protected void preCache(List<Position> grid, Position centerPosition)
throws InterruptedException {
// Pre-cache the tiles that will be needed for the intersection calculations.
double n = 0;
final long start = System.currentTimeMillis();
for (Position gridPos : grid) // for each grid point.
{
final double progress = 100 * (n++ / grid.size());
terrain.cacheIntersectingTiles(centerPosition, gridPos);
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
progressBar.setValue((int) progress);
progressBar.setString(null);
}
});
}
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
progressBar.setValue(100);
}
});
long end = System.currentTimeMillis();
System.out.printf(
"Pre-caching time %d milliseconds, cache usage %f, tiles %d\n",
end - start, terrain.getCacheUsage(), terrain.getNumCacheEntries());
}
protected void computeAndShowIntersections(final Position curPos) {
this.previousCurrentPosition = curPos;
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
setCursor(WaitCursor);
}
});
// Dispatch the calculation threads in a separate thread to avoid locking up the user
// interface.
this.calculationDispatchThread =
new Thread(
new Runnable() {
public void run() {
try {
performIntersectionTests(curPos);
} catch (InterruptedException e) {
System.out.println("Operation was interrupted");
}
}
});
this.calculationDispatchThread.start();
}
public void showCommunicationErrorDialogLater(
final Exception e, final String message, final Object... args) {
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
showCommunicationErrorDialog(e, message, args);
}
});
}
protected void performIntersectionTests(final Position curPos) throws InterruptedException {
// Clear the results lists when the user selects a new location.
this.firstIntersectionPositions.clear();
this.sightLines.clear();
// Raise the selected location and the grid points a little above ground just to show we can.
final double height = 5; // meters
// Form the grid.
double gridRadius = GRID_RADIUS.degrees;
Sector sector =
Sector.fromDegrees(
curPos.getLatitude().degrees - gridRadius, curPos.getLatitude().degrees + gridRadius,
curPos.getLongitude().degrees - gridRadius,
curPos.getLongitude().degrees + gridRadius);
this.grid = buildGrid(sector, height, GRID_DIMENSION, GRID_DIMENSION);
this.numGridPoints = grid.size();
// Compute the position of the selected location (incorporate its height).
this.referencePosition = new Position(curPos.getLatitude(), curPos.getLongitude(), height);
this.referencePoint =
terrain.getSurfacePoint(curPos.getLatitude(), curPos.getLongitude(), height);
// // Pre-caching is unnecessary and is useful only when it occurs before the
// intersection
// // calculations. It will incur extra overhead otherwise. The normal intersection
// calculations
// // cause the same caching, making subsequent calculations on the same area
// faster.
// this.preCache(grid, this.referencePosition);
// On the EDT, show the grid.
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
progressBar.setValue(0);
progressBar.setString(null);
clearLayers();
showGrid(grid, referencePosition);
getWwd().redraw();
}
});
// Perform the intersection calculations.
this.startTime = System.currentTimeMillis();
for (Position gridPos : this.grid) // for each grid point.
{
//noinspection ConstantConditions
if (NUM_THREADS > 0) this.threadPool.execute(new Intersector(gridPos));
else performIntersection(gridPos);
}
}
public void start(String appConfigurationLocation, Dimension appSize) throws Exception {
this.appTitle = Configuration.getStringValue(Constants.APPLICATION_DISPLAY_NAME);
this.appSize = appSize;
this.unitsFormat = new WWOUnitsFormat();
this.unitsFormat.setShowUTM(true);
this.unitsFormat.setShowWGS84(true);
this.appConfigurationLocation = appConfigurationLocation;
final AppConfiguration appConfig = new AppConfiguration();
appConfig.initialize(this);
appConfig.configure(this.appConfigurationLocation);
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
redraw();
}
});
}
/** Keeps the progress meter current. When calculations are complete, displays the results. */
protected synchronized void updateProgress() {
// Update the progress bar only once every 250 milliseconds to avoid stealing time from
// calculations.
if (this.sightLines.size() >= this.numGridPoints) endTime = System.currentTimeMillis();
else if (System.currentTimeMillis() < this.lastTime + 250) return;
this.lastTime = System.currentTimeMillis();
// On the EDT, update the progress bar and if calculations are complete, update the World
// Window.
