public void doAction() throws VisADException, RemoteException {
      if (!init) {
        init = true;
        return;
      }

      Gridded2DSet set = (Gridded2DSet) rubberBand.getData();

      float[] low = set.getLow();
      float[] high = set.getHi();

      xmap.setRange(low[0], high[0]);
      ymap.setRange(low[1], high[1]);
    }
Exemple #2
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  /** ensure that non-Manual components of flow_tuple have equal dataRanges symmetric about 0.0 */
  public static void equalizeFlow(Vector mapVector, DisplayTupleType flow_tuple)
      throws VisADException, RemoteException {
    double[] range = new double[2];
    double low = Double.MAX_VALUE;
    double hi = -Double.MAX_VALUE;
    boolean anyAuto = false;

    Enumeration maps = mapVector.elements();
    while (maps.hasMoreElements()) {
      ScalarMap map = ((ScalarMap) maps.nextElement());
      DisplayRealType dtype = map.getDisplayScalar();
      DisplayTupleType tuple = dtype.getTuple();
      if (flow_tuple.equals(tuple) && !map.isManual && !map.badRange()) {
        anyAuto = true;
        low = Math.min(low, map.dataRange[0]);
        hi = Math.max(hi, map.dataRange[1]);
      }
    }
    if (!anyAuto) return;
    hi = Math.max(hi, -low);
    low = -hi;
    maps = mapVector.elements();
    while (maps.hasMoreElements()) {
      ScalarMap map = ((ScalarMap) maps.nextElement());
      DisplayRealType dtype = map.getDisplayScalar();
      DisplayTupleType tuple = dtype.getTuple();
      if (flow_tuple.equals(tuple) && !map.isManual && !map.badRange()) {
        map.setRange(null, low, hi, false);
      }
    }
  }
Exemple #3
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  /**
   * Initialize the color maps
   *
   * @throws RemoteException On badness
   * @throws VisADException On badness
   */
  private void initColorMaps() throws VisADException, RemoteException {
    setupTypes();
    if (doColors) {
      ScalarMap rmap = new ScalarMap(front_red, Display.Red);
      rmap.setRange(0.0, 1.0);
      ScalarMap gmap = new ScalarMap(front_green, Display.Green);
      gmap.setRange(0.0, 1.0);
      ScalarMap bmap = new ScalarMap(front_blue, Display.Blue);
      bmap.setRange(0.0, 1.0);

      ScalarMapSet maps = getScalarMapSet(); // new ScalarMapSet();
      maps.add(rmap);
      maps.add(bmap);
      maps.add(gmap);
      setScalarMapSet(maps);
    }
  }
Exemple #4
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 /**
  * explicitly set the range of data (RealType) values according to Unit conversion between this
  * ScalarMap's RealType and DisplayRealType (both must have Units and they must be convertable; if
  * neither this nor setRange is invoked, then the range will be computed from the initial values
  * of Data objects linked to the Display by autoscaling logic.
  *
  * @throws VisADException VisAD error
  * @throws RemoteException Java RMI error
  */
 public void setRangeByUnits() throws VisADException, RemoteException {
   isManual = true;
   setRange(null, 0.0, 0.0, true);
   if (scale == scale && offset == offset) {
     incTick(); // did work, so wake up Display
   } else {
     isManual = false; // didn't work, so don't lock out auto-scaling
   }
 }
Exemple #5
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 /**
  * explicitly set the range of data (RealType) values; used for linear map from Scalar to
  * DisplayScalar values; if neither this nor setRangeByUnits is invoked, then the range will be
  * computed from the initial values of Data objects linked to the Display by autoscaling logic; if
  * the range of data values is (0.0, 1.0), for example, this method may be invoked with low = 1.0
  * and hi = 0.0 to invert the display scale .
  *
  * @param low lower range value (see notes above)
  * @param hi upper range value (see notes above)
  * @param remoteId id of remote scale
  * @throws VisADException VisAD error
  * @throws RemoteException Java RMI error
  */
 public void setRange(double low, double hi, int remoteId) throws VisADException, RemoteException {
   if (DisplayScalar.equals(Display.Animation)) {
     System.err.println("Warning: setRange on " + "ScalarMap to Display.Animation has no effect.");
     return;
   }
   isManual = true;
   setRange(null, low, hi, false, remoteId);
   if (scale == scale && offset == offset) {
     incTick(); // did work, so wake up Display
   } else {
     isManual = false; // didn't work, so don't lock out auto-scaling
   }
 }
 public void displayChanged(final DisplayEvent e) throws VisADException, RemoteException {
   // TODO: write a method like isChannelUpdate(EVENT_ID)? or maybe just
   // deal with a super long if-statement and put an "OR MOUSE_RELEASED"
   // up here?
   if (e.getId() == DisplayEvent.MOUSE_RELEASED_CENTER) {
     float val = (float) display.getDisplayRenderer().getDirectAxisValue(domainType);
     setWaveNumber(val);
     if (displayControl != null) displayControl.handleChannelChange(val);
   } else if (e.getId() == DisplayEvent.MOUSE_PRESSED_LEFT) {
     if (e.getInputEvent().isControlDown()) {
       xmap.setRange(initialRangeX[0], initialRangeX[1]);
       ymap.setRange(initialRangeY[0], initialRangeY[1]);
     }
   } else if (e.getId() == DisplayEvent.MOUSE_RELEASED) {
     float val = getSelectorValue(channelSelector);
     if (val != waveNumber) {
       // TODO: setWaveNumber needs to be rethought, as it calls
       // setSelectorValue which is redundant in the cases of dragging
       // or clicking
       setWaveNumber(val);
       if (displayControl != null) displayControl.handleChannelChange(val);
     }
   }
 }
  /**
   * prepare for transforming Data into scene graph depictions, including possible auto-scaling of
   * ScalarMaps
   *
   * @param temp Vector of DataRenderers
   * @param tmap Vector of ScalarMaps
   * @param go flag indicating whether Data transforms are requested
   * @param initialize flag indicating whether auto-scaling is requested
   * @throws VisADException a VisAD error occurred
   * @throws RemoteException an RMI error occurred
   */
  public void prepareAction(Vector temp, Vector tmap, boolean go, boolean initialize)
      throws VisADException, RemoteException {
    DataShadow shadow = null;
    Enumeration renderers = temp.elements();
    while (renderers.hasMoreElements()) {
      DataRenderer renderer = (DataRenderer) renderers.nextElement();
      shadow = renderer.prepareAction(go, initialize, shadow);
    }

