = new JPanel(); panel.setLayout(new BoxLayout(panel, BoxLayout.Y_AXIS)); panel.setAlignmentY(JPanel.TOP_ALIGNMENT); panel.setAlignmentX(JPanel.LEFT_ALIGNMENT); frame.getContentPane().add(panel); // add display to JPanel panel.add(display.getComponent()); // set size of JFrame and make it visible frame.setSize(500, 500); frame.setVisible(true); }
/** * Returns the AWT component. * * @return The AWT component. */ public Component getComponent() { return display.getComponent(); }
/** * run 'java visad.bom.ImageRendererJ3D len step' to test animation behavior of ImageRendererJ3D * renders a loop of len at step ms per frame then updates loop by deleting first time and adding * a new last time */ public static void main(String args[]) throws VisADException, RemoteException, IOException { int step = 1000; int len = 3; if (args.length > 0) { try { len = Integer.parseInt(args[0]); } catch (NumberFormatException e) { len = 3; } } if (len < 1) len = 1; if (args.length > 1) { try { step = Integer.parseInt(args[1]); } catch (NumberFormatException e) { step = 1000; } } if (step < 1) step = 1; // create a netCDF reader Plain plain = new Plain(); // open a netCDF file containing an image sequence and adapt // it to a Field Data object Field raw_image_sequence = null; try { // raw_image_sequence = (Field) plain.open("images256x256.nc"); raw_image_sequence = (Field) plain.open("images.nc"); } catch (IOException exc) { String s = "To run this example, the images.nc file must be " + "present in\nthe current directory." + "You can obtain this file from:\n" + " ftp://www.ssec.wisc.edu/pub/visad-2.0/images.nc.Z"; System.out.println(s); System.exit(0); } // just take first half of raw_image_sequence FunctionType image_sequence_type = (FunctionType) raw_image_sequence.getType(); Set raw_set = raw_image_sequence.getDomainSet(); float[][] raw_times = raw_set.getSamples(); int raw_len = raw_times[0].length; if (raw_len != 4) { throw new VisADException("wrong number of images in sequence"); } float raw_span = (4.0f / 3.0f) * (raw_times[0][3] - raw_times[0][0]); double[][] times = new double[1][len]; for (int i = 0; i < len; i++) { times[0][i] = raw_times[0][i % raw_len] + raw_span * (i / raw_len); } Gridded1DDoubleSet set = new Gridded1DDoubleSet(raw_set.getType(), times, len); Field image_sequence = new FieldImpl(image_sequence_type, set); for (int i = 0; i < len; i++) { image_sequence.setSample(i, raw_image_sequence.getSample(i % raw_len)); } // create a DataReference for image sequence final DataReference image_ref = new DataReferenceImpl("image"); image_ref.setData(image_sequence); // create a Display using Java3D DisplayImpl display = new DisplayImplJ3D("image display"); // extract the type of image and use // it to determine how images are displayed FunctionType image_type = (FunctionType) image_sequence_type.getRange(); RealTupleType domain_type = image_type.getDomain(); // map image coordinates to display coordinates display.addMap(new ScalarMap((RealType) domain_type.getComponent(0), Display.XAxis)); display.addMap(new ScalarMap((RealType) domain_type.getComponent(1), Display.YAxis)); // map image brightness values to RGB (default is grey scale) display.addMap(new ScalarMap((RealType) image_type.getRange(), Display.RGB)); RealType hour_type = (RealType) image_sequence_type.getDomain().getComponent(0); ScalarMap animation_map = new ScalarMap(hour_type, Display.Animation); display.addMap(animation_map); AnimationControl animation_control = (AnimationControl) animation_map.getControl(); animation_control.setStep(step); animation_control.setOn(true); /* // link the Display to image_ref ImageRendererJ3D renderer = new ImageRendererJ3D(); display.addReferences(renderer, image_ref); // display.addReference(image_ref); */ // create JFrame (i.e., a window) for display and slider JFrame frame = new JFrame("ImageRendererJ3D test"); frame.addWindowListener( new WindowAdapter() { public void windowClosing(WindowEvent e) { System.exit(0); } }); // create JPanel in JFrame JPanel panel = new JPanel(); panel.setLayout(new BoxLayout(panel, BoxLayout.Y_AXIS)); panel.setAlignmentY(JPanel.TOP_ALIGNMENT); panel.setAlignmentX(JPanel.LEFT_ALIGNMENT); frame.getContentPane().add(panel); // add display to JPanel panel.add(display.getComponent()); // set size of JFrame and make it visible frame.setSize(500, 500); frame.setVisible(true); System.out.println("first animation sequence"); // link the Display to image_ref ImageRendererJ3D renderer = new ImageRendererJ3D(); display.addReferences(renderer, image_ref); // display.addReference(image_ref); // wait 4 * len seconds new Delay(len * 4000); // substitute a new image sequence for the old one for (int i = 0; i < len; i++) { times[0][i] = raw_times[0][(i + 1) % raw_len] + raw_span * ((i + 1) / raw_len); } set = new Gridded1DDoubleSet(raw_set.getType(), times, len); FieldImpl new_image_sequence = new FieldImpl(image_sequence_type, set); for (int i = 0; i < len; i++) { new_image_sequence.setSample(i, raw_image_sequence.getSample((i + 1) % raw_len)); } System.out.println("second animation sequence"); // tell renderer to resue frames in its scene graph renderer.setReUseFrames(true); image_ref.setData(new_image_sequence); }