public void testInterpolate() {
MCoordinate mc0NaN = MCoordinate.create2d(0.0, 0.0);
MCoordinate mc0 = MCoordinate.create2dWithMeasure(0.0, 0.0, 0.0);
MCoordinate mc2NaN = MCoordinate.create2d(2.0, 0.0);
MCoordinate mc5NaN = MCoordinate.create2d(5.0, 0.0);
MCoordinate mc10NaN = MCoordinate.create2d(10.0, 0.0);
MCoordinate mc10 = MCoordinate.create2dWithMeasure(10.0, 0.0, 10.0);
// Internal coordinate measures are not defined, outer measures are
// 0-10, total 2d length is 10
MLineString line =
mgeomFactory.createMLineString(new MCoordinate[] {mc0, mc2NaN, mc5NaN, mc10});
MLineString lineBeginNaN =
mgeomFactory.createMLineString(new MCoordinate[] {mc0NaN, mc2NaN, mc5NaN, mc10});
MLineString lineEndNaN =
mgeomFactory.createMLineString(new MCoordinate[] {mc0, mc2NaN, mc5NaN, mc10NaN});
assertTrue(DoubleComparator.equals(line.getLength(), 10));
assertTrue(DoubleComparator.equals(lineBeginNaN.getLength(), 10));
assertTrue(DoubleComparator.equals(lineEndNaN.getLength(), 10));
line.interpolate(mc0.m, mc10.m);
lineBeginNaN.interpolate(mc0.m, mc10.m);
lineEndNaN.interpolate(mc0.m, mc10.m);
assertTrue(line.isMonotone(false));
assertTrue(line.isMonotone(true));
assertTrue(lineBeginNaN.isMonotone(false));
assertTrue(lineBeginNaN.isMonotone(true));
assertTrue(lineEndNaN.isMonotone(false));
assertTrue(lineEndNaN.isMonotone(true));
double[] expectedM = new double[] {mc0.m, 2.0, 5.0, mc10.m};
for (int i = 0; i < expectedM.length; i++) {
double actualMLine = line.getCoordinateSequence().getOrdinate(i, CoordinateSequence.M);
double actualBeginNaN =
lineBeginNaN.getCoordinateSequence().getOrdinate(i, CoordinateSequence.M);
double actualEndNaN = lineEndNaN.getCoordinateSequence().getOrdinate(i, CoordinateSequence.M);
assertTrue(DoubleComparator.equals(expectedM[i], actualMLine));
assertTrue(DoubleComparator.equals(expectedM[i], actualBeginNaN));
assertTrue(DoubleComparator.equals(expectedM[i], actualEndNaN));
}
// Test Continuous case by interpolating with begin and end measures
// equal
double continuousMeasure = 0.0D;
line.interpolate(continuousMeasure, continuousMeasure);
double[] measures = line.getMeasures();
for (int i = 0; i < measures.length; i++)
assertTrue(DoubleComparator.equals(measures[i], continuousMeasure));
}
public void testGetClosestPoint() {
try {
if (!arbitraryLine.isMonotone(false)) {
Coordinate mc = arbitraryLine.getClosestPoint(new Coordinate(1.0, 2.0), 0.1);
assertTrue(false); // should never evaluate this
}
} catch (Exception e) {
assertTrue(
((MGeometryException) e).getType() == MGeometryException.OPERATION_REQUIRES_MONOTONE);
}
try {
// check reaction on null string
MCoordinate mc = nullLine.getClosestPoint(new Coordinate(0.0, 1.0), 1.0);
assertNull(mc);
// must return the very same coordinate if the coordinate is a
// coordinate of the line
arbitraryLine.measureOnLength(false);
int selp = (int) (arbitraryLine.getNumPoints() / 2);
MCoordinate mcexp = (MCoordinate) arbitraryLine.getCoordinateN(selp);
MCoordinate mctest = arbitraryLine.getClosestPoint(mcexp, 1);
assertEquals(mcexp, mctest);
// must not return a point that is beyond the tolerance
mctest = controlledLine.getClosestPoint(new Coordinate(20.0, 20, 0), 1.0);
assertNull(mctest);
// check for cases of circular MGeometry: lowest measure should be
// return.
ringLine.measureOnLength(false);
assertTrue(ringLine.isRing());
assertTrue(ringLine.isMonotone(false));
assertTrue(ringLine.getMeasureDirection() == MGeometry.INCREASING);
MCoordinate expCo = MCoordinate.create2dWithMeasure(0.0, 0.0, 0.0);
MCoordinate testCo = ringLine.getClosestPoint(expCo, 0.1);
assertTrue(DoubleComparator.equals(testCo.m, expCo.m));
ringLine.reverseMeasures();
testCo = ringLine.getClosestPoint(expCo, 0.1);
assertTrue(DoubleComparator.equals(testCo.m, expCo.m));
ringLine.measureOnLength(false);
int n = ringLine.getNumPoints() - 1;
ringLine.setMeasureAtIndex(n, 100.0);
ringLine.setMeasureAtIndex(0, 0.0);
testCo = ringLine.getClosestPoint(expCo, 0.001);
assertTrue(DoubleComparator.equals(testCo.m, 0.0));
// get two neighbouring points along the arbitraryline
arbitraryLine.measureOnLength(false);
int elem1Indx = (int) (Math.random() * (arbitraryLine.getNumPoints() - 1));
int elem2Indx = 0;
if (elem1Indx == arbitraryLine.getNumPoints() - 1) {
elem2Indx = elem1Indx - 1;
} else {
elem2Indx = elem1Indx + 1;
}
// testsuite-suite whether a coordinate between these two returns exactly
MCoordinate mco1 = (MCoordinate) arbitraryLine.getCoordinateN(elem1Indx);
MCoordinate mco2 = (MCoordinate) arbitraryLine.getCoordinateN(elem2Indx);
double d = mco1.distance(mco2);
double offset = Math.random();
mcexp =
MCoordinate.create2dWithMeasure(
mco1.x + offset * (mco2.x - mco1.x), mco1.y + offset * (mco2.y - mco1.y), 0.0);
mctest = arbitraryLine.getClosestPoint(mcexp, d);
mcexp.m = mco1.m + offset * (mco2.m - mco1.m);
assertEquals(mcexp.x, mctest.x, 0.001);
assertEquals(mcexp.y, mctest.y, 0.001);
assertEquals(mcexp.z, mctest.z, 0.001);
double delta = Math.random();
MCoordinate mcin =
MCoordinate.create2dWithMeasure(
mco1.x + offset * (mco2.x - mco1.x) + delta,
mco1.y + offset * (mco2.y - mco1.y) + delta,
0.0);
// returned point is on the line
mctest = arbitraryLine.getClosestPoint(mcin, d);
assertEquals(mcin.x, mctest.x, delta * Math.sqrt(2));
assertEquals(mcin.y, mctest.y, delta * Math.sqrt(2));
} catch (Exception e) {
e.printStackTrace();
assertTrue(false); // should never reach this point
}
}