    if (shadow != null) {
      // apply RealType ranges and animationSampling
      Enumeration maps = tmap.elements();
      while (maps.hasMoreElements()) {
        ScalarMap map = ((ScalarMap) maps.nextElement());
        map.setRange(shadow);
      }
    }

    ScalarMap.equalizeFlow(tmap, Display.DisplayFlow1Tuple);
    ScalarMap.equalizeFlow(tmap, Display.DisplayFlow2Tuple);
  }
  /**
   * Construct a satellite display using the specified McIDAS map file, image source. The image can
   * be displayed on a 3D globe or on a flat rectillinear projection.
   *
   * @param mapFile location of the McIDAS map file (path or URL)
   * @param imageSource location of the image source (path or URL)
   * @param display3D if true, use 3D display, otherwise flat rectillinear
   * @param remap remap the image into a domain over North America
   */
  public SatDisplay(String mapFile, String imageSource, boolean display3D, boolean remap) {
    try {
      //  Read in the map file
      BaseMapAdapter baseMapAdapter;
      if (mapFile.indexOf("://") > 0) // URL specified
      {
        baseMapAdapter = new BaseMapAdapter(new URL(mapFile));
      } else // local disk file
      {
        baseMapAdapter = new BaseMapAdapter(mapFile);
      }

      // Create the display and set up the scalar maps to map
      // data to the display
      ScalarMap latMap; // latitude  -> YAxis
      ScalarMap lonMap; // longitude -> XAxis
      if (display3D) {
        display = new DisplayImplJ3D("display");
        latMap = new ScalarMap(RealType.Latitude, Display.Latitude);
        lonMap = new ScalarMap(RealType.Longitude, Display.Longitude);
      } else {
        display = new DisplayImplJ3D("display", new TwoDDisplayRendererJ3D());
        latMap = new ScalarMap(RealType.Latitude, Display.YAxis);
        lonMap = new ScalarMap(RealType.Longitude, Display.XAxis);
      }
      display.addMap(latMap);
      display.addMap(lonMap);

      // set the display to a global scale
      latMap.setRange(-90.0, 90.0);
      lonMap.setRange(-180.0, 180.0);

      // create a reference for the map line
      DataReference maplinesRef = new DataReferenceImpl("MapLines");
      maplinesRef.setData(baseMapAdapter.getData());

      // set the attributes of the map lines (color, location)
      ConstantMap[] maplinesConstantMap = new ConstantMap[4];
      maplinesConstantMap[0] = new ConstantMap(0., Display.Blue);
      maplinesConstantMap[1] = new ConstantMap(1., Display.Red);
      maplinesConstantMap[2] = new ConstantMap(0., Display.Green);
      maplinesConstantMap[3] = new ConstantMap(1.001, Display.Radius); // just above the image

      // read in the image
      AreaAdapter areaAdapter = new AreaAdapter(imageSource);
      FlatField image = areaAdapter.getData();

      // Extract the metadata from the image
      FunctionType imageFunctionType = (FunctionType) image.getType();
      RealTupleType imageDomainType = imageFunctionType.getDomain();
      RealTupleType imageRangeType = (RealTupleType) imageFunctionType.getRange();

      // remap and resample the image
      if (remap) {
        int SIZE = 256;
        RealTupleType latlonType =
            ((CoordinateSystem) imageDomainType.getCoordinateSystem()).getReference();
        Linear2DSet remapDomainSet =
            new Linear2DSet(latlonType, -4.0, 70.0, SIZE, -150.0, 5.0, SIZE);
        image = (FlatField) image.resample(remapDomainSet, Data.NEAREST_NEIGHBOR, Data.NO_ERRORS);
      }

