package net.osmand.router; import gnu.trove.map.hash.TLongObjectHashMap; import java.io.IOException; import java.text.MessageFormat; import java.util.ArrayList; import java.util.Comparator; import java.util.Iterator; import java.util.List; import java.util.PriorityQueue; import net.osmand.PlatformUtil; import net.osmand.binary.RouteDataBorderLinePoint; import net.osmand.binary.RouteDataObject; import net.osmand.osm.MapRenderingTypes; import net.osmand.util.MapUtils; import org.apache.commons.logging.Log; public class BinaryRoutePlanner { private final int REVERSE_WAY_RESTRICTION_ONLY = 1024; /*private*/ final int STANDARD_ROAD_IN_QUEUE_OVERHEAD = 220; /*private */final int STANDARD_ROAD_VISITED_OVERHEAD = 150; protected static final Log log = PlatformUtil.getLog(BinaryRoutePlanner.class); private static final int ROUTE_POINTS = 11; private static final boolean TRACE_ROUTING = false; public static double squareRootDist(int x1, int y1, int x2, int y2) { // translate into meters double dy = MapUtils.convert31YToMeters(y1, y2); double dx = MapUtils.convert31XToMeters(x1, x2); return Math.sqrt(dx * dx + dy * dy); // return measuredDist(x1, y1, x2, y2); } private static class SegmentsComparator implements Comparator { final RoutingContext ctx; public SegmentsComparator(RoutingContext ctx) { this.ctx = ctx; } @Override public int compare(RouteSegment o1, RouteSegment o2) { return ctx.roadPriorityComparator(o1.distanceFromStart, o1.distanceToEnd, o2.distanceFromStart, o2.distanceToEnd); } } private static class NonHeuristicSegmentsComparator implements Comparator { public NonHeuristicSegmentsComparator() { } @Override public int compare(RouteSegment o1, RouteSegment o2) { return roadPriorityComparator(o1.distanceFromStart, o1.distanceToEnd, o2.distanceFromStart, o2.distanceToEnd, 0.5); } } /** * Calculate route between start.segmentEnd and end.segmentStart (using A* algorithm) * return list of segments */ @SuppressWarnings("unused") FinalRouteSegment searchRouteInternal(final RoutingContext ctx, RouteSegment start, RouteSegment end) throws InterruptedException, IOException { // measure time ctx.timeToLoad = 0; ctx.visitedSegments = 0; ctx.memoryOverhead = 1000; ctx.timeToCalculate = System.nanoTime(); if(ctx.config.initialDirection != null) { // mark here as positive for further check ctx.firstRoadId = calculateRoutePointId(start.getRoad(), start.getSegmentStart(), true); double plusDir = start.getRoad().directionRoute(start.getSegmentStart(), true); double diff = plusDir - ctx.config.initialDirection; if(Math.abs(MapUtils.alignAngleDifference(diff)) <= Math.PI / 3) { ctx.firstRoadDirection = 1; } else if(Math.abs(MapUtils.alignAngleDifference(diff - Math.PI)) <= Math.PI / 3) { ctx.firstRoadDirection = -1; } } // Initializing priority queue to visit way segments Comparator nonHeuristicSegmentsComparator = new NonHeuristicSegmentsComparator(); PriorityQueue graphDirectSegments = new PriorityQueue(50, new SegmentsComparator(ctx)); PriorityQueue graphReverseSegments = new PriorityQueue(50, new SegmentsComparator(ctx)); // Set to not visit one segment twice (stores road.id << X + segmentStart) TLongObjectHashMap visitedDirectSegments = new TLongObjectHashMap(); TLongObjectHashMap visitedOppositeSegments = new TLongObjectHashMap(); RouteSegment recalcEndSegment = smartRecalculationEnabled(ctx, visitedOppositeSegments); boolean runRecalculation = false; if(recalcEndSegment != null) { runRecalculation = true; end = recalcEndSegment; } // for start : f(start) = g(start) + h(start) = 0 + h(start) = h(start) float estimatedDistance = (float) estimatedDistance(ctx, ctx.targetX, ctx.targetY, ctx.startX, ctx.startY); end.distanceToEnd = start.distanceToEnd = estimatedDistance; graphDirectSegments.add(start); graphReverseSegments.add(end); // Extract & analyze segment with min(f(x)) from queue while final segment is not found boolean inverse = false; boolean init = false; PriorityQueue graphSegments; if(inverse) { graphSegments = graphReverseSegments; } else { graphSegments = graphDirectSegments; } ctx.loadBorderPoints(); FinalRouteSegment finalSegment = null; while (!graphSegments.isEmpty()) { RouteSegment segment = graphSegments.poll(); // use accumulative approach ctx.memoryOverhead = (visitedDirectSegments.size() + visitedOppositeSegments.size()) * STANDARD_ROAD_VISITED_OVERHEAD + (graphDirectSegments.size() + graphReverseSegments.size()) * STANDARD_ROAD_IN_QUEUE_OVERHEAD; if(TRACE_ROUTING){ printRoad(">", segment); } if(segment instanceof FinalRouteSegment) { if(RoutingContext.SHOW_GC_SIZE){ log.warn("Estimated overhead " + (ctx.memoryOverhead / (1<<20))+ " mb"); printMemoryConsumption("Memory occupied after calculation : "); } finalSegment = (FinalRouteSegment) segment; break; } if (ctx.memoryOverhead > ctx.config.memoryLimitation * 0.95 && RoutingContext.SHOW_GC_SIZE) { printMemoryConsumption("Memory occupied before exception : "); } if(ctx.memoryOverhead > ctx.config.memoryLimitation * 0.95) { throw new IllegalStateException("There is no enough memory " + ctx.config.memoryLimitation/(1<<20) + " Mb"); } ctx.visitedSegments++; if (!inverse) { processRouteSegment(ctx, false, graphDirectSegments, visitedDirectSegments, segment, visitedOppositeSegments, true); processRouteSegment(ctx, false, graphDirectSegments, visitedDirectSegments, segment, visitedOppositeSegments, false); } else { processRouteSegment(ctx, true, graphReverseSegments, visitedOppositeSegments, segment, visitedDirectSegments, true); processRouteSegment(ctx, true, graphReverseSegments, visitedOppositeSegments,segment, visitedDirectSegments, false); } updateCalculationProgress(ctx, graphDirectSegments, graphReverseSegments); if(graphReverseSegments.isEmpty()){ throw new IllegalArgumentException("Route is not found to selected target point."); } if(graphDirectSegments.isEmpty()){ throw new IllegalArgumentException("Route is not found from selected start point."); } if(runRecalculation) { // nothing to do inverse = false; } else if (!init) { inverse = !inverse; init = true; } else if (ctx.planRouteIn2Directions()) { inverse = nonHeuristicSegmentsComparator.compare(graphDirectSegments.peek(), graphReverseSegments.peek()) > 0; if (graphDirectSegments.size() * 1.3 > graphReverseSegments.size()) { inverse = true; } else if (graphDirectSegments.size() < 1.3 * graphReverseSegments.size()) { inverse = false; } } else { // different strategy : use onedirectional graph inverse = ctx.getPlanRoadDirection() < 0; } if (inverse) { graphSegments = graphReverseSegments; } else { graphSegments = graphDirectSegments; } // check if interrupted if(ctx.calculationProgress != null && ctx.calculationProgress.isCancelled) { throw new InterruptedException("Route calculation interrupted"); } } printDebugMemoryInformation(ctx, graphDirectSegments, graphReverseSegments, visitedDirectSegments, visitedOppositeSegments); return finalSegment; } private void printMemoryConsumption( String string) { long h1 = RoutingContext.runGCUsedMemory(); float mb = (1 << 20); log.warn(string + h1 / mb); } private void updateCalculationProgress(final RoutingContext ctx, PriorityQueue graphDirectSegments, PriorityQueue graphReverseSegments) { if(ctx.calculationProgress != null) { ctx.calculationProgress.reverseSegmentQueueSize = graphReverseSegments.size(); ctx.calculationProgress.directSegmentQueueSize = graphDirectSegments.size(); if(graphDirectSegments.size() > 0) { ctx.calculationProgress.distanceFromBegin = Math.max(graphDirectSegments.peek().distanceFromStart, ctx.calculationProgress.distanceFromBegin); } if(graphDirectSegments.size() > 0) { ctx.calculationProgress.distanceFromEnd = Math.max(graphReverseSegments.peek().distanceFromStart, ctx.calculationProgress.distanceFromBegin); } } } private RouteSegment smartRecalculationEnabled(final RoutingContext ctx, TLongObjectHashMap visitedOppositeSegments) { boolean runRecalculation = ctx.previouslyCalculatedRoute != null && ctx.previouslyCalculatedRoute.size() > 0 && ctx.config.recalculateDistance != 0; if (runRecalculation) { RouteSegment previous = null; List rlist = new ArrayList(); float distanceThreshold = ctx.config.recalculateDistance; float threshold = 0; for(RouteSegmentResult rr : ctx.previouslyCalculatedRoute) { threshold += rr.getDistance(); if(threshold > distanceThreshold) { rlist.add(rr); } } runRecalculation = rlist.size() > 0; if (rlist.size() > 0) { for (RouteSegmentResult rr : rlist) { RouteSegment segment = new RouteSegment(rr.getObject(), rr.getEndPointIndex()); if (previous != null) { previous.setParentRoute(segment); previous.setParentSegmentEnd(rr.getStartPointIndex()); boolean positive = rr.getStartPointIndex() < rr.getEndPointIndex(); long t = calculateRoutePointId(rr.getObject(), positive ? rr.getEndPointIndex() - 1 : rr.getEndPointIndex(), positive); visitedOppositeSegments.put(t, segment); } previous = segment; } return previous; } } return null; } private void printRoad(String prefix, RouteSegment segment) { String pr; if(segment.parentRoute != null){ pr = " pend="+segment.parentSegmentEnd +" parent=" + segment.parentRoute.road; } else { pr = ""; } println(prefix +"" + segment.road + " ind=" + segment.getSegmentStart() + " ds=" + ((float)segment.distanceFromStart) + " es="+((float)segment.distanceToEnd) + pr); } private float estimatedDistance(final RoutingContext ctx, int targetEndX, int targetEndY, int startX, int startY) { double distance = squareRootDist(startX, startY, targetEndX, targetEndY); return (float) (distance / ctx.getRouter().getMaxDefaultSpeed()); } protected static float h(RoutingContext ctx, int begX, int begY, int endX, int endY, RouteSegment next) { double distToFinalPoint = squareRootDist(begX, begY, endX, endY); if (RoutingContext.USE_BORDER_LINES) { int begBorder = ctx.searchBorderLineIndex(begY); int endBorder = ctx.searchBorderLineIndex(endY); if (begBorder != endBorder) { double res = 0; boolean plus = begBorder < endBorder; boolean beginEqStart = begX == ctx.startX && begY == ctx.startY; boolean beginEqTarget = begX == ctx.targetX && begY == ctx.targetY; boolean endEqStart = endX == ctx.startX && endY == ctx.startY; boolean endEqTarget = endX == ctx.targetX && endY == ctx.targetY; if(endEqStart || endEqTarget) { // we start from intermediate point and end in target or start if (begX > ctx.leftBorderBoundary && begX < ctx.rightBorderBoundary) { List pnts = ctx.borderLines[plus ? begBorder : begBorder - 1].borderPoints; for (RouteDataBorderLinePoint p : pnts) { double f = (endEqTarget ? p.distanceToEndPoint : p.distanceToStartPoint) + squareRootDist(p.x, p.y, begX, begY); if (res > f || res <= 0) { res = f; } } } } else if(beginEqStart || beginEqTarget) { if (endX > ctx.leftBorderBoundary && endX < ctx.rightBorderBoundary) { List pnts = ctx.borderLines[plus ? endBorder - 1 : endBorder].borderPoints; for (RouteDataBorderLinePoint p : pnts) { double f = (beginEqTarget ? p.distanceToEndPoint : p.distanceToStartPoint) + squareRootDist(p.x, p.y, endX, endY); if (res > f || res <= 0) { res = f; } } } } else { throw new IllegalStateException(); } if(res > 0) { if(res < distToFinalPoint - 0.01) { throw new IllegalStateException("Estimated distance " + res + " > " + distToFinalPoint); } // if(endEqStart && res - distToFinalPoint > 13000) { // System.out.println(" Res="+res + " dist=" +distToFinalPoint); // } distToFinalPoint = res; } else { // FIXME put penalty // distToFinalPoint = distToFinalPoint; } } } double result = distToFinalPoint / ctx.getRouter().getMaxDefaultSpeed(); return (float) result; } private static void println(String logMsg) { // log.info(logMsg); System.out.println(logMsg); } private static void printInfo(String logMsg) { log.warn(logMsg); } public void printDebugMemoryInformation(RoutingContext ctx, PriorityQueue graphDirectSegments, PriorityQueue graphReverseSegments, TLongObjectHashMap visitedDirectSegments,TLongObjectHashMap visitedOppositeSegments) { printInfo("Time to calculate : " + (System.nanoTime() - ctx.timeToCalculate) / 1e6 + ", time to load : " + ctx.timeToLoad / 1e6 + ", time to load headers : " + ctx.timeToLoadHeaders / 1e6); int maxLoadedTiles = Math.max(ctx.maxLoadedTiles, ctx.getCurrentlyLoadedTiles()); printInfo("Current loaded tiles : " + ctx.getCurrentlyLoadedTiles() + ", maximum loaded tiles " + maxLoadedTiles); printInfo("Loaded tiles " + ctx.loadedTiles + " (distinct "+ctx.distinctLoadedTiles+ "), unloaded tiles " + ctx.unloadedTiles + ", loaded more than once same tiles " + ctx.loadedPrevUnloadedTiles ); printInfo("Visited roads " + ctx.visitedSegments + ", relaxed roads " + ctx.relaxedSegments); if (graphDirectSegments != null && graphReverseSegments != null) { printInfo("Priority queues sizes : " + graphDirectSegments.size() + "/" + graphReverseSegments.size()); } if (visitedDirectSegments != null && visitedOppositeSegments != null) { printInfo("Visited interval sizes: " + visitedDirectSegments.size() + "/" + visitedOppositeSegments.size()); } for(int k=0; k> 17) + " points " + ctx.borderLines[k].borderPoints.size()); } } private void processRouteSegment(final RoutingContext ctx, boolean reverseWaySearch, PriorityQueue graphSegments, TLongObjectHashMap visitedSegments, RouteSegment segment, TLongObjectHashMap oppositeSegments, boolean direction) throws IOException { final RouteDataObject road = segment.road; boolean initDirectionAllowed = checkIfInitialMovementAllowedOnSegment(ctx, reverseWaySearch, visitedSegments, segment, direction, road); boolean directionAllowed = initDirectionAllowed; // Go through all point of the way and find ways to continue // ! Actually there is small bug when there is restriction to move forward on the way (it doesn't take into account) float obstaclesTime = 0; if(segment.getParentRoute() != null && directionAllowed) { obstaclesTime = (float) ctx.getRouter().calculateTurnTime(segment, direction? segment.getRoad().getPointsLength() - 1 : 0, segment.getParentRoute(), segment.getParentSegmentEnd()); } if(ctx.firstRoadId == calculateRoutePointId(road, segment.getSegmentStart(), true) ) { if(direction && ctx.firstRoadDirection < 0) { obstaclesTime += 500; } else if(!direction && ctx.firstRoadDirection > 0) { obstaclesTime += 500; } } float segmentDist = 0; // +/- diff from middle point int segmentEnd = segment.getSegmentStart(); while (directionAllowed) { int prevInd = segmentEnd; if(direction) { segmentEnd ++; } else { segmentEnd --; } if (segmentEnd < 0 || segmentEnd >= road.getPointsLength()) { directionAllowed = false; continue; } final int intervalId = direction ? segmentEnd - 1 : segmentEnd; visitedSegments.put(calculateRoutePointId(road, intervalId, direction), segment); final int x = road.getPoint31XTile(segmentEnd); final int y = road.getPoint31YTile(segmentEnd); final int prevx = road.getPoint31XTile(prevInd); final int prevy = road.getPoint31YTile(prevInd); if(x == prevx && y == prevy) { continue; } if(RoutingContext.USE_BORDER_LINES) { int st = ctx.searchBorderLineIndex(y); int tt = ctx.searchBorderLineIndex(prevy); if(st != tt){ // System.out.print(" " + st + " != " + tt + " " + road.id + " ? "); for(int i = Math.min(st, tt); i < Math.max(st, tt) & i < ctx.borderLines.length ; i++) { Iterator pnts = ctx.borderLines[i].borderPoints.iterator(); boolean changed = false; while(pnts.hasNext()) { RouteDataBorderLinePoint o = pnts.next(); if(o.id == road.id) { // System.out.println("Point removed !"); pnts.remove(); changed = true; } } if(changed){ ctx.updateDistanceForBorderPoints(ctx.startX, ctx.startY, true); ctx.updateDistanceForBorderPoints(ctx.targetX, ctx.targetY, false); } } } } // 2. calculate point and try to load neighbor ways if they are not loaded segmentDist += squareRootDist(x, y, prevx, prevy); // 2.1 calculate possible obstacle plus time double obstacle = ctx.getRouter().defineRoutingObstacle(road, segmentEnd); if (obstacle < 0) { directionAllowed = false; continue; } obstaclesTime += obstacle; boolean alreadyVisited = checkIfOppositieSegmentWasVisited(ctx, reverseWaySearch, graphSegments, segment, oppositeSegments, road, segmentEnd, direction, intervalId, segmentDist, obstaclesTime); if (alreadyVisited) { directionAllowed = false; continue; } // could be expensive calculation // 3. get intersected ways final RouteSegment roadNext = ctx.loadRouteSegment(x, y, ctx.config.memoryLimitation - ctx.memoryOverhead); if(roadNext != null && !((roadNext == segment || roadNext.road.id == road.id) && roadNext.next == null)) { // check if there are outgoing connections in that case we need to stop processing boolean outgoingConnections = false; RouteSegment r = roadNext; while(r != null && !outgoingConnections) { if(r.road.id != road.id || r.getSegmentStart() != 0 || r.road.getOneway() != 1){ outgoingConnections = true; } r = r.next; } if (outgoingConnections) { directionAllowed = false; } float distStartObstacles = segment.distanceFromStart + calculateTimeWithObstacles(ctx, road, segmentDist , obstaclesTime); processIntersections(ctx, graphSegments, visitedSegments, distStartObstacles, segment, segmentEnd, roadNext, reverseWaySearch, outgoingConnections); } } if(initDirectionAllowed && ctx.visitor != null){ ctx.visitor.visitSegment(segment, segmentEnd, true); } } private boolean checkIfInitialMovementAllowedOnSegment(final RoutingContext ctx, boolean reverseWaySearch, TLongObjectHashMap visitedSegments, RouteSegment segment, boolean direction, final RouteDataObject road ) { boolean directionAllowed; final int middle = segment.getSegmentStart(); int oneway = ctx.getRouter().isOneWay(road); // use positive direction as agreed if (!reverseWaySearch) { if(direction){ directionAllowed = oneway >= 0; } else { directionAllowed = oneway <= 0; } } else { if(direction){ directionAllowed = oneway <= 0; } else { directionAllowed = oneway >= 0; } } if(direction) { if(middle == road.getPointsLength() - 1 || visitedSegments.containsKey(calculateRoutePointId(road, middle, true)) || segment.getAllowedDirection() == -1) { directionAllowed = false; } } else { if(middle == 0 || visitedSegments.containsKey(calculateRoutePointId(road, middle - 1, false)) || segment.getAllowedDirection() == 1) { directionAllowed = false; } } return directionAllowed; } private boolean checkIfOppositieSegmentWasVisited(final RoutingContext ctx, boolean reverseWaySearch, PriorityQueue graphSegments, RouteSegment segment, TLongObjectHashMap oppositeSegments, final RouteDataObject road, int segmentEnd, boolean positive, int intervalId, float segmentDist, float obstaclesTime) { long opp = calculateRoutePointId(road, intervalId, !positive); if (oppositeSegments.containsKey(opp)) { RouteSegment opposite = oppositeSegments.get(opp); if (opposite.getSegmentStart() == segmentEnd) { FinalRouteSegment frs = new FinalRouteSegment(road, segment.getSegmentStart()); float distStartObstacles = segment.distanceFromStart + calculateTimeWithObstacles(ctx, road, segmentDist , obstaclesTime); frs.setParentRoute(segment.getParentRoute()); frs.setParentSegmentEnd(segment.getParentSegmentEnd()); frs.reverseWaySearch = reverseWaySearch; frs.distanceFromStart = opposite.distanceFromStart + distStartObstacles; frs.distanceToEnd = 0; frs.opposite = opposite; graphSegments.add(frs); return true; } } return false; } private float calculateTimeWithObstacles(RoutingContext ctx, RouteDataObject road, float distOnRoadToPass, float obstaclesTime) { float priority = ctx.getRouter().defineSpeedPriority(road); float speed = (ctx.getRouter().defineSpeed(road) * priority); if (speed == 0) { speed = (ctx.getRouter().getMinDefaultSpeed() * priority); } // speed can not exceed max default speed according to A* if(speed > ctx.getRouter().getMaxDefaultSpeed()) { speed = ctx.getRouter().getMaxDefaultSpeed(); } return obstaclesTime + distOnRoadToPass / speed; } private long calculateRoutePointId(final RouteDataObject road, int intervalId, boolean positive) { return (road.getId() << ROUTE_POINTS) + (intervalId << 1) + (positive ? 1 : 0); } private boolean proccessRestrictions(RoutingContext ctx, RouteDataObject road, RouteSegment inputNext, boolean reverseWay) { ctx.segmentsToVisitPrescripted.clear(); ctx.segmentsToVisitNotForbidden.clear(); boolean exclusiveRestriction = false; RouteSegment next = inputNext; if (!reverseWay && road.getRestrictionLength() == 0) { return false; } if(!ctx.getRouter().restrictionsAware()) { return false; } while (next != null) { int type = -1; if (!reverseWay) { for (int i = 0; i < road.getRestrictionLength(); i++) { if (road.getRestrictionId(i) == next.road.id) { type = road.getRestrictionType(i); break; } } } else { for (int i = 0; i < next.road.getRestrictionLength(); i++) { int rt = next.road.getRestrictionType(i); long restrictedTo = next.road.getRestrictionId(i); if (restrictedTo == road.id) { type = rt; break; } // Check if there is restriction only to the other than current road if (rt == MapRenderingTypes.RESTRICTION_ONLY_RIGHT_TURN || rt == MapRenderingTypes.RESTRICTION_ONLY_LEFT_TURN || rt == MapRenderingTypes.RESTRICTION_ONLY_STRAIGHT_ON) { // check if that restriction applies to considered junk RouteSegment foundNext = inputNext; while (foundNext != null) { if (foundNext.getRoad().id == restrictedTo) { break; } foundNext = foundNext.next; } if (foundNext != null) { type = REVERSE_WAY_RESTRICTION_ONLY; // special constant } } } } if (type == REVERSE_WAY_RESTRICTION_ONLY) { // next = next.next; continue; } else if (type == -1 && exclusiveRestriction) { // next = next.next; continue; } else if (type == MapRenderingTypes.RESTRICTION_NO_LEFT_TURN || type == MapRenderingTypes.RESTRICTION_NO_RIGHT_TURN || type == MapRenderingTypes.RESTRICTION_NO_STRAIGHT_ON || type == MapRenderingTypes.RESTRICTION_NO_U_TURN) { // next = next.next; continue; } else if (type == -1) { // case no restriction ctx.segmentsToVisitNotForbidden.add(next); } else { // case exclusive restriction (only_right, only_straight, ...) // 1. in case we are going backward we should not consider only_restriction // as exclusive because we have many "in" roads and one "out" // 2. in case we are going forward we have one "in" and many "out" if (!reverseWay) { exclusiveRestriction = true; ctx.segmentsToVisitNotForbidden.clear(); ctx.segmentsToVisitPrescripted.add(next); } else { ctx.segmentsToVisitNotForbidden.add(next); } } next = next.next; } ctx.segmentsToVisitPrescripted.addAll(ctx.segmentsToVisitNotForbidden); return true; } private void processIntersections(RoutingContext ctx, PriorityQueue graphSegments, TLongObjectHashMap visitedSegments, float distFromStart, RouteSegment segment, int segmentEnd, RouteSegment inputNext, boolean reverseWaySearch, boolean addSameRoadFutureDirection) { byte searchDirection = reverseWaySearch ? (byte)-1 : (byte)1; boolean thereAreRestrictions = proccessRestrictions(ctx, segment.road, inputNext, reverseWaySearch); Iterator nextIterator = null; if (thereAreRestrictions) { nextIterator = ctx.segmentsToVisitPrescripted.iterator(); if(TRACE_ROUTING){ println(" >> There are restrictions"); } } // Calculate possible ways to put into priority queue RouteSegment next = inputNext; boolean hasNext = nextIterator == null || nextIterator.hasNext(); while (hasNext) { if (nextIterator != null) { next = nextIterator.next(); } boolean nextPlusNotAllowed = (next.getSegmentStart() == next.road.getPointsLength() - 1) || visitedSegments.containsKey(calculateRoutePointId(next.road, next.getSegmentStart(), true)); boolean nextMinusNotAllowed = (next.getSegmentStart() == 0) || visitedSegments.containsKey(calculateRoutePointId(next.road, next.getSegmentStart() - 1, false)); boolean sameRoadFutureDirection = next.road.id == segment.road.id && next.getSegmentStart() == segmentEnd; // road.id could be equal on roundabout, but we should accept them boolean alreadyVisited = nextPlusNotAllowed && nextMinusNotAllowed; boolean skipRoad = sameRoadFutureDirection && !addSameRoadFutureDirection; if (!alreadyVisited && !skipRoad) { int targetEndX = reverseWaySearch? ctx.startX : ctx.targetX; int targetEndY = reverseWaySearch? ctx.startY : ctx.targetY; float distanceToEnd = h(ctx, segment.getRoad().getPoint31XTile(segmentEnd), segment.getRoad().getPoint31YTile(segmentEnd), targetEndX, targetEndY, next); // assigned to wrong direction if(next.getDirectionAssigned() == -searchDirection){ next = new RouteSegment(next.getRoad(), next.getSegmentStart()); } if (next.getParentRoute() == null || ctx.roadPriorityComparator(next.distanceFromStart, next.distanceToEnd, distFromStart, distanceToEnd) > 0) { if (next.getParentRoute() != null) { if (!graphSegments.remove(next)) { throw new IllegalStateException("Should be handled by direction flag"); } } next.assignDirection(searchDirection); next.distanceFromStart = distFromStart; next.distanceToEnd = distanceToEnd; if(sameRoadFutureDirection) { next.setAllowedDirection((byte) (segment.getSegmentStart() < next.getSegmentStart() ? 1 : - 1)); } if(TRACE_ROUTING) { printRoad(" >>", next); } // put additional information to recover whole route after next.setParentRoute(segment); next.setParentSegmentEnd(segmentEnd); graphSegments.add(next); } if (ctx.visitor != null) { // ctx.visitor.visitSegment(next, false); } } else if(!sameRoadFutureDirection){ // the segment was already visited! We need to follow better route if it exists // that is very strange situation and almost exception (it can happen when we underestimate distnceToEnd) if (next.getDirectionAssigned() == searchDirection && distFromStart < next.distanceFromStart && next.road.id != segment.road.id) { if(ctx.config.heuristicCoefficient <= 1) { throw new IllegalStateException("distance from start " + distFromStart + " < " +next.distanceFromStart); } // That code is incorrect (when segment is processed itself, // then it tries to make wrong u-turn) - // this situation should be very carefully checked in future (seems to be fixed) next.distanceFromStart = distFromStart; next.setParentRoute(segment); next.setParentSegmentEnd(segmentEnd); if (ctx.visitor != null) { // ctx.visitor.visitSegment(next, false); } } } // iterate to next road if (nextIterator == null) { next = next.next; hasNext = next != null; } else { hasNext = nextIterator.hasNext(); } } } /*public */static int roadPriorityComparator(double o1DistanceFromStart, double o1DistanceToEnd, double o2DistanceFromStart, double o2DistanceToEnd, double heuristicCoefficient ) { // f(x) = g(x) + h(x) --- g(x) - distanceFromStart, h(x) - distanceToEnd (not exact) return Double.compare(o1DistanceFromStart + heuristicCoefficient * o1DistanceToEnd, o2DistanceFromStart + heuristicCoefficient * o2DistanceToEnd); } public interface RouteSegmentVisitor { public void visitSegment(RouteSegment segment, int segmentEnd, boolean poll); } public static class RouteSegment { final short segStart; final RouteDataObject road; // needed to store intersection of routes RouteSegment next = null; // search context (needed for searching route) // Initially it should be null (!) because it checks was it segment visited before RouteSegment parentRoute = null; short parentSegmentEnd = 0; // 1 - positive , -1 - negative, 0 not assigned byte directionAssgn = 0; // 1 - only positive allowed, -1 - only negative allowed byte allowedDirection = 0; // distance measured in time (seconds) float distanceFromStart = 0; float distanceToEnd = 0; public RouteSegment(RouteDataObject road, int segmentStart) { this.road = road; this.segStart = (short) segmentStart; } public byte getDirectionAssigned(){ return directionAssgn; } public RouteSegment getParentRoute() { return parentRoute; } public void setParentRoute(RouteSegment parentRoute) { this.parentRoute = parentRoute; } public void assignDirection(byte b) { directionAssgn = b; } public byte getAllowedDirection() { return allowedDirection; } public void setAllowedDirection(byte allowedDirection) { this.allowedDirection = allowedDirection; } public void setParentSegmentEnd(int parentSegmentEnd) { this.parentSegmentEnd = (short) parentSegmentEnd; } public int getParentSegmentEnd() { return parentSegmentEnd; } public RouteSegment getNext() { return next; } public int getSegmentStart() { return segStart; } public RouteDataObject getRoad() { return road; } public String getTestName(){ return MessageFormat.format("s{0,number,#.##} e{1,number,#.##}", ((float)distanceFromStart), ((float)distanceToEnd)); } public Iterator getIterator() { return new Iterator() { RouteSegment next = RouteSegment.this; @Override public void remove() { throw new UnsupportedOperationException(); } @Override public RouteSegment next() { RouteSegment c = next; if(next != null) { next = next.next; } return c; } @Override public boolean hasNext() { return next != null; } }; } } static class FinalRouteSegment extends RouteSegment { boolean reverseWaySearch; RouteSegment opposite; public FinalRouteSegment(RouteDataObject road, int segmentStart) { super(road, segmentStart); } } }