NBNode*
NBNodeCont::retrieve(const Position& position, SUMOReal offset) const {
    for (NodeCont::const_iterator i = myNodes.begin(); i != myNodes.end(); i++) {
        NBNode* node = (*i).second;
        if (fabs(node->getPosition().x() - position.x()) < offset
                &&
                fabs(node->getPosition().y() - position.y()) < offset) {
            return node;
        }
    }
    return 0;
}
bool
NIImporter_DlrNavteq::TrafficlightsHandler::report(const std::string& result) {
// #ID     POICOL-TYPE     DESCRIPTION     LONGITUDE       LATITUDE        NAVTEQ_LINK_ID  NODEID

    if (result[0] == '#') {
        return true;
    }
    StringTokenizer st(result, StringTokenizer::WHITECHARS);
    const std::string edgeID = st.get(5);
    NBEdge* edge = myEdgeCont.retrieve(edgeID);
    if (edge == nullptr) {
        WRITE_WARNING("The traffic light edge '" + edgeID + "' could not be found");
    } else {
        NBNode* node = edge->getToNode();
        if (node->getType() != NODETYPE_TRAFFIC_LIGHT) {
            node->reinit(node->getPosition(), NODETYPE_TRAFFIC_LIGHT);
            // @note. There may be additional information somewhere in the GDF files about traffic light type ...
            TrafficLightType type = SUMOXMLDefinitions::TrafficLightTypes.get(OptionsCont::getOptions().getString("tls.default-type"));
            // @note actually we could use the navteq node ID here
            NBTrafficLightDefinition* tlDef = new NBOwnTLDef(node->getID(), node, 0, type);
            if (!myTLLogicCont.insert(tlDef)) {
                // actually, nothing should fail here
                delete tlDef;
                throw ProcessError("Could not allocate tls for '" + node->getID() + "'.");
            }
        }
    }
    return true;
}
void
NWWriter_DlrNavteq::writeTrafficSignals(const OptionsCont& oc, NBNodeCont& nc) {
    OutputDevice& device = OutputDevice::getDevice(oc.getString("dlr-navteq-output") + "_traffic_signals.txt");
    writeHeader(device, oc);
    const GeoConvHelper& gch = GeoConvHelper::getFinal();
    const bool haveGeo = gch.usingGeoProjection();
    const SUMOReal geoScale = pow(10.0f, haveGeo ? 5 : 2); // see NIImporter_DlrNavteq::GEO_SCALE
    device.setPrecision(0);
    // write format specifier
    device << "#Traffic signal related to LINK_ID and NODE_ID with location relative to driving direction.\n#column format like pointcollection.\n#DESCRIPTION->LOCATION: 1-rechts von LINK; 2-links von LINK; 3-oberhalb LINK -1-keineAngabe\n#RELATREC_ID\tPOICOL_TYPE\tDESCRIPTION\tLONGITUDE\tLATITUDE\tLINK_ID\n";
    // write record for every edge incoming to a tls controlled node
    for (std::map<std::string, NBNode*>::const_iterator i = nc.begin(); i != nc.end(); ++i) {
        NBNode* n = (*i).second;
        if (n->isTLControlled()) {
            Position pos = n->getPosition();
            gch.cartesian2geo(pos);
            pos.mul(geoScale);
            const EdgeVector& incoming = n->getIncomingEdges();
            for (EdgeVector::const_iterator it = incoming.begin(); it != incoming.end(); ++it) {
                NBEdge* e = *it;
                device << e->getID() << "\t"
                       << "12\t" // POICOL_TYPE
                       << "LSA;NODEIDS#" << n->getID() << "#;LOCATION#-1#;\t"
                       << pos.x() << "\t"
                       << pos.y() << "\t"
                       << e->getID() << "\n";
            }
        }
    }
}
Exemple #4
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void
NWWriter_XML::writeNodes(const OptionsCont& oc, NBNodeCont& nc) {
    const GeoConvHelper& gch = GeoConvHelper::getFinal();
    bool useGeo = oc.exists("proj.plain-geo") && oc.getBool("proj.plain-geo");
    if (useGeo && !gch.usingGeoProjection()) {
        WRITE_WARNING("Ignoring option \"proj.plain-geo\" because no geo-conversion has been defined");
        useGeo = false;
    }
    const bool geoAccuracy = useGeo || gch.usingInverseGeoProjection();

