bool
OptionsParser::processNonBooleanSingleSwitch(OptionsCont& oc, const char* arg) {
if (arg[1] == '=') {
if (strlen(arg) < 3) {
WRITE_ERROR("Missing value for parameter '" + std::string(arg).substr(0, 1) + "'.");
return false;
} else {
return oc.set(convert(arg[0]), std::string(arg + 2));
}
} else {
if (strlen(arg) < 2) {
WRITE_ERROR("Missing value for parameter '" + std::string(arg) + "'.");
return false;
} else {
return oc.set(convert(arg[0]), std::string(arg + 1));
}
}
}
void
NBNetBuilder::compute(OptionsCont& oc,
const std::set<std::string>& explicitTurnarounds,
bool removeElements) {
GeoConvHelper& geoConvHelper = GeoConvHelper::getProcessing();
const bool lefthand = oc.getBool("lefthand");
if (lefthand) {
mirrorX();
};
// MODIFYING THE SETS OF NODES AND EDGES
// Removes edges that are connecting the same node
long before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Removing self-loops");
myNodeCont.removeSelfLoops(myDistrictCont, myEdgeCont, myTLLCont);
PROGRESS_TIME_MESSAGE(before);
//
if (oc.exists("remove-edges.isolated") && oc.getBool("remove-edges.isolated")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Finding isolated roads");
myNodeCont.removeIsolatedRoads(myDistrictCont, myEdgeCont, myTLLCont);
PROGRESS_TIME_MESSAGE(before);
}
//
if (oc.exists("keep-edges.postload") && oc.getBool("keep-edges.postload")) {
if (oc.isSet("keep-edges.explicit") || oc.isSet("keep-edges.input-file")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Removing unwished edges");
myEdgeCont.removeUnwishedEdges(myDistrictCont);
PROGRESS_TIME_MESSAGE(before);
}
}
if (oc.getBool("junctions.join") || (oc.exists("ramps.guess") && oc.getBool("ramps.guess"))) {
// preliminary geometry computations to determine the length of edges
// This depends on turning directions and sorting of edge list
// in case junctions are joined geometry computations have to be repeated
// preliminary roundabout computations to avoid damaging roundabouts via junctions.join or ramps.guess
NBTurningDirectionsComputer::computeTurnDirections(myNodeCont, false);
NBNodesEdgesSorter::sortNodesEdges(myNodeCont);
myEdgeCont.computeLaneShapes();
myNodeCont.computeNodeShapes();
myEdgeCont.computeEdgeShapes();
if (oc.getBool("roundabouts.guess")) {
myEdgeCont.guessRoundabouts();
}
const std::set<EdgeSet>& roundabouts = myEdgeCont.getRoundabouts();
for (std::set<EdgeSet>::const_iterator it_round = roundabouts.begin();
it_round != roundabouts.end(); ++it_round) {
std::vector<std::string> nodeIDs;
for (EdgeSet::const_iterator it_edge = it_round->begin(); it_edge != it_round->end(); ++it_edge) {
nodeIDs.push_back((*it_edge)->getToNode()->getID());
}
myNodeCont.addJoinExclusion(nodeIDs);
}
}
// join junctions (may create new "geometry"-nodes so it needs to come before removing these
if (oc.exists("junctions.join-exclude") && oc.isSet("junctions.join-exclude")) {
myNodeCont.addJoinExclusion(oc.getStringVector("junctions.join-exclude"));
}
unsigned int numJoined = myNodeCont.joinLoadedClusters(myDistrictCont, myEdgeCont, myTLLCont);
if (oc.getBool("junctions.join")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Joining junction clusters");
numJoined += myNodeCont.joinJunctions(oc.getFloat("junctions.join-dist"), myDistrictCont, myEdgeCont, myTLLCont);
PROGRESS_TIME_MESSAGE(before);
}
if (oc.getBool("junctions.join") || (oc.exists("ramps.guess") && oc.getBool("ramps.guess"))) {
// reset geometry to avoid influencing subsequent steps (ramps.guess)
