/* Needs Testing! */
public Drivelane[] getLanesLeadingFrom(Drivelane lane, int ruType) throws InfraException {
Road road = lane.getRoad();
// Road[] which will contain the Roads of this Node in a sorted fashion:
// [0] == the drivelanes on this Road will have to turn left to get to 'road', ..
Road[] srt_rarr = new Road[3];
if (allRoads[0] == road) {
srt_rarr[0] = allRoads[1]; // Must turn left
srt_rarr[1] = allRoads[2]; // Must go straight on
srt_rarr[2] = allRoads[3]; // Must turn right
} else if (allRoads[1] == road) {
srt_rarr[0] = allRoads[2];
srt_rarr[1] = allRoads[3];
srt_rarr[2] = allRoads[0];
} else if (allRoads[2] == road) {
srt_rarr[0] = allRoads[3];
srt_rarr[1] = allRoads[0];
srt_rarr[2] = allRoads[1];
} else {
srt_rarr[0] = allRoads[0];
srt_rarr[1] = allRoads[1];
srt_rarr[2] = allRoads[2];
}
// System.out.println("Junction getLanesLeadingFrom "+nodeId);
Vector v = new Vector();
Drivelane[] lanes;
int num_lanes;
int cnt_lanes = 0;
boolean[] targets = lane.getTargets();
for (int i = 0; i < 3; i++) {
if (srt_rarr[i] != null && targets[i] == true) {
// System.out.println("Road at target:"+i+" isnt null, getting Outboundlanes");
lanes = srt_rarr[i].getOutboundLanes(this);
num_lanes = lanes.length;
// System.out.println("Num lanes :"+num_lanes);
for (int j = 0; j < num_lanes; j++) {
Drivelane l = lanes[j];
// System.out.println("Lane"+j+" being checked now. Has type:"+l.getType());
if (l.mayUse(ruType)) {
v.addElement(l);
cnt_lanes++;
}
}
}
}
return (Drivelane[]) v.toArray(new Drivelane[cnt_lanes]);
}
public Drivelane[] getLanesLeadingTo(Drivelane lane, int ruType) throws InfraException {
Road road = lane.getRoad();
// Road[] which will contain the Roads of this Node in a sorted fashion:
// [0] == the drivelanes on this Road will have to turn left to get to 'road', ..
Road[] srt_rarr = new Road[3];
if (allRoads[0] == road) {
srt_rarr[0] = allRoads[3]; // Must turn left
srt_rarr[1] = allRoads[2]; // Must go straight on
srt_rarr[2] = allRoads[1]; // Must turn right
} else if (allRoads[1] == road) {
srt_rarr[0] = allRoads[0];
srt_rarr[1] = allRoads[3];
srt_rarr[2] = allRoads[2];
} else if (allRoads[2] == road) {
srt_rarr[0] = allRoads[1];
srt_rarr[1] = allRoads[0];
srt_rarr[2] = allRoads[3];
} else {
srt_rarr[0] = allRoads[2];
srt_rarr[1] = allRoads[1];
srt_rarr[2] = allRoads[0];
}
Vector v = new Vector();
Drivelane[] lanes;
int num_lanes;
int cnt_lanes = 0;
boolean[] targets;
for (int i = 0; i < 3; i++) {
if (srt_rarr[i] != null) {
lanes = srt_rarr[i].getInboundLanes(this);
num_lanes = lanes.length;
for (int j = 0; j < num_lanes; j++) {
Drivelane l = lanes[j];
targets = l.getTargets();
if (targets[i] == true && l.mayUse(ruType)) {
v.addElement(l);
cnt_lanes++;
}
}
}
}
return (Drivelane[]) v.toArray(new Drivelane[cnt_lanes]);
}
protected Target[] ownedTargets(Sign tl, int pos, Node des, boolean light) {
// This method will determine to which destinations you can go starting at this source
// represented in this QEntry
CountEntry dummy = new CountEntry(tl, pos, des, light, tl, pos);
Target[] ownedtargets;
Vector candidate_targets;
candidate_targets = new Vector();
// Use the count table to sort this out, we need all Targets from
// Only the elements in the count table are used, other just give a P
Enumeration _enum = count.elements();
while (_enum.hasMoreElements()) {
CountEntry current_entry = (CountEntry) _enum.nextElement();
if (current_entry.sameSource(dummy) != 0) {
candidate_targets.addElement(new Target(current_entry.tl_new, current_entry.pos_new));
}
}
ownedtargets = new Target[candidate_targets.size()];
candidate_targets.copyInto(ownedtargets);
return ownedtargets;
}
public void loadSecondStage(Dictionary dictionaries)
throws XMLInvalidInputException, XMLTreeException {
XMLUtils.loadSecondStage(count.elements(), dictionaries);
// XMLUtils.loadSecondStage(p_table.elements(),dictionaries);
System.out.println("SL1 second stage load finished.");
}