    OutputDevice& device = OutputDevice::getDevice(oc.getString("plain-output-prefix") + ".nod.xml");
    device.writeXMLHeader("nodes", NWFrame::MAJOR_VERSION + " xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\" xsi:noNamespaceSchemaLocation=\"http://sumo-sim.org/xsd/nodes_file.xsd\"");

    // write network offsets and projection to allow reconstruction of original coordinates
    if (!useGeo) {
        NWWriter_SUMO::writeLocation(device);
    }

    // write nodes
    for (std::map<std::string, NBNode*>::const_iterator i = nc.begin(); i != nc.end(); ++i) {
        NBNode* n = (*i).second;
        device.openTag(SUMO_TAG_NODE);
        device.writeAttr(SUMO_ATTR_ID, n->getID());
        // write position
        Position pos = n->getPosition();
        if (useGeo) {
            gch.cartesian2geo(pos);
        }
        if (geoAccuracy) {
            device.setPrecision(GEO_OUTPUT_ACCURACY);
        }
        NWFrame::writePositionLong(pos, device);
        if (geoAccuracy) {
            device.setPrecision();
        }

        device.writeAttr(SUMO_ATTR_TYPE, toString(n->getType()));
        if (n->isTLControlled()) {
            const std::set<NBTrafficLightDefinition*>& tlss = n->getControllingTLS();
            // set may contain multiple programs for the same id.
            // make sure ids are unique and sorted
            std::set<std::string> tlsIDs;
            for (std::set<NBTrafficLightDefinition*>::const_iterator it_tl = tlss.begin(); it_tl != tlss.end(); it_tl++) {
                tlsIDs.insert((*it_tl)->getID());
            }
            std::vector<std::string> sortedIDs(tlsIDs.begin(), tlsIDs.end());
            sort(sortedIDs.begin(), sortedIDs.end());
            device.writeAttr(SUMO_ATTR_TLID, sortedIDs);
        }
        device.closeTag();
    }
    device.close();
}
void
NWWriter_SUMO::writeJunction(OutputDevice& into, const NBNode& n) {
    // write the attributes
    into.openTag(SUMO_TAG_JUNCTION).writeAttr(SUMO_ATTR_ID, n.getID());
    into.writeAttr(SUMO_ATTR_TYPE, n.getType());
    NWFrame::writePositionLong(n.getPosition(), into);
    // write the incoming lanes
    std::string incLanes;
    const std::vector<NBEdge*>& incoming = n.getIncomingEdges();
    for (std::vector<NBEdge*>::const_iterator i = incoming.begin(); i != incoming.end(); ++i) {
        unsigned int noLanes = (*i)->getNumLanes();
        for (unsigned int j = 0; j < noLanes; j++) {
            incLanes += (*i)->getLaneID(j);
            if (i != incoming.end() - 1 || j < noLanes - 1) {
                incLanes += ' ';
            }
        }
    }
    into.writeAttr(SUMO_ATTR_INCLANES, incLanes);
    // write the internal lanes
    std::string intLanes;
    if (!OptionsCont::getOptions().getBool("no-internal-links")) {
        unsigned int l = 0;
        for (EdgeVector::const_iterator i = incoming.begin(); i != incoming.end(); i++) {
            const std::vector<NBEdge::Connection>& elv = (*i)->getConnections();
            for (std::vector<NBEdge::Connection>::const_iterator k = elv.begin(); k != elv.end(); ++k) {
                if ((*k).toEdge == 0) {
                    continue;
                }
                if (l != 0) {
                    intLanes += ' ';
                }
                if (!(*k).haveVia) {
                    intLanes += (*k).id + "_0";
                } else {
                    intLanes += (*k).viaID + "_0";
                }
                l++;
            }
        }
    }
    into.writeAttr(SUMO_ATTR_INTLANES, intLanes);
    // close writing
    into.writeAttr(SUMO_ATTR_SHAPE, n.getShape());
    if (n.getType() == NODETYPE_DEAD_END) {
        into.closeTag();
    } else {
        // write right-of-way logics
        n.writeLogic(into);
        into.closeTag();
    }
}
void
NWWriter_DlrNavteq::writeNodesUnsplitted(const OptionsCont& oc, NBNodeCont& nc, NBEdgeCont& ec) {
    // For "real" nodes we simply use the node id.
    // For internal nodes (geometry vectors describing edge geometry in the parlance of this format)
    // we use the id of the edge and do not bother with
    // compression (each direction gets its own internal node).
    // XXX add option for generating numerical ids in case the input network has string ids and the target process needs integers
    OutputDevice& device = OutputDevice::getDevice(oc.getString("dlr-navteq-output") + "_nodes_unsplitted.txt");
    writeHeader(device, oc);
    const GeoConvHelper& gch = GeoConvHelper::getFinal();
    const bool haveGeo = gch.usingGeoProjection();
    const SUMOReal geoScale = pow(10.0f, haveGeo ? 5 : 2); // see NIImporter_DlrNavteq::GEO_SCALE
    device.setPrecision(0);
    if (!haveGeo) {
        WRITE_WARNING("DlrNavteq node data will be written in (floating point) cartesian coordinates");
    }
    // write format specifier
    device << "# NODE_ID\tIS_BETWEEN_NODE\tamount_of_geocoordinates\tx1\ty1\t[x2 y2  ... xn  yn]\n";
    // write normal nodes
    for (std::map<std::string, NBNode*>::const_iterator i = nc.begin(); i != nc.end(); ++i) {
        NBNode* n = (*i).second;
        Position pos = n->getPosition();
        gch.cartesian2geo(pos);
        pos.mul(geoScale);
        device << n->getID() << "\t0\t1\t" << pos.x() << "\t" << pos.y() << "\n";
    }
    // write "internal" nodes
    for (std::map<std::string, NBEdge*>::const_iterator i = ec.begin(); i != ec.end(); ++i) {
        NBEdge* e = (*i).second;
        const PositionVector& geom = e->getGeometry();
        if (geom.size() > 2) {
            std::string internalNodeID = e->getID();
            if (internalNodeID == UNDEFINED ||
                    (nc.retrieve(internalNodeID) != 0)) {
                // need to invent a new name to avoid clashing with the id of a 'real' node or a reserved name
                internalNodeID += "_geometry";
            }
            device << internalNodeID << "\t1\t" << geom.size() - 2;
            for (size_t ii = 1; ii < geom.size() - 1; ++ii) {
                Position pos = geom[(int)ii];
                gch.cartesian2geo(pos);
                pos.mul(geoScale);
                device << "\t" << pos.x() << "\t" << pos.y();
            }
            device << "\n";
        }
    }
    device.close();
}
void
NBNodeCont::discardTrafficLights(NBTrafficLightLogicCont& tlc, bool geometryLike) {
    for (NodeCont::const_iterator i = myNodes.begin(); i != myNodes.end(); ++i) {
        NBNode* node = i->second;
        if (!geometryLike || node->geometryLike()) {
            // make a copy of tldefs
            const std::set<NBTrafficLightDefinition*> tldefs = node->getControllingTLS();
            for (std::set<NBTrafficLightDefinition*>::const_iterator it = tldefs.begin(); it != tldefs.end(); ++it) {