myEdgeCont.computeLaneShapes();
}
if (numJoined > 0) {
// bit of a misnomer since we're already done
WRITE_MESSAGE(" Joined " + toString(numJoined) + " junction cluster(s).");
}
//
if (removeElements) {
unsigned int no = 0;
const bool removeGeometryNodes = oc.exists("geometry.remove") && oc.getBool("geometry.remove");
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Removing empty nodes" + std::string(removeGeometryNodes ? " and geometry nodes" : ""));
// removeUnwishedNodes needs turnDirections. @todo: try to call this less often
NBTurningDirectionsComputer::computeTurnDirections(myNodeCont, false);
no = myNodeCont.removeUnwishedNodes(myDistrictCont, myEdgeCont, myTLLCont, removeGeometryNodes);
PROGRESS_TIME_MESSAGE(before);
WRITE_MESSAGE(" " + toString(no) + " nodes removed.");
}
// MOVE TO ORIGIN
// compute new boundary after network modifications have taken place
Boundary boundary;
for (std::map<std::string, NBNode*>::const_iterator it = myNodeCont.begin(); it != myNodeCont.end(); ++it) {
boundary.add(it->second->getPosition());
}
for (std::map<std::string, NBEdge*>::const_iterator it = myEdgeCont.begin(); it != myEdgeCont.end(); ++it) {
boundary.add(it->second->getGeometry().getBoxBoundary());
}
geoConvHelper.setConvBoundary(boundary);
if (!oc.getBool("offset.disable-normalization") && oc.isDefault("offset.x") && oc.isDefault("offset.y")) {
moveToOrigin(geoConvHelper, lefthand);
}
geoConvHelper.computeFinal(lefthand); // information needed for location element fixed at this point
if (oc.exists("geometry.min-dist") && oc.isSet("geometry.min-dist")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Reducing geometries");
myEdgeCont.reduceGeometries(oc.getFloat("geometry.min-dist"));
PROGRESS_TIME_MESSAGE(before);
}
// @note: removing geometry can create similar edges so joinSimilarEdges must come afterwards
// @note: likewise splitting can destroy similarities so joinSimilarEdges must come before
if (removeElements && oc.getBool("edges.join")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Joining similar edges");
myNodeCont.joinSimilarEdges(myDistrictCont, myEdgeCont, myTLLCont);
PROGRESS_TIME_MESSAGE(before);
}
if (oc.getBool("opposites.guess")) {
PROGRESS_BEGIN_MESSAGE("guessing opposite direction edges");
myEdgeCont.guessOpposites();
PROGRESS_DONE_MESSAGE();
}
//
if (oc.exists("geometry.split") && oc.getBool("geometry.split")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Splitting geometry edges");
myEdgeCont.splitGeometry(myNodeCont);
PROGRESS_TIME_MESSAGE(before);
}
// turning direction
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing turning directions");
NBTurningDirectionsComputer::computeTurnDirections(myNodeCont);
PROGRESS_TIME_MESSAGE(before);
// correct edge geometries to avoid overlap
myNodeCont.avoidOverlap();
// guess ramps
if ((oc.exists("ramps.guess") && oc.getBool("ramps.guess")) || (oc.exists("ramps.set") && oc.isSet("ramps.set"))) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Guessing and setting on-/off-ramps");
NBNodesEdgesSorter::sortNodesEdges(myNodeCont);
NBRampsComputer::computeRamps(*this, oc);
PROGRESS_TIME_MESSAGE(before);
}
// guess sidewalks
if (oc.getBool("sidewalks.guess") || oc.getBool("sidewalks.guess.from-permissions")) {
const int sidewalks = myEdgeCont.guessSidewalks(oc.getFloat("default.sidewalk-width"),
oc.getFloat("sidewalks.guess.min-speed"),
oc.getFloat("sidewalks.guess.max-speed"),
oc.getBool("sidewalks.guess.from-permissions"));
