private Geometry getSimpleLine(final Geometry geometry, final double dTolerance) {
Geometry simple;
if (m_bPreserve) {
simple = TopologyPreservingSimplifier.simplify(geometry, dTolerance);
} else {
simple = DouglasPeuckerSimplifier.simplify(geometry, dTolerance);
}
return simple;
}
@Override
public void decodeData(boolean autoClosed)
throws DecodeException, IOException, TransformException {
super.decodeData(autoClosed);
polyMultimap = ArrayListMultimap.create();
radialDataBlock = new RadialDataBlock();
radialDataBlock.builder(this.decodeCinradXHeader.getRandomAccessFile(), -1);
if (autoClosed) {
this.decodeCinradXHeader.getRandomAccessFile().close();
}
SimpleFeatureTypeBuilder builder = new SimpleFeatureTypeBuilder();
builder.setCRS(crs);
builder.setName("Cinrad-X Radial Data");
builder.add("geom", Geometry.class);
builder.add("colorIndex", Float.class);
builder.add("value", Float.class);
schema = builder.buildFeatureType();
// Reset index counter
geoIndex = 0;
if (getPlaneFeatures() == null) {
planeFeatures = new DefaultFeatureCollection();
}
planeFeatures.clear();
double minA = filter.getMinAzimuth();
double maxA = filter.getMaxAzimuth();
if (maxA - minA < 360.0) {
while (minA >= 360.0) {
minA -= 360.0;
maxA -= 360.0;
}
}
for (RadialData data : radialDataBlock.getRadialDatas()) {
if (testInAzimuthRange(data, minA, maxA)) {
double startAngle = data.getStartAngle();
double endAngle = startAngle + data.getAngleWidth();
// double angle1 = 90.0 - startAngle;
// double angle2 = 90.0 - endAngle;
if (startAngle < 0) {
startAngle += 360;
}
if (endAngle < 0) {
endAngle += 360;
}
// Add .00000001 to any 0, 90, 180, 270, 360 values to prevent
// sin
// or cos error
if (startAngle == 0.0
|| startAngle == 90.0
|| startAngle == 180.0
|| startAngle == 270.0
|| startAngle == 360.0) {
startAngle += 0.00001;
}
if (endAngle == 0.0
|| endAngle == 90.0
|| endAngle == 180.0
|| endAngle == 270.0
|| endAngle == 360.0) {
endAngle += 0.00001;
}
startAngle = Math.toRadians(startAngle);
endAngle = Math.toRadians(endAngle);
int startRange = data.getRadialHeader().getStartRange();
int key;
float value;
for (Map.Entry<Integer, Float> entry : data.getDataValueArray().entrySet()) {
value = entry.getValue();
if (testValueRange(value)) {
key = entry.getKey();
// double[] geoXY;
double[] albX = new double[4];
double[] albY = new double[4];
int length1 = startRange + key * data.getRadialHeader().getResolution();
albX[0] = length1 * Math.sin(startAngle);
albY[0] = length1 * Math.cos(startAngle);
albX[1] = length1 * Math.sin(endAngle);
albY[1] = length1 * Math.cos(endAngle);
int length2 = length1 + data.getRadialHeader().getResolution();
albX[2] = length2 * Math.sin(endAngle);
albY[2] = length2 * Math.cos(endAngle);
albX[3] = length2 * Math.sin(startAngle);
albY[3] = length2 * Math.cos(startAngle);
Coordinate[] cArray = new Coordinate[5];
// Add the first point
double[] srcPts0 = {albX[0], albY[0]};
double[] dstPts0 = new double[2];
cinradTransform.transform(srcPts0, 0, dstPts0, 0, 1);
cArray[0] = new Coordinate(dstPts0[0], dstPts0[1]);
for (int nr = 1; nr < albX.length; nr++) {
double[] srcPts = {albX[nr], albY[nr]};
double[] dstPts = new double[2];
cinradTransform.transform(srcPts, 0, dstPts, 0, 1);
cArray[nr] = new Coordinate(dstPts[0], dstPts[1]);
}
// Add the first point again to close polygon
cArray[4] = new Coordinate(dstPts0[0], dstPts0[1]);
LinearRing lr = geoFactory.createLinearRing(cArray);
Polygon poly = JTSUtilities.makeGoodShapePolygon(geoFactory.createPolygon(lr, null));
// System.out.println("value:" + entry.getValue());
if (configuration.getBoolean(COLOR_MODE, true)) {
polyMultimap.put(CinradXUtils.getRadialColorIndex(entry.getValue()) * 1.0f, poly);
} else {
polyMultimap.put(entry.getValue(), poly);
}
}
}
}
}
Set<Float> valueSet = polyMultimap.keySet();
// System.out.println(valueSet.size());
if (valueSet.size() > 0) {
for (Float v : valueSet) {
Float color = new Float(v);
Float value = color;
if (configuration.getBoolean(COLOR_MODE, true)) {
value = color * 5;
}
if (configuration.getBoolean(REDUCE_POLYGONS, true)) {
logger.debug("REDUCING POLYGONS!");
if (polyMultimap.get(v).size() > 0) {
Polygon[] polyArray = new Polygon[polyMultimap.get(v).size()];
GeometryCollection polyCollection =
geoFactory.createGeometryCollection(polyMultimap.get(v).toArray(polyArray));
Geometry union = polyCollection.buffer(geometryBuffer);
union = TopologyPreservingSimplifier.simplify(union, geometrySimplify);
logger.debug("Geometry Type:" + union.getGeometryType());
// polyMultimap.get(v).clear();
if (union.getGeometryType().equalsIgnoreCase("MultiPolygon")) {
// logger.debug(union.toString());
if (configuration.getBoolean(MULTIPOLYGON_MODE, true)) {
SimpleFeature feature =
SimpleFeatureBuilder.build(
schema,
new Object[] {union, color, value},
new Integer(geoIndex++).toString());
planeFeatures.add(feature);
} else {
MultiPolygon multiPolygon = (MultiPolygon) union;
for (int j = 0; j < multiPolygon.getNumGeometries(); j++) {
// create the feature
SimpleFeature feature =
SimpleFeatureBuilder.build(
schema,
new Object[] {(Geometry) multiPolygon.getGeometryN(j), color, value},
new Integer(geoIndex++).toString());
planeFeatures.add(feature);
// logger.debug(feature.toString());
}
}
} else if (union.getGeometryType().equalsIgnoreCase("Polygon")) {
if (configuration.getBoolean(MULTIPOLYGON_MODE, true)) {
// create the feature
Polygon[] pa = {(Polygon) union};
SimpleFeature feature =
SimpleFeatureBuilder.build(
schema,
new Object[] {(Geometry) new MultiPolygon(pa, geoFactory), color, value},
new Integer(geoIndex++).toString());
planeFeatures.add(feature);
} else {
// create the feature
SimpleFeature feature =
SimpleFeatureBuilder.build(
schema,
new Object[] {(Geometry) union, color, value},
new Integer(geoIndex++).toString());
planeFeatures.add(feature);
}
// logger.debug(feature.toString());
}
}
} else {
for (Polygon poly : polyMultimap.get(v)) {
SimpleFeature feature =
SimpleFeatureBuilder.build(
schema, new Object[] {poly, color, value}, new Integer(geoIndex++).toString());
planeFeatures.add(feature);
// logger.debug(feature.toString());
}
}
}
}
}
private Geometry generalize(Geometry g, double tolerance) {
return TopologyPreservingSimplifier.simplify(g, tolerance);
}