                NBTrafficLightDefinition* tlDef = *it;
                node->removeTrafficLight(tlDef);
                tlc.extract(tlDef);
            }
            node->reinit(node->getPosition(), NODETYPE_UNKNOWN);
        }
    }
}
Exemple #8
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// ===========================================================================
// method definitions
// ===========================================================================
GNEJunction::GNEJunction(NBNode& nbn, GNENet* net, bool loaded) :
    GUIGlObject(GLO_JUNCTION, nbn.getID()),
    GNEAttributeCarrier(SUMO_TAG_JUNCTION),
    myNBNode(nbn),
    myOrigPos(nbn.getPosition()),
    myAmCreateEdgeSource(false),
    myNet(net),
    myLogicStatus(loaded ? LOADED : GUESSED),
    myAmResponsible(false),
    myHasValidLogic(loaded),
    myAmTLSSelected(false) {
    const double EXTENT = 2;
    myBoundary = Boundary(
                     myOrigPos.x() - EXTENT, myOrigPos.y() - EXTENT,
                     myOrigPos.x() + EXTENT, myOrigPos.y() + EXTENT);
    myMaxSize = 2 * EXTENT;
    rebuildCrossings(false);
}
Exemple #9
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void
NBNodeCont::discardTrafficLights(NBTrafficLightLogicCont& tlc, bool geometryLike, bool guessSignals) {
    for (NodeCont::const_iterator i = myNodes.begin(); i != myNodes.end(); ++i) {
        NBNode* node = i->second;
        if (!geometryLike || node->geometryLike()) {
            // make a copy of tldefs
            const std::set<NBTrafficLightDefinition*> tldefs = node->getControllingTLS();
            if (guessSignals && node->isTLControlled() && node->geometryLike()) {
                // record signal location
                const EdgeVector& outgoing = node->getOutgoingEdges();
                for (EdgeVector::const_iterator it_o = outgoing.begin(); it_o != outgoing.end(); ++it_o) {
                    (*it_o)->setSignalOffset((*it_o)->getLength());
                }
            }
            for (std::set<NBTrafficLightDefinition*>::const_iterator it = tldefs.begin(); it != tldefs.end(); ++it) {
                NBTrafficLightDefinition* tlDef = *it;
                node->removeTrafficLight(tlDef);
                tlc.extract(tlDef);
            }
            node->reinit(node->getPosition(), NODETYPE_UNKNOWN);
        }
    }
}
bool
NIImporter_DlrNavteq::EdgesHandler::report(const std::string& result) {
    // parse version number from first comment line and initialize column definitions
    if (result[0] == '#') {
        if (!myColumns.empty()) {
            return true;
        }
        const double version = readVersion(result, myFile);
        if (version > 0) {
            myVersion = version;
            // init columns
            const int NUM_COLUMNS = 25; // @note arrays must match this size!
            const int MC = MISSING_COLUMN;
            if (myVersion < 3) {
                const int columns[] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, MC, 12, 13, 14, 15, 16, 17, 18, 19, 20, MC, MC, -21};
                myColumns = std::vector<int>(columns, columns + NUM_COLUMNS);
            } else if (myVersion < 6) {
                const int columns[] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, MC, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, -23};
                myColumns = std::vector<int>(columns, columns + NUM_COLUMNS);
            } else {
                const int columns[] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24};
                myColumns = std::vector<int>(columns, columns + NUM_COLUMNS);
            }
        }
        return true;
    }
    if (myColumns.empty()) {
        throw ProcessError("Missing version string in file '" + myFile + "'.");
    }
    // interpret link attributes
    StringTokenizer st(result, StringTokenizer::WHITECHARS);
    const std::string id = getColumn(st, LINK_ID);
    // form of way (for priority and permissions)
    int form_of_way;
    try {
        form_of_way = StringUtils::toInt(getColumn(st, FORM_OF_WAY));
    } catch (NumberFormatException&) {
        throw ProcessError("Non-numerical value for form_of_way of link '" + id + "'.");
    }
    // brunnel type (bridge/tunnel/ferry (for permissions)
    int brunnel_type;
    try {
        brunnel_type = StringUtils::toInt(getColumn(st, BRUNNEL_TYPE));
    } catch (NumberFormatException&) {
        throw ProcessError("Non-numerical value for brunnel_type of link '" + id + "'.");
    }
    // priority based on street_type / frc
    int priority;
    try {
        priority = -StringUtils::toInt(getColumn(st, FUNCTIONAL_ROAD_CLASS));
        // lower priority using form_of_way
        if (form_of_way == 11) {
            priority -= 1; // frontage road, very often with lowered curb
        } else if (form_of_way > 11) {
            priority -= 2; // parking/service access assume lowered curb
        }
    } catch (NumberFormatException&) {
        throw ProcessError("Non-numerical value for street_type of link '" + id + "').");
    }
    // street name
    std::string streetName = getStreetNameFromIDs(
                                 getColumn(st, NAME_ID1_REGIONAL),
                                 getColumn(st, NAME_ID2_LOCAL));
    // try to get the nodes
    const std::string fromID = getColumn(st, NODE_ID_FROM);
    const std::string toID = getColumn(st, NODE_ID_TO);
    NBNode* from = myNodeCont.retrieve(fromID);
    NBNode* to = myNodeCont.retrieve(toID);
    if (from == nullptr) {
        throw ProcessError("The from-node '" + fromID + "' of link '" + id + "' could not be found");
    }
    if (to == nullptr) {
        throw ProcessError("The to-node '" + toID + "' of link '" + id + "' could not be found");
    }
    // speed
    double speed;
    try {
        speed = StringUtils::toInt(getColumn(st, SPEED_RESTRICTION, "-1")) / 3.6;
    } catch (NumberFormatException&) {
        throw ProcessError("Non-numerical value for the SPEED_RESTRICTION of link '" + id + "'.");
    }
    if (speed < 0) {
        // speed category as fallback
        speed = NINavTeqHelper::getSpeed(id, getColumn(st, SPEED_CATEGORY));
    }
    // number of lanes
    int numLanes;
    try {
        // EXTENDED_NUMBER_OF_LANES is prefered but may not be defined
        numLanes = StringUtils::toInt(getColumn(st, EXTENDED_NUMBER_OF_LANES, "-1"));
        if (numLanes == -1) {
            numLanes = NINavTeqHelper::getLaneNumber(id, getColumn(st, NUMBER_OF_LANES), speed);
        }
    } catch (NumberFormatException&) {
        throw ProcessError("Non-numerical value for the number of lanes of link '" + id + "'.");
    }