WRITE_MESSAGE("Guessed " + toString(sidewalks) + " sidewalks.");
}
// check whether any not previously setable connections may be set now
myEdgeCont.recheckPostProcessConnections();
// remap ids if wished
if (oc.getBool("numerical-ids")) {
int numChangedEdges = myEdgeCont.mapToNumericalIDs();
int numChangedNodes = myNodeCont.mapToNumericalIDs();
if (numChangedEdges + numChangedNodes > 0) {
WRITE_MESSAGE("Remapped " + toString(numChangedEdges) + " edge IDs and " + toString(numChangedNodes) + " node IDs.");
}
}
//
if (oc.exists("geometry.max-angle")) {
myEdgeCont.checkGeometries(
DEG2RAD(oc.getFloat("geometry.max-angle")),
oc.getFloat("geometry.min-radius"),
oc.getBool("geometry.min-radius.fix"));
}
// GEOMETRY COMPUTATION
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Sorting nodes' edges");
NBNodesEdgesSorter::sortNodesEdges(myNodeCont);
PROGRESS_TIME_MESSAGE(before);
myEdgeCont.computeLaneShapes();
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing node shapes");
if (oc.exists("geometry.junction-mismatch-threshold")) {
myNodeCont.computeNodeShapes(oc.getFloat("geometry.junction-mismatch-threshold"));
} else {
myNodeCont.computeNodeShapes();
}
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing edge shapes");
myEdgeCont.computeEdgeShapes();
PROGRESS_TIME_MESSAGE(before);
// resort edges based on the node and edge shapes
NBNodesEdgesSorter::sortNodesEdges(myNodeCont, true);
NBTurningDirectionsComputer::computeTurnDirections(myNodeCont, false);
// APPLY SPEED MODIFICATIONS
if (oc.exists("speed.offset")) {
const SUMOReal speedOffset = oc.getFloat("speed.offset");
const SUMOReal speedFactor = oc.getFloat("speed.factor");
if (speedOffset != 0 || speedFactor != 1 || oc.isSet("speed.minimum")) {
const SUMOReal speedMin = oc.isSet("speed.minimum") ? oc.getFloat("speed.minimum") : -std::numeric_limits<SUMOReal>::infinity();
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Applying speed modifications");
for (std::map<std::string, NBEdge*>::const_iterator i = myEdgeCont.begin(); i != myEdgeCont.end(); ++i) {
(*i).second->setSpeed(-1, MAX2((*i).second->getSpeed() * speedFactor + speedOffset, speedMin));
}
PROGRESS_TIME_MESSAGE(before);
}
}
// CONNECTIONS COMPUTATION
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing node types");
NBNodeTypeComputer::computeNodeTypes(myNodeCont);
PROGRESS_TIME_MESSAGE(before);
//
bool haveCrossings = false;
if (oc.getBool("crossings.guess")) {
haveCrossings = true;
int crossings = 0;
for (std::map<std::string, NBNode*>::const_iterator i = myNodeCont.begin(); i != myNodeCont.end(); ++i) {
crossings += (*i).second->guessCrossings();
}
WRITE_MESSAGE("Guessed " + toString(crossings) + " pedestrian crossings.");
}
if (!haveCrossings) {
// recheck whether we had crossings in the input
for (std::map<std::string, NBNode*>::const_iterator i = myNodeCont.begin(); i != myNodeCont.end(); ++i) {
if (i->second->getCrossings().size() > 0) {
haveCrossings = true;
break;
}
}
}
if (oc.isDefault("no-internal-links") && !haveCrossings && myHaveLoadedNetworkWithoutInternalEdges) {
oc.set("no-internal-links", "true");
}
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing priorities");
NBEdgePriorityComputer::computeEdgePriorities(myNodeCont);
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing approached edges");
myEdgeCont.computeEdge2Edges(oc.getBool("no-left-connections"));
PROGRESS_TIME_MESSAGE(before);
//
if (oc.getBool("roundabouts.guess")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Guessing and setting roundabouts");