      // select which band to show...
      ScalarMap rgbMap = new ScalarMap((RealType) imageRangeType.getComponent(0), Display.RGB);
      display.addMap(rgbMap);

      // set the enhancement to a grey scale
      ColorControl colorControl = (ColorControl) rgbMap.getControl();
      colorControl.initGreyWedge();

      // create a data reference for the image
      DataReferenceImpl imageRef = new DataReferenceImpl("ImageRef");
      imageRef.setData(image);

      // add the data references to the display
      display.disableAction();
      drmap = new DefaultRendererJ3D();
      drimage = new DefaultRendererJ3D();
      drmap.toggle(false);
      drimage.toggle(false);
      display.addDisplayListener(this);

      display.addReferences(drmap, maplinesRef, maplinesConstantMap);
      display.addReferences(drimage, imageRef, null);
      display.enableAction();
    } catch (Exception ne) {
      ne.printStackTrace();
      System.exit(1);
    }
  }
Exemple #9
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 /** set range used for linear map from Scalar to DisplayScalar values */
 private synchronized void setRange(DataShadow shadow, double low, double hi, boolean unit_flag)
     throws VisADException, RemoteException {
   setRange(shadow, low, hi, unit_flag, VisADEvent.LOCAL_SOURCE);
 }
Exemple #10
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 /**
  * set range used for linear map from Scalar to DisplayScalar values; this is the call for
  * automatic scaling
  */
 public void setRange(DataShadow shadow) throws VisADException, RemoteException {
   if (!isManual) setRange(shadow, 0.0, 0.0, false, VisADEvent.LOCAL_SOURCE);
 }
Exemple #11
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 /**
  * Explicitly sets the range of {@link RealType} data values that is mapped to the natural range
  * of {@link DisplayRealType} display values. This method is used to define a linear map from
  * Scalar to DisplayScalar values. If neither this nor {@link #setRangeByUnits()} is invoked, then
  * the range will be computed by autoscaling logic from the initial values of Data objects linked
  * to the Display. If the range of data values is (0.0, 1.0), for example, this method may be
  * invoked with low = 1.0 and hi = 0.0 to invert the display scale.
  *
  * @param low One end of the range of applicable data.
  * @param hi The other end of the range of applicable data.
  * @throws VisADException VisAD failure.
  * @throws RemoteException Java RMI failure.
  */
 public void setRange(double low, double hi) throws VisADException, RemoteException {
   setRange(low, hi, VisADEvent.LOCAL_SOURCE);
 }
  private void init() throws VisADException, RemoteException {

    HydraDataSource source = (HydraDataSource) dataChoice.getDataSource();

    // TODO revisit this, may want to move method up to base class HydraDataSource
    if (source instanceof SuomiNPPDataSource) {
      data = ((SuomiNPPDataSource) source).getMultiSpectralData(dataChoice);
    }

    if (source instanceof MultiSpectralDataSource) {
      data = ((MultiSpectralDataSource) source).getMultiSpectralData(dataChoice);
    }

    waveNumber = data.init_wavenumber;

    try {
      spectrum = data.getSpectrum(new int[] {1, 1});
    } catch (Exception e) {
      LogUtil.logException("MultiSpectralDisplay.init", e);
    }

    domainSet = (Gridded1DSet) spectrum.getDomainSet();
    initialRangeX = getXRange(domainSet);
    initialRangeY = data.getDataRange();

    domainType = getDomainType(spectrum);
    rangeType = getRangeType(spectrum);

    master = new XYDisplay(DISP_NAME, domainType, rangeType);

    setDisplayMasterAttributes(master);

    // set up the x- and y-axis
    xmap = new ScalarMap(domainType, Display.XAxis);
    ymap = new ScalarMap(rangeType, Display.YAxis);

    xmap.setRange(initialRangeX[0], initialRangeX[1]);
    ymap.setRange(initialRangeY[0], initialRangeY[1]);

    display = master.getDisplay();
    display.addMap(xmap);
    display.addMap(ymap);
    display.addDisplayListener(this);

    new RubberBandBox(this, xmap, ymap);

    if (displayControl == null) { // - add in a ref for the default spectrum, ie no DisplayControl
      DataReferenceImpl spectrumRef = new DataReferenceImpl(hashCode() + "_spectrumRef");
      spectrumRef.setData(spectrum);
      addRef(spectrumRef, Color.WHITE);
    }

    if (data.hasBandNames()) {
      bandSelectComboBox = new JComboBox(data.getBandNames().toArray());
      bandSelectComboBox.setSelectedItem(data.init_bandName);
      bandSelectComboBox.addActionListener(
          new ActionListener() {
            public void actionPerformed(ActionEvent e) {
              String bandName = (String) bandSelectComboBox.getSelectedItem();
              if (bandName == null) return;

              HashMap<String, Float> bandMap = data.getBandNameMap();
              if (bandMap == null) return;

              if (!bandMap.containsKey(bandName)) return;

              setWaveNumber(bandMap.get(bandName));
            }
          });
    }
  }
  /** 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);
  }
Exemple #14
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  /**
   * 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);
  }