    const std::string navTeqTypeId = getColumn(st, VEHICLE_TYPE) + "_" + getColumn(st, FORM_OF_WAY);
    // build the edge
    NBEdge* e = nullptr;
    const std::string interID = getColumn(st, BETWEEN_NODE_ID);
    if (interID == "-1") {
        e = new NBEdge(id, from, to, myTypeCont.knows(navTeqTypeId) ? navTeqTypeId : "", speed, numLanes, priority,
                       NBEdge::UNSPECIFIED_WIDTH, NBEdge::UNSPECIFIED_OFFSET, streetName);
    } else {
        PositionVector geoms = myGeoms[interID];
        if (getColumn(st, CONNECTION, "0") == "1") {
            geoms = geoms.reverse();
        }
        geoms.insert(geoms.begin(), from->getPosition());
        geoms.push_back(to->getPosition());
        const std::string origID = OptionsCont::getOptions().getBool("output.original-names") ? id : "";
        e = new NBEdge(id, from, to, myTypeCont.knows(navTeqTypeId) ? navTeqTypeId : "", speed, numLanes, priority,
                       NBEdge::UNSPECIFIED_WIDTH, NBEdge::UNSPECIFIED_OFFSET, geoms, streetName, origID, LANESPREAD_CENTER);
    }