const int numGuessed = myEdgeCont.guessRoundabouts();
if (numGuessed > 0) {
WRITE_MESSAGE(" Guessed " + toString(numGuessed) + " roundabout(s).");
}
PROGRESS_TIME_MESSAGE(before);
}
myEdgeCont.markRoundabouts();
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing approaching lanes");
myEdgeCont.computeLanes2Edges();
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Dividing of lanes on approached lanes");
myNodeCont.computeLanes2Lanes();
myEdgeCont.sortOutgoingLanesConnections();
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Processing turnarounds");
if (!oc.getBool("no-turnarounds")) {
myEdgeCont.appendTurnarounds(oc.getBool("no-turnarounds.tls"));
} else {
myEdgeCont.appendTurnarounds(explicitTurnarounds, oc.getBool("no-turnarounds.tls"));
}
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Rechecking of lane endings");
myEdgeCont.recheckLanes();
PROGRESS_TIME_MESSAGE(before);
if (haveCrossings && !oc.getBool("no-internal-links")) {
for (std::map<std::string, NBNode*>::const_iterator i = myNodeCont.begin(); i != myNodeCont.end(); ++i) {
i->second->buildCrossingsAndWalkingAreas();
}
}
// GUESS TLS POSITIONS
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Assigning nodes to traffic lights");
if (oc.isSet("tls.set")) {
std::vector<std::string> tlControlledNodes = oc.getStringVector("tls.set");
TrafficLightType type = SUMOXMLDefinitions::TrafficLightTypes.get(oc.getString("tls.default-type"));
for (std::vector<std::string>::const_iterator i = tlControlledNodes.begin(); i != tlControlledNodes.end(); ++i) {
NBNode* node = myNodeCont.retrieve(*i);
if (node == 0) {
WRITE_WARNING("Building a tl-logic for junction '" + *i + "' is not possible." + "\n The junction '" + *i + "' is not known.");
} else {
myNodeCont.setAsTLControlled(node, myTLLCont, type);
}
}
}
myNodeCont.guessTLs(oc, myTLLCont);
PROGRESS_TIME_MESSAGE(before);
//
if (oc.getBool("tls.join")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Joining traffic light nodes");
myNodeCont.joinTLS(myTLLCont, oc.getFloat("tls.join-dist"));
PROGRESS_TIME_MESSAGE(before);
}
// COMPUTING RIGHT-OF-WAY AND TRAFFIC LIGHT PROGRAMS
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing traffic light control information");
myTLLCont.setTLControllingInformation(myEdgeCont, myNodeCont);
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing node logics");
myNodeCont.computeLogics(myEdgeCont, oc);
PROGRESS_TIME_MESSAGE(before);
//
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Computing traffic light logics");
std::pair<unsigned int, unsigned int> numbers = myTLLCont.computeLogics(oc);
PROGRESS_TIME_MESSAGE(before);
std::string progCount = "";
if (numbers.first != numbers.second) {
progCount = "(" + toString(numbers.second) + " programs) ";
}
WRITE_MESSAGE(" " + toString(numbers.first) + " traffic light(s) " + progCount + "computed.");
//
if (oc.isSet("street-sign-output")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Generating street signs");
myEdgeCont.generateStreetSigns();
PROGRESS_TIME_MESSAGE(before);
}
// FINISHING INNER EDGES
if (!oc.getBool("no-internal-links")) {
before = SysUtils::getCurrentMillis();
PROGRESS_BEGIN_MESSAGE("Building inner edges");
for (std::map<std::string, NBEdge*>::const_iterator i = myEdgeCont.begin(); i != myEdgeCont.end(); ++i) {
(*i).second->sortOutgoingConnectionsByIndex();
}
// walking areas shall only be built if crossings are wished as well
