/**
* Generate an itinerary from a @{link GraphPath}. The algorithm here is to walk over each state
* in the graph path, accumulating geometry, time, and length data from the incoming edge. When
* the incoming edge and outgoing edge have different modes (or when a vehicle changes names due
* to interlining) a new leg is generated. Street legs undergo an additional processing step to
* generate turn-by-turn directions.
*
* @param path
* @param showIntermediateStops whether intermediate stops are included in the generated itinerary
* @return itinerary
*/
private Itinerary generateItinerary(GraphPath path, boolean showIntermediateStops) {
Graph graph = path.getRoutingContext().graph;
TransitIndexService transitIndex = graph.getService(TransitIndexService.class);
Itinerary itinerary = makeEmptyItinerary(path);
EdgeNarrative postponedAlerts = null;
Leg leg = null;
CoordinateArrayListSequence coordinates = new CoordinateArrayListSequence();
double previousElevation = Double.MAX_VALUE;
int startWalk = -1;
int i = -1;
PlanGenState pgstate = PlanGenState.START;
String nextName = null;
for (State state : path.states) {
i += 1;
Edge backEdge = state.getBackEdge();
EdgeNarrative backEdgeNarrative = state.getBackEdgeNarrative();
if (backEdge == null) {
continue;
}
TraverseMode mode = backEdgeNarrative.getMode();
if (mode != null) {
long dt = state.getAbsTimeDeltaSec();
if (mode == TraverseMode.BOARDING
|| mode == TraverseMode.ALIGHTING
|| mode == TraverseMode.STL) {
itinerary.waitingTime += dt;
} else if (mode.isOnStreetNonTransit()) {
itinerary.walkDistance += backEdgeNarrative.getDistance();
itinerary.walkTime += dt;
} else if (mode.isTransit()) {
itinerary.transitTime += dt;
}
}
if (backEdge instanceof FreeEdge) {
if (backEdge instanceof PreBoardEdge) {
// Add boarding alerts to the next leg
postponedAlerts = backEdgeNarrative;
} else if (backEdge instanceof PreAlightEdge) {
// Add alighting alerts to the previous leg
addNotesToLeg(itinerary.legs.get(itinerary.legs.size() - 1), backEdgeNarrative);
}
continue;
}
if (backEdge instanceof EdgeWithElevation) {
PackedCoordinateSequence profile = ((EdgeWithElevation) backEdge).getElevationProfile();
previousElevation = applyElevation(profile, itinerary, previousElevation);
}
switch (pgstate) {
case START:
if (mode == TraverseMode.WALK) {
pgstate = PlanGenState.WALK;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = i;
} else if (mode == TraverseMode.BICYCLE) {
pgstate = PlanGenState.BICYCLE;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = i;
} else if (mode == TraverseMode.CAR) {
pgstate = PlanGenState.CAR;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = i;
} else if (mode == TraverseMode.BOARDING) {
// this itinerary starts with transit
pgstate = PlanGenState.PRETRANSIT;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = -1;
} else if (mode == TraverseMode.STL) {
// this comes after an alight; do nothing
} else if (mode == TraverseMode.TRANSFER) {
// handle the whole thing in one step
leg = makeLeg(itinerary, state);
coordinates = new CoordinateArrayListSequence();
coordinates.add(state.getBackState().getVertex().getCoordinate());
coordinates.add(state.getVertex().getCoordinate());
finalizeLeg(leg, state, path.states, i, i, coordinates);
coordinates.clear();
} else {
LOG.error("Unexpected state (in START): " + mode);
}
break;
case WALK:
if (leg == null) {
leg = makeLeg(itinerary, state);
}
if (mode == TraverseMode.WALK) {
// do nothing
} else if (mode == TraverseMode.BICYCLE) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates);
startWalk = i;
leg = makeLeg(itinerary, state);
if (backEdge instanceof RentABikeOnEdge) {
leg.rentedBike = true;
}
pgstate = PlanGenState.BICYCLE;
} else if (mode == TraverseMode.STL) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates);
leg = null;
pgstate = PlanGenState.PRETRANSIT;
} else if (mode == TraverseMode.BOARDING) {
// this only happens in case of a timed transfer.