    // NavTeq imports can be done with a typemap (if supplied), if not, the old defaults are used
    if (myTypeCont.knows(navTeqTypeId)) {
        e->setPermissions(myTypeCont.getPermissions(navTeqTypeId));
    } else {
        // add vehicle type information to the edge
        if (myVersion < 6.0) {
            NINavTeqHelper::addVehicleClasses(*e, getColumn(st, VEHICLE_TYPE));
        } else {
            NINavTeqHelper::addVehicleClassesV6(*e, getColumn(st, VEHICLE_TYPE));
        }
        if (e->getPermissions() == SVCAll) {
            e->setPermissions(myTypeCont.getPermissions(""));
        }
        // permission modifications based on form_of_way
        if (form_of_way == 14) { // pedestrian area (fussgaengerzone)
            // unfortunately, the veh_type string is misleading in this case
            e->disallowVehicleClass(-1, SVC_PASSENGER);
        }
        // permission modifications based on brunnel_type
        if (brunnel_type == 10) { // ferry
            e->setPermissions(SVC_SHIP, -1);
        }
    }

    // insert the edge to the network
    if (!myEdgeCont.insert(e)) {
        delete e;
        throw ProcessError("Could not add edge '" + id + "'.");
    }
    return true;
}
void
NIImporter_SUMO::_loadNetwork(const 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::exists(*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);
        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 == toString(EDGEFUNC_INTERNAL)) {
            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;
            mySuspectKeepShape = false; // no problem with reconstruction if edge shape is given explicit
        } 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;
                }
                nbe->addLane2LaneConnection(
                    fromLaneIndex, toEdge, c.toLaneIdx, NBEdge::L2L_VALIDATED,
                    false, c.mayDefinitelyPass);