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
int progress = (int) (100d * getSightlinesSize() / (double) numGridPoints);
progressBar.setValue(progress);
if (progress >= 100) {
setCursor(Cursor.getDefaultCursor());
progressBar.setString((endTime - startTime) + " ms");
showResults();
System.out.printf("Calculation time %d milliseconds\n", endTime - startTime);
}
}
});
}
protected void importImagery() {
try {
// Read the data and save it in a temp file.
File sourceFile = ExampleUtil.saveResourceToTempFile(IMAGE_PATH, ".tif");
// Create a raster reader to read this type of file. The reader is created from the
// currently
// configured factory. The factory class is specified in the Configuration, and a different
// one can be
// specified there.
DataRasterReaderFactory readerFactory =
(DataRasterReaderFactory)
WorldWind.createConfigurationComponent(AVKey.DATA_RASTER_READER_FACTORY_CLASS_NAME);
DataRasterReader reader = readerFactory.findReaderFor(sourceFile, null);
// Before reading the raster, verify that the file contains imagery.
AVList metadata = reader.readMetadata(sourceFile, null);
if (metadata == null || !AVKey.IMAGE.equals(metadata.getStringValue(AVKey.PIXEL_FORMAT)))
throw new Exception("Not an image file.");
// Read the file into the raster. read() returns potentially several rasters if there are
// multiple
// files, but in this case there is only one so just use the first element of the returned
// array.
DataRaster[] rasters = reader.read(sourceFile, null);
if (rasters == null || rasters.length == 0)
throw new Exception("Can't read the image file.");
DataRaster raster = rasters[0];
// Determine the sector covered by the image. This information is in the GeoTIFF file or
// auxiliary
// files associated with the image file.
final Sector sector = (Sector) raster.getValue(AVKey.SECTOR);
if (sector == null) throw new Exception("No location specified with image.");
// Request a sub-raster that contains the whole image. This step is necessary because only
// sub-rasters
// are reprojected (if necessary); primary rasters are not.
int width = raster.getWidth();
int height = raster.getHeight();
// getSubRaster() returns a sub-raster of the size specified by width and height for the
// area indicated
// by a sector. The width, height and sector need not be the full width, height and sector
// of the data,
// but we use the full values of those here because we know the full size isn't huge. If it
// were huge
// it would be best to get only sub-regions as needed or install it as a tiled image layer
// rather than
// merely import it.
DataRaster subRaster = raster.getSubRaster(width, height, sector, null);
// Tne primary raster can be disposed now that we have a sub-raster. Disposal won't affect
// the
// sub-raster.
raster.dispose();
// Verify that the sub-raster can create a BufferedImage, then create one.
if (!(subRaster instanceof BufferedImageRaster))
throw new Exception("Cannot get BufferedImage.");
BufferedImage image = ((BufferedImageRaster) subRaster).getBufferedImage();
// The sub-raster can now be disposed. Disposal won't affect the BufferedImage.
subRaster.dispose();
// Create a SurfaceImage to display the image over the specified sector.
final SurfaceImage si1 = new SurfaceImage(image, sector);
// On the event-dispatch thread, add the imported data as an SurfaceImageLayer.
SwingUtilities.invokeLater(
new Runnable() {
public void run() {
// Add the SurfaceImage to a layer.
SurfaceImageLayer layer = new SurfaceImageLayer();
layer.setName("Imported Surface Image");
layer.setPickEnabled(false);
layer.addRenderable(si1);
// Add the layer to the model and update the application's layer panel.
insertBeforeCompass(AppFrame.this.getWwd(), layer);
AppFrame.this.getLayerPanel().update(AppFrame.this.getWwd());
// Set the view to look at the imported image.
ExampleUtil.goTo(getWwd(), sector);
}
});
} catch (Exception e) {
e.printStackTrace();
}
}