for (std::map<std::string, NBNode*>::const_iterator i = myNodeCont.begin(); i != myNodeCont.end(); ++i) {
(*i).second->buildInnerEdges();
}
PROGRESS_TIME_MESSAGE(before);
}
if (lefthand) {
mirrorX();
};
// report
WRITE_MESSAGE("-----------------------------------------------------");
WRITE_MESSAGE("Summary:");
myNodeCont.printBuiltNodesStatistics();
WRITE_MESSAGE(" Network boundaries:");
WRITE_MESSAGE(" Original boundary : " + toString(geoConvHelper.getOrigBoundary()));
WRITE_MESSAGE(" Applied offset : " + toString(geoConvHelper.getOffsetBase()));
WRITE_MESSAGE(" Converted boundary : " + toString(geoConvHelper.getConvBoundary()));
WRITE_MESSAGE("-----------------------------------------------------");
NBRequest::reportWarnings();
// report on very large networks
if (MAX2(geoConvHelper.getConvBoundary().xmax(), geoConvHelper.getConvBoundary().ymax()) > 1000000 ||
MIN2(geoConvHelper.getConvBoundary().xmin(), geoConvHelper.getConvBoundary().ymin()) < -1000000) {
WRITE_WARNING("Network contains very large coordinates and will probably flicker in the GUI. Check for outlying nodes and make sure the network is shifted to the coordinate origin");
}
}
void
NIImporter_SUMO::_loadNetwork(OptionsCont& oc) {
// check whether the option is set (properly)
if (!oc.isUsableFileList("sumo-net-file")) {
return;
}
// parse file(s)
std::vector<std::string> files = oc.getStringVector("sumo-net-file");
for (std::vector<std::string>::const_iterator file = files.begin(); file != files.end(); ++file) {
if (!FileHelpers::isReadable(*file)) {
WRITE_ERROR("Could not open sumo-net-file '" + *file + "'.");
return;
}
setFileName(*file);
PROGRESS_BEGIN_MESSAGE("Parsing sumo-net from '" + *file + "'");
XMLSubSys::runParser(*this, *file, true);
PROGRESS_DONE_MESSAGE();
}
// build edges
for (std::map<std::string, EdgeAttrs*>::const_iterator i = myEdges.begin(); i != myEdges.end(); ++i) {
EdgeAttrs* ed = (*i).second;
// skip internal edges
if (ed->func == EDGEFUNC_INTERNAL || ed->func == EDGEFUNC_CROSSING || ed->func == EDGEFUNC_WALKINGAREA) {
continue;
}
// get and check the nodes
NBNode* from = myNodeCont.retrieve(ed->fromNode);
NBNode* to = myNodeCont.retrieve(ed->toNode);
if (from == 0) {
WRITE_ERROR("Edge's '" + ed->id + "' from-node '" + ed->fromNode + "' is not known.");
continue;
}
if (to == 0) {
WRITE_ERROR("Edge's '" + ed->id + "' to-node '" + ed->toNode + "' is not known.");
continue;
}
// edge shape
PositionVector geom;
if (ed->shape.size() > 0) {
geom = ed->shape;
} else {
// either the edge has default shape consisting only of the two node
// positions or we have a legacy network
geom = reconstructEdgeShape(ed, from->getPosition(), to->getPosition());
}
// build and insert the edge
NBEdge* e = new NBEdge(ed->id, from, to,
ed->type, ed->maxSpeed,
(unsigned int) ed->lanes.size(),
ed->priority, NBEdge::UNSPECIFIED_WIDTH, NBEdge::UNSPECIFIED_OFFSET,
geom, ed->streetName, "", ed->lsf, true); // always use tryIgnoreNodePositions to keep original shape
e->setLoadedLength(ed->length);
if (!myNetBuilder.getEdgeCont().insert(e)) {
WRITE_ERROR("Could not insert edge '" + ed->id + "'.");
delete e;
continue;
}
ed->builtEdge = myNetBuilder.getEdgeCont().retrieve(ed->id);
}
// assign further lane attributes (edges are built)
for (std::map<std::string, EdgeAttrs*>::const_iterator i = myEdges.begin(); i != myEdges.end(); ++i) {
EdgeAttrs* ed = (*i).second;
NBEdge* nbe = ed->builtEdge;
if (nbe == 0) { // inner edge or removed by explicit list, vclass, ...