                // maybe we have a tls-controlled connection
                if (c.tlID != "") {
                    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
            SUMOVehicleClasses allowed;
            SUMOVehicleClasses disallowed;
            parseVehicleClasses(lane->allow, lane->disallow, allowed, disallowed);
            nbe->setVehicleClasses(allowed, disallowed, fromLaneIndex);
            // width, offset
            nbe->setWidth(fromLaneIndex, lane->width);
            nbe->setOffset(fromLaneIndex, lane->offset);
            nbe->setSpeed(fromLaneIndex, lane->maxSpeed);
        }
        nbe->declareConnectionsAsLoaded();
    }
    // insert loaded prohibitions
    for (std::vector<Prohibition>::const_iterator it = myProhibitions.begin(); it != myProhibitions.end(); it++) {
        NBEdge* prohibitedFrom = myEdges[it->prohibitedFrom]->builtEdge;
        if (prohibitedFrom == 0) {
            WRITE_ERROR("Edge '" + it->prohibitedFrom + "' in prohibition was not built");
        } else {
            NBNode* n = prohibitedFrom->getToNode();
            n->addSortedLinkFoes(
                NBConnection(myEdges[it->prohibitorFrom]->builtEdge, myEdges[it->prohibitorTo]->builtEdge),
                NBConnection(prohibitedFrom, myEdges[it->prohibitedTo]->builtEdge));
        }
    }

    // final warning
    if (mySuspectKeepShape) {
        WRITE_WARNING("The input network may have been built using option 'xml.keep-shape'.\n... Accuracy of junction positions cannot be guaranteed.");
    }

}
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);
    }
}
Exemple #13
0
void
NWWriter_SUMO::writeJunction(OutputDevice& into, const NBNode& n, const bool checkLaneFoes) {
    // write the attributes
    into.openTag(SUMO_TAG_JUNCTION).writeAttr(SUMO_ATTR_ID, n.getID());
    into.writeAttr(SUMO_ATTR_TYPE, n.getType());
    NWFrame::writePositionLong(n.getPosition(), into);
    // write the incoming lanes
    std::string incLanes;
    const std::vector<NBEdge*>& incoming = n.getIncomingEdges();
    for (std::vector<NBEdge*>::const_iterator i = incoming.begin(); i != incoming.end(); ++i) {
        unsigned int noLanes = (*i)->getNumLanes();
        for (unsigned int j = 0; j < noLanes; j++) {
            incLanes += (*i)->getLaneID(j);
            if (i != incoming.end() - 1 || j < noLanes - 1) {
                incLanes += ' ';
            }
        }
    }
    const std::vector<NBNode::Crossing>& crossings = n.getCrossings();
    for (std::vector<NBNode::Crossing>::const_iterator it = crossings.begin(); it != crossings.end(); it++) {
        incLanes += ' ' + (*it).prevWalkingArea + "_0";
    }
    into.writeAttr(SUMO_ATTR_INCLANES, incLanes);
    // write the internal lanes
    std::string intLanes;
    if (!OptionsCont::getOptions().getBool("no-internal-links")) {
        unsigned int l = 0;
        for (EdgeVector::const_iterator i = incoming.begin(); i != incoming.end(); i++) {
            const std::vector<NBEdge::Connection>& elv = (*i)->getConnections();
            for (std::vector<NBEdge::Connection>::const_iterator k = elv.begin(); k != elv.end(); ++k) {
                if ((*k).toEdge == 0) {
                    continue;
                }
                if (l != 0) {
                    intLanes += ' ';
                }
                if (!(*k).haveVia) {
                    intLanes += (*k).getInternalLaneID();
                } else {
                    intLanes += (*k).viaID + "_0";
                }
                l++;
            }
        }
    }
    if (n.getType() != NODETYPE_DEAD_END && n.getType() != NODETYPE_NOJUNCTION) {
        for (std::vector<NBNode::Crossing>::const_iterator it = crossings.begin(); it != crossings.end(); it++) {
            intLanes += ' ' + (*it).id + "_0";
        }
    }
    into.writeAttr(SUMO_ATTR_INTLANES, intLanes);
    // close writing
    