pgstate = PlanGenState.PRETRANSIT;
finalizeLeg(leg, state, path.states, startWalk, i, coordinates);
leg = makeLeg(itinerary, state);
itinerary.transfers++;
} else if (backEdgeNarrative instanceof LegSwitchingEdge) {
nextName = state.getBackState().getBackState().getBackState().getVertex().getName();
finalizeLeg(leg, state, path.states, startWalk, i - 1, coordinates);
leg = null;
pgstate = PlanGenState.START;
} else {
LOG.error("Unexpected state (in WALK): " + mode);
}
break;
case BICYCLE:
if (leg == null) {
leg = makeLeg(itinerary, state);
}
if (mode == TraverseMode.BICYCLE) {
// do nothing
} else if (mode == TraverseMode.WALK) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates);
leg = makeLeg(itinerary, state);
startWalk = i;
pgstate = PlanGenState.WALK;
} else if (mode == TraverseMode.STL) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates);
leg = null;
pgstate = PlanGenState.PRETRANSIT;
} else if (backEdgeNarrative instanceof LegSwitchingEdge) {
finalizeLeg(leg, state, path.states, startWalk, i - 1, coordinates);
leg = null;
pgstate = PlanGenState.START;
} else {
LOG.error("Unexpected state (in BICYCLE): " + mode);
}
break;
case CAR:
if (leg == null) {
leg = makeLeg(itinerary, state);
}
if (mode == TraverseMode.CAR) {
// do nothing
} else if (mode == TraverseMode.STL) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates);
leg = null;
pgstate = PlanGenState.PRETRANSIT;
} else if (backEdgeNarrative instanceof LegSwitchingEdge) {
finalizeLeg(leg, state, path.states, startWalk, i - 1, coordinates);
leg = null;
pgstate = PlanGenState.START;
} else {
LOG.error("Unexpected state (in CAR): " + mode);
}
break;
case PRETRANSIT:
if (mode == TraverseMode.BOARDING) {
if (leg != null) {
LOG.error("leg unexpectedly not null (boarding loop)");
} else {
leg = makeLeg(itinerary, state);
leg.stop = new ArrayList<Place>();
itinerary.transfers++;
leg.boardRule = (String) state.getExtension("boardAlightRule");
}
} else if (backEdge instanceof HopEdge) {
pgstate = PlanGenState.TRANSIT;
fixupTransitLeg(leg, state, transitIndex);
leg.stop = new ArrayList<Place>();
} else {
LOG.error("Unexpected state (in PRETRANSIT): " + mode);
}
break;
case TRANSIT:
String route = backEdgeNarrative.getName();
if (mode == TraverseMode.ALIGHTING) {
if (showIntermediateStops && leg.stop != null && leg.stop.size() > 0) {
if (leg.stop.isEmpty()) {
leg.stop = null;
}
}
leg.alightRule = (String) state.getExtension("boardAlightRule");
finalizeLeg(leg, state, null, -1, -1, coordinates);
leg = null;
pgstate = PlanGenState.START;
} else if (mode.toString().equals(leg.mode)) {
// no mode change, handle intermediate stops
if (showIntermediateStops) {
/*
* any further transit edge, add "from" vertex to intermediate stops
*/
if (!(backEdge instanceof DwellEdge)) {
Place stop = makePlace(state.getBackState(), true);
leg.stop.add(stop);
} else if (leg.stop.size() > 0) {
leg.stop.get(leg.stop.size() - 1).departure = makeCalendar(state);
}
}
if (!route.equals(leg.route)) {
// interline dwell
finalizeLeg(leg, state, null, -1, -1, coordinates);
leg = makeLeg(itinerary, state);
leg.stop = new ArrayList<Place>();
fixupTransitLeg(leg, state, transitIndex);
leg.startTime = makeCalendar(state);
leg.interlineWithPreviousLeg = true;
}
} else {
LOG.error("Unexpected state (in TRANSIT): " + mode);
}
break;
}
if (leg != null) {
leg.distance += backEdgeNarrative.getDistance();
Geometry edgeGeometry = backEdgeNarrative.getGeometry();
if (edgeGeometry != null) {
Coordinate[] edgeCoordinates = edgeGeometry.getCoordinates();
if (coordinates.size() > 0
&& coordinates.getCoordinate(coordinates.size() - 1).equals(edgeCoordinates[0])) {
coordinates.extend(edgeCoordinates, 1);
} else {
coordinates.extend(edgeCoordinates);
}
}
if (postponedAlerts != null) {
addNotesToLeg(leg, postponedAlerts);
postponedAlerts = null;
}
addNotesToLeg(leg, backEdgeNarrative);
}
} /* end loop over graphPath edge list */
if (leg != null) {
finalizeLeg(leg, path.states.getLast(), path.states, startWalk, i, coordinates);
}
itinerary.removeBogusLegs();
itinerary.fixupDates(graph.getService(CalendarServiceData.class));
if (itinerary.legs.size() == 0) throw new TrivialPathException();
return itinerary;
}
/**
* Generate an itinerary from a @{link GraphPath}. The algorithm here is to walk over each state
* in the graph path, accumulating geometry, time, and length data from the incoming edge. When
* the incoming edge and outgoing edge have different modes (or when a vehicle changes names due
* to interlining) a new leg is generated. Street legs undergo an additional processing step to
* generate turn-by-turn directions.
*
* @param path
* @param showIntermediateStops whether intermediate stops are included in the generated itinerary
* @return itinerary
*/
private Itinerary generateItinerary(GraphPath path, boolean showIntermediateStops) {
Graph graph = path.getRoutingContext().graph;
TransitIndexService transitIndex = graph.getService(TransitIndexService.class);
Itinerary itinerary = makeEmptyItinerary(path);
Set<Alert> postponedAlerts = null;
Leg leg = null;
CoordinateArrayListSequence coordinates = new CoordinateArrayListSequence();
double previousElevation = Double.MAX_VALUE;
int startWalk = -1;
int i = -1;
boolean foldingElevatorLegIntoCycleLeg = false;
PlanGenState pgstate = PlanGenState.START;
String nextName = null;
for (State state : path.states) {
i += 1;
Edge backEdge = state.getBackEdge();
if (backEdge == null) {
continue;
}
// debug: push vehicle late status out to UI
// if (backEdge instanceof PatternHop) {
// TripTimes tt = state.getTripTimes();
// int hop = ((PatternHop)backEdge).stopIndex;
// LOG.info("{} {}", tt.getTrip().toString(), hop);
// if ( ! tt.isScheduled()) {
// int delay = tt.getDepartureDelay(hop);
// String d = "on time";
// if (Math.abs(delay) > 10) {
// d = String.format("%2.1f min %s", delay / 60.0,
// (delay < 0) ? "early" : "late");
// }
// d = "Using real-time delay information: ".concat(d);
// leg.addAlert(Alert.createSimpleAlerts(d));
// LOG.info(d);
// }
// else {
// leg.addAlert(Alert.createSimpleAlerts("Using published timetables."));
// LOG.info("sched");
// }
// }
TraverseMode mode = state.getBackMode();
if (mode != null) {
long dt = state.getAbsTimeDeltaSec();
if (mode == TraverseMode.BOARDING
|| mode == TraverseMode.ALIGHTING
|| mode == TraverseMode.STL) {
itinerary.waitingTime += dt;
} else if (mode.isOnStreetNonTransit()) {
itinerary.walkDistance += backEdge.getDistance();
itinerary.walkTime += dt;
} else if (mode.isTransit()) {
itinerary.transitTime += dt;
}
}
if (backEdge instanceof FreeEdge) {
if (backEdge instanceof PreBoardEdge) {
// Add boarding alerts to the next leg
postponedAlerts = state.getBackAlerts();
} else if (backEdge instanceof PreAlightEdge) {
// Add alighting alerts to the previous leg
addNotesToLeg(itinerary.legs.get(itinerary.legs.size() - 1), state.getBackAlerts());
}
continue;
}
if (backEdge instanceof EdgeWithElevation) {
PackedCoordinateSequence profile = ((EdgeWithElevation) backEdge).getElevationProfile();
previousElevation = applyElevation(profile, itinerary, previousElevation);
}
switch (pgstate) {
case START:
if (mode == TraverseMode.WALK) {
pgstate = PlanGenState.WALK;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = i;
} else if (mode == TraverseMode.BICYCLE) {
pgstate = PlanGenState.BICYCLE;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = i;
} else if (mode == TraverseMode.CAR) {
pgstate = PlanGenState.CAR;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
startWalk = i;
} else if (mode == TraverseMode.BOARDING) {
// this itinerary starts with transit
pgstate = PlanGenState.PRETRANSIT;
leg = makeLeg(itinerary, state);
leg.from.orig = nextName;
itinerary.transfers++;
startWalk = -1;
} else if (mode == TraverseMode.STL) {
// this comes after an alight; do nothing
} else if (mode == TraverseMode.TRANSFER) {
// handle the whole thing in one step
leg = makeLeg(itinerary, state);
coordinates = new CoordinateArrayListSequence();
coordinates.add(state.getBackState().getVertex().getCoordinate());
coordinates.add(state.getVertex().getCoordinate());
finalizeLeg(leg, state, path.states, i, i, coordinates, itinerary);
coordinates.clear();
} else {
LOG.error("Unexpected state (in START): " + mode);
}
break;
case WALK:
if (leg == null) {
leg = makeLeg(itinerary, state);
}
if (mode == TraverseMode.WALK) {
// do nothing
} else if (mode == TraverseMode.BICYCLE) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates, itinerary);
startWalk = i;
leg = makeLeg(itinerary, state);
pgstate = PlanGenState.BICYCLE;
} else if (mode == TraverseMode.STL) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates, itinerary);
leg = null;
pgstate = PlanGenState.PRETRANSIT;
} else if (mode == TraverseMode.BOARDING) {
// this only happens in case of a timed transfer.
pgstate = PlanGenState.PRETRANSIT;
finalizeLeg(leg, state, path.states, startWalk, i, coordinates, itinerary);
leg = makeLeg(itinerary, state);
itinerary.transfers++;
} else if (backEdge instanceof LegSwitchingEdge) {
nextName = state.getBackState().getBackState().getBackState().getVertex().getName();
finalizeLeg(leg, state, path.states, startWalk, i - 1, coordinates, itinerary);
leg = null;
pgstate = PlanGenState.START;
} else {
LOG.error("Unexpected state (in WALK): " + mode);
}
break;
case BICYCLE:
if (leg == null) {
leg = makeLeg(itinerary, state);
}
// If there are elevator edges that have mode == BICYCLE on both sides, they should
// be folded into the bicycle leg. But ones with walk on one side or the other should
// not
if (state.getBackEdge() instanceof ElevatorBoardEdge) {
int j = i + 1;
// proceed forward from the current state until we find one that isn't on an
// elevator, and check the traverse mode
while (path.states.get(j).getBackEdge() instanceof ElevatorEdge) j++;
// path.states[j] is not an elevator edge
if (path.states.get(j).getBackMode() == TraverseMode.BICYCLE)
foldingElevatorLegIntoCycleLeg = true;
}
if (foldingElevatorLegIntoCycleLeg) {
if (state.getBackEdge() instanceof ElevatorEdge) {
break; // from the case
} else {
foldingElevatorLegIntoCycleLeg = false;
// do not break but allow it to be processed below (which will do nothing)
}
}
if (mode == TraverseMode.BICYCLE) {
// do nothing
} else if (mode == TraverseMode.WALK) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates, itinerary);
leg = makeLeg(itinerary, state);
startWalk = i;
pgstate = PlanGenState.WALK;
} else if (mode == TraverseMode.STL) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates, itinerary);
startWalk = i;
leg = null;
pgstate = PlanGenState.PRETRANSIT;
} else if (backEdge instanceof LegSwitchingEdge) {
finalizeLeg(leg, state, path.states, startWalk, i - 1, coordinates, itinerary);
leg = null;
pgstate = PlanGenState.START;
} else {
LOG.error("Unexpected state (in BICYCLE): " + mode);
}
break;
case CAR:
if (leg == null) {
leg = makeLeg(itinerary, state);
}
if (mode == TraverseMode.CAR) {
// do nothing
} else if (mode == TraverseMode.STL) {
finalizeLeg(leg, state, path.states, startWalk, i, coordinates, itinerary);
leg = null;
pgstate = PlanGenState.PRETRANSIT;
} else if (backEdge instanceof LegSwitchingEdge) {
finalizeLeg(leg, state, path.states, startWalk, i - 1, coordinates, itinerary);
leg = null;
pgstate = PlanGenState.START;
} else {
LOG.error("Unexpected state (in CAR): " + mode);
}
break;
case PRETRANSIT:
if (mode == TraverseMode.BOARDING) {
if (leg != null) {
LOG.error("leg unexpectedly not null (boarding loop)");
} else {
leg = makeLeg(itinerary, state);
leg.from.stopIndex = ((OnBoardForwardEdge) backEdge).getStopIndex();
leg.stop = new ArrayList<Place>();
itinerary.transfers++;
leg.boardRule = (String) state.getExtension("boardAlightRule");
}
} else if (backEdge instanceof HopEdge) {
pgstate = PlanGenState.TRANSIT;
fixupTransitLeg(leg, state, transitIndex);
leg.stop = new ArrayList<Place>();
} else {
LOG.error("Unexpected state (in PRETRANSIT): " + mode);
}
break;
case TRANSIT:
String route = backEdge.getName();
if (mode == TraverseMode.ALIGHTING) {
if (showIntermediateStops && leg.stop != null && leg.stop.size() > 0) {
if (leg.stop.isEmpty()) {
leg.stop = null;
}
}
leg.alightRule = (String) state.getExtension("boardAlightRule");
finalizeLeg(leg, state, null, -1, -1, coordinates, itinerary);
leg = null;
pgstate = PlanGenState.START;
} else if (mode.toString().equals(leg.mode)) {
// no mode change, handle intermediate stops
if (showIntermediateStops) {
/*
* any further transit edge, add "from" vertex to intermediate stops
*/
if (!(backEdge instanceof DwellEdge)) {
Place stop =
makePlace(
state.getBackState(), state.getBackState().getVertex().getName(), true);
leg.stop.add(stop);
} else if (leg.stop.size() > 0) {
leg.stop.get(leg.stop.size() - 1).departure = makeCalendar(state);
}
}
if (!route.equals(leg.route)) {
// interline dwell
finalizeLeg(leg, state, null, -1, -1, coordinates, itinerary);
leg = makeLeg(itinerary, state);
leg.stop = new ArrayList<Place>();
fixupTransitLeg(leg, state, transitIndex);
leg.startTime = makeCalendar(state);
leg.interlineWithPreviousLeg = true;
}
} else {
LOG.error("Unexpected state (in TRANSIT): " + mode);
}
break;
}
if (leg != null) {
leg.distance += backEdge.getDistance();
Geometry edgeGeometry = backEdge.getGeometry();
if (edgeGeometry != null) {
Coordinate[] edgeCoordinates = edgeGeometry.getCoordinates();
if (coordinates.size() > 0
&& coordinates.getCoordinate(coordinates.size() - 1).equals(edgeCoordinates[0])) {
coordinates.extend(edgeCoordinates, 1);
} else {
coordinates.extend(edgeCoordinates);
}
}
if (postponedAlerts != null) {
addNotesToLeg(leg, postponedAlerts);
postponedAlerts = null;
}
addNotesToLeg(leg, state.getBackAlerts());
}
} /* end loop over graphPath edge list */
if (leg != null) {
finalizeLeg(leg, path.states.getLast(), path.states, startWalk, i, coordinates, itinerary);
}
itinerary.removeBogusLegs();
itinerary.fixupDates(graph.getService(CalendarServiceData.class));
if (itinerary.legs.size() == 0) throw new TrivialPathException();
return itinerary;
}