public void ensureIncreasingTime() { if (getPositionCount() < 2) return; long completeTime = getTime(); // ms double completeDistance = getDistance(); // m double averageSpeed = completeTime > 0 ? completeDistance / completeTime * 1000 : 1.0; // m/s List<P> positions = getPositions(); P first = positions.get(0); if (!first.hasTime()) first.setTime(fromCalendar(Calendar.getInstance(UTC))); P previous = first; for (int i = 1; i < positions.size(); i++) { P next = positions.get(i); CompactCalendar time = next.getTime(); if (time == null || time.equals(previous.getTime())) { Double distance = next.calculateDistance(previous); Long millis = distance != null ? (long) (distance / averageSpeed * 1000) : null; if (millis == null || millis < 1000) millis = 1000L; next.setTime( fromMillisAndTimeZone( previous.getTime().getTimeInMillis() + millis, previous.getTime().getTimeZoneId())); } previous = next; } }
private void move(int index, int upOrDown) { List<P> positions = getPositions(); P move = positions.get(index); P replace = positions.get(index + upOrDown); positions.set(index + upOrDown, move); positions.set(index, replace); }
public double getElevationDelta(int index) { List<P> positions = getPositions(); NavigationPosition previous = index > 0 ? positions.get(index - 1) : null; NavigationPosition current = index < positions.size() ? positions.get(index) : null; if (previous != null && current != null) { Double elevation = previous.calculateElevation(current); if (elevation != null) return elevation; } return 0; }
public int[] getPositionsWithinDistanceToPredecessor(double distance) { List<Integer> result = new ArrayList<>(); List<P> positions = getPositions(); if (positions.size() <= 2) return new int[0]; P previous = positions.get(0); for (int i = 1; i < positions.size() - 1; i++) { P next = positions.get(i); if (!next.hasCoordinates() || next.calculateDistance(previous) <= distance) result.add(i); else previous = next; } return toArray(result); }
public double[] getDistancesFromStart(int startIndex, int endIndex) { double[] result = new double[endIndex - startIndex + 1]; List<P> positions = getPositions(); int index = 0; double distance = 0.0; NavigationPosition previous = positions.size() > 0 ? positions.get(0) : null; while (index <= endIndex) { NavigationPosition next = positions.get(index); if (previous != null) { Double delta = previous.calculateDistance(next); if (delta != null) distance += delta; if (index >= startIndex) result[index - startIndex] = distance; } index++; previous = next; } return result; }
public int[] getContainedPositions(BoundingBox boundingBox) { List<Integer> result = new ArrayList<>(); List<P> positions = getPositions(); for (int i = 0; i < positions.size(); i++) { P position = positions.get(i); if (position.hasCoordinates() && boundingBox.contains(position)) result.add(i); } return toArray(result); }
/** * Removes duplicate adjacent {@link #getPositions() positions} from this route, leaving only * distinct neighbours */ public void removeDuplicates() { List<P> positions = getPositions(); P previous = null; int index = 0; while (index < positions.size()) { P next = positions.get(index); if (previous != null && (!next.hasCoordinates() || next.calculateDistance(previous) <= 0.0)) { positions.remove(index); } else index++; previous = next; } }
public double getElevationDescend(int startIndex, int endIndex) { double result = 0; List<P> positions = getPositions(); NavigationPosition previous = null; for (int i = startIndex; i <= endIndex; i++) { NavigationPosition next = positions.get(i); if (previous != null) { Double elevation = previous.calculateElevation(next); if (elevation != null && elevation < 0) result += abs(elevation); } previous = next; } return result; }
public double getDistance(int startIndex, int endIndex) { double result = 0; List<P> positions = getPositions(); NavigationPosition previous = null; for (int i = startIndex; i <= endIndex; i++) { NavigationPosition next = positions.get(i); if (previous != null) { Double distance = previous.calculateDistance(next); if (distance != null) result += distance; } previous = next; } return result; }
public double[] getDistancesFromStart(int[] indices) { double[] result = new double[indices.length]; if (indices.length > 0 && getPositionCount() > 0) { Arrays.sort(indices); int endIndex = min(indices[indices.length - 1], getPositionCount() - 1); int index = 0; double distance = 0.0; List<P> positions = getPositions(); NavigationPosition previous = positions.get(0); while (index <= endIndex) { NavigationPosition next = positions.get(index); if (previous != null) { Double delta = previous.calculateDistance(next); if (delta != null) distance += delta; int indexInIndices = binarySearch(indices, index); if (indexInIndices >= 0) result[indexInIndices] = distance; } index++; previous = next; } } return result; }
public int getClosestPosition(double longitude, double latitude, double threshold) { int closestIndex = -1; double closestDistance = MAX_VALUE; List<P> positions = getPositions(); for (int i = 0; i < positions.size(); ++i) { P point = positions.get(i); Double distance = point.calculateDistance(longitude, latitude); if (distance != null && distance < closestDistance && distance < threshold) { closestDistance = distance; closestIndex = i; } } return closestIndex; }
public void order(List<P> positions) { List<P> existing = getPositions(); for (int i = 0; i < positions.size(); i++) { existing.set(i, positions.get(i)); } }
public P getSuccessor(P position) { List<P> positions = getPositions(); int index = positions.indexOf(position); return index != -1 && index < positions.size() - 1 ? positions.get(index + 1) : null; }