public RoutingContext(
RoutingRequest traverseOptions, Graph graph, Vertex from, Vertex to, boolean findPlaces) {
this.opt = traverseOptions;
this.graph = graph;
if (findPlaces) {
// normal mode, search for vertices based on fromPlace and toPlace
fromVertex = graph.streetIndex.getVertexForPlace(opt.getFromPlace(), opt);
toVertex = graph.streetIndex.getVertexForPlace(opt.getToPlace(), opt, fromVertex);
if (opt.intermediatePlaces != null) {
for (NamedPlace intermediate : opt.intermediatePlaces) {
Vertex vertex = graph.streetIndex.getVertexForPlace(intermediate, opt);
intermediateVertices.add(vertex);
}
}
} else {
// debug mode, force endpoint vertices to those specified rather than searching
fromVertex = from;
toVertex = to;
}
if (opt.getStartingTransitStopId() != null) {
TransitIndexService tis = graph.getService(TransitIndexService.class);
if (tis == null) {
throw new RuntimeException(
"Next/Previous/First/Last trip "
+ "functionality depends on the transit index. Rebuild "
+ "the graph with TransitIndexBuilder");
}
AgencyAndId stopId = opt.getStartingTransitStopId();
startingStop = tis.getPreBoardEdge(stopId).getToVertex();
}
origin = opt.arriveBy ? toVertex : fromVertex;
target = opt.arriveBy ? fromVertex : toVertex;
calendarService = graph.getCalendarService();
transferTable = graph.getTransferTable();
timetableSnapshot = null;
setServiceDays();
if (opt.batch) remainingWeightHeuristic = new TrivialRemainingWeightHeuristic();
else remainingWeightHeuristic = heuristicFactory.getInstanceForSearch(opt);
}
@Override
public List<GraphPath> plan(State origin, Vertex target, int nItineraries) {
Date targetTime = new Date(origin.getTime() * 1000);
TraverseOptions options = origin.getOptions();
if (_graphService.getCalendarService() != null)
options.setCalendarService(_graphService.getCalendarService());
options.setTransferTable(_graphService.getGraph().getTransferTable());
options.setServiceDays(targetTime.getTime() / 1000);
if (options.getModes().getTransit()
&& !_graphService.getGraph().transitFeedCovers(targetTime)) {
// user wants a path through the transit network,
// but the date provided is outside those covered by the transit feed.
throw new TransitTimesException();
}
// decide which A* heuristic to use
options.remainingWeightHeuristic =
_remainingWeightHeuristicFactory.getInstanceForSearch(options, target);
LOG.debug("Applied A* heuristic: {}", options.remainingWeightHeuristic);
// If transit is not to be used, disable walk limit and only search for one itinerary.
if (!options.getModes().getTransit()) {
nItineraries = 1;
options.setMaxWalkDistance(Double.MAX_VALUE);
}
ArrayList<GraphPath> paths = new ArrayList<GraphPath>();
// The list of options specifying various modes, banned routes, etc to try for multiple
// itineraries
Queue<TraverseOptions> optionQueue = new LinkedList<TraverseOptions>();
optionQueue.add(options);
/* if the user wants to travel by transit, create a bus-only set of options */
if (options.getModes().getTrainish() && options.getModes().contains(TraverseMode.BUS)) {
TraverseOptions busOnly = options.clone();
busOnly.setModes(options.getModes().clone());
busOnly.getModes().setTrainish(false);
// Moved inside block to avoid double insertion in list ? (AMB)
// optionQueue.add(busOnly);
}
double maxWeight = Double.MAX_VALUE;
long maxTime = options.isArriveBy() ? 0 : Long.MAX_VALUE;
while (paths.size() < nItineraries) {
options = optionQueue.poll();
if (options == null) {
break;
}
StateEditor editor = new StateEditor(origin, null);
editor.setTraverseOptions(options);
origin = editor.makeState();
// options.worstTime = maxTime;
// options.maxWeight = maxWeight;
long searchBeginTime = System.currentTimeMillis();
LOG.debug("BEGIN SEARCH");
List<GraphPath> somePaths = _routingService.route(origin, target);
LOG.debug("END SEARCH {} msec", System.currentTimeMillis() - searchBeginTime);
if (maxWeight == Double.MAX_VALUE) {
/*
* the worst trip we are willing to accept is at most twice as bad or twice as long.
*/
if (somePaths.isEmpty()) {
// if there is no first path, there won't be any other paths
return null;
}
GraphPath path = somePaths.get(0);
long duration = path.getDuration();
LOG.debug("Setting max time and weight for subsequent searches.");
LOG.debug("First path start time: {}", path.getStartTime());
maxTime =
path.getStartTime() + MAX_TIME_FACTOR * (options.isArriveBy() ? -duration : duration);
LOG.debug("First path duration: {}", duration);
LOG.debug("Max time set to: {}", maxTime);
maxWeight = path.getWeight() * MAX_WEIGHT_FACTOR;
LOG.debug("Max weight set to: {}", maxWeight);
}
if (somePaths.isEmpty()) {
LOG.debug("NO PATHS FOUND");
continue;
}
for (GraphPath path : somePaths) {
if (!paths.contains(path)) {
// DEBUG
// path.dump();
paths.add(path);
// now, create a list of options, one with each trip in this journey banned.
LOG.debug("New trips: {}", path.getTrips());
TraverseOptions newOptions = options.clone();
for (AgencyAndId trip : path.getTrips()) {
newOptions.bannedTrips.add(trip);
}
if (!optionQueue.contains(newOptions)) {
optionQueue.add(newOptions);
}
/*
* // now, create a list of options, one with each route in this trip banned. //
* the HashSet banned is not strictly necessary as the optionsQueue will //
* already remove duplicate options, but it might be slightly faster as //
* hashing TraverseOptions is slow. LOG.debug("New routespecs: {}",
* path.getRouteSpecs()); for (RouteSpec spec : path.getRouteSpecs()) {
* TraverseOptions newOptions = options.clone();
* newOptions.bannedRoutes.add(spec); if (!optionQueue.contains(newOptions)) {
* optionQueue.add(newOptions); } }
*/
}
}
LOG.debug("{} / {} itineraries", paths.size(), nItineraries);
}
if (paths.size() == 0) {
return null;
}
// We order the list of returned paths by the time of arrival or departure (not path duration)
Collections.sort(paths, new PathComparator(origin.getOptions().isArriveBy()));
return paths;
}