continue;
}
for (unsigned int fromLaneIndex = 0; fromLaneIndex < (unsigned int) ed->lanes.size(); ++fromLaneIndex) {
LaneAttrs* lane = ed->lanes[fromLaneIndex];
// connections
const std::vector<Connection>& connections = lane->connections;
for (std::vector<Connection>::const_iterator c_it = connections.begin(); c_it != connections.end(); c_it++) {
const Connection& c = *c_it;
if (myEdges.count(c.toEdgeID) == 0) {
WRITE_ERROR("Unknown edge '" + c.toEdgeID + "' given in connection.");
continue;
}
NBEdge* toEdge = myEdges[c.toEdgeID]->builtEdge;
if (toEdge == 0) { // removed by explicit list, vclass, ...
continue;
}
if (nbe->hasConnectionTo(toEdge, c.toLaneIdx)) {
WRITE_WARNING("Target lane '" + toEdge->getLaneID(c.toLaneIdx) + "' has multiple connections from '" + nbe->getID() + "'.");
}
nbe->addLane2LaneConnection(
fromLaneIndex, toEdge, c.toLaneIdx, NBEdge::L2L_VALIDATED,
true, c.mayDefinitelyPass, c.keepClear, c.contPos);
// maybe we have a tls-controlled connection
if (c.tlID != "" && myRailSignals.count(c.tlID) == 0) {
const std::map<std::string, NBTrafficLightDefinition*>& programs = myTLLCont.getPrograms(c.tlID);
if (programs.size() > 0) {
std::map<std::string, NBTrafficLightDefinition*>::const_iterator it;
for (it = programs.begin(); it != programs.end(); it++) {
NBLoadedSUMOTLDef* tlDef = dynamic_cast<NBLoadedSUMOTLDef*>(it->second);
if (tlDef) {
tlDef->addConnection(nbe, toEdge, fromLaneIndex, c.toLaneIdx, c.tlLinkNo);
} else {
throw ProcessError("Corrupt traffic light definition '" + c.tlID + "' (program '" + it->first + "')");
}
}
} else {
WRITE_ERROR("The traffic light '" + c.tlID + "' is not known.");
}
}
}
// allow/disallow XXX preferred
nbe->setPermissions(parseVehicleClasses(lane->allow, lane->disallow), fromLaneIndex);
// width, offset
nbe->setLaneWidth(fromLaneIndex, lane->width);
nbe->setEndOffset(fromLaneIndex, lane->endOffset);
nbe->setSpeed(fromLaneIndex, lane->maxSpeed);
}
nbe->declareConnectionsAsLoaded();
if (!nbe->hasLaneSpecificWidth() && nbe->getLanes()[0].width != NBEdge::UNSPECIFIED_WIDTH) {
nbe->setLaneWidth(-1, nbe->getLaneWidth(0));
}
if (!nbe->hasLaneSpecificEndOffset() && nbe->getEndOffset(0) != NBEdge::UNSPECIFIED_OFFSET) {
nbe->setEndOffset(-1, nbe->getEndOffset(0));
}
}
// insert loaded prohibitions
for (std::vector<Prohibition>::const_iterator it = myProhibitions.begin(); it != myProhibitions.end(); it++) {
NBEdge* prohibitedFrom = myEdges[it->prohibitedFrom]->builtEdge;
NBEdge* prohibitedTo = myEdges[it->prohibitedTo]->builtEdge;
NBEdge* prohibitorFrom = myEdges[it->prohibitorFrom]->builtEdge;
NBEdge* prohibitorTo = myEdges[it->prohibitorTo]->builtEdge;
if (prohibitedFrom == 0) {
WRITE_WARNING("Edge '" + it->prohibitedFrom + "' in prohibition was not built");
} else if (prohibitedTo == 0) {
WRITE_WARNING("Edge '" + it->prohibitedTo + "' in prohibition was not built");
} else if (prohibitorFrom == 0) {
WRITE_WARNING("Edge '" + it->prohibitorFrom + "' in prohibition was not built");
} else if (prohibitorTo == 0) {
WRITE_WARNING("Edge '" + it->prohibitorTo + "' in prohibition was not built");
} else {
NBNode* n = prohibitedFrom->getToNode();
n->addSortedLinkFoes(
NBConnection(prohibitorFrom, prohibitorTo),
NBConnection(prohibitedFrom, prohibitedTo));
}
}
if (!myHaveSeenInternalEdge) {
myNetBuilder.haveLoadedNetworkWithoutInternalEdges();
}
if (oc.isDefault("lefthand")) {
oc.set("lefthand", toString(myAmLefthand));
}
if (oc.isDefault("junctions.corner-detail")) {
oc.set("junctions.corner-detail", toString(myCornerDetail));
}
if (oc.isDefault("junctions.internal-link-detail") && myLinkDetail > 0) {
oc.set("junctions.internal-link-detail", toString(myLinkDetail));
}
if (!deprecatedVehicleClassesSeen.empty()) {
WRITE_WARNING("Deprecated vehicle class(es) '" + toString(deprecatedVehicleClassesSeen) + "' in input network.");
deprecatedVehicleClassesSeen.clear();
}
// add loaded crossings
if (!oc.getBool("no-internal-links")) {
for (std::map<std::string, std::vector<Crossing> >::const_iterator it = myPedestrianCrossings.begin(); it != myPedestrianCrossings.end(); ++it) {
NBNode* node = myNodeCont.retrieve((*it).first);
for (std::vector<Crossing>::const_iterator it_c = (*it).second.begin(); it_c != (*it).second.end(); ++it_c) {
const Crossing& crossing = (*it_c);
EdgeVector edges;
for (std::vector<std::string>::const_iterator it_e = crossing.crossingEdges.begin(); it_e != crossing.crossingEdges.end(); ++it_e) {
NBEdge* edge = myNetBuilder.getEdgeCont().retrieve(*it_e);
// edge might have been removed due to options
if (edge != 0) {
edges.push_back(edge);
}
}
if (edges.size() > 0) {
node->addCrossing(edges, crossing.width, crossing.priority, true);
}
}
}
}
// add roundabouts
for (std::vector<std::vector<std::string> >::const_iterator it = myRoundabouts.begin(); it != myRoundabouts.end(); ++it) {
EdgeSet roundabout;
for (std::vector<std::string>::const_iterator it_r = it->begin(); it_r != it->end(); ++it_r) {
NBEdge* edge = myNetBuilder.getEdgeCont().retrieve(*it_r);
if (edge == 0) {
if (!myNetBuilder.getEdgeCont().wasIgnored(*it_r)) {
WRITE_ERROR("Unknown edge '" + (*it_r) + "' in roundabout");
}
} else {
roundabout.insert(edge);
}
}
myNetBuilder.getEdgeCont().addRoundabout(roundabout);
}
}
void
GNELoadThread::setDefaultOptions(OptionsCont& oc) {
oc.set("offset.disable-normalization", "true"); // preserve the given network as far as possible
oc.set("no-turnarounds", "true"); // otherwise it is impossible to manually removed turn-arounds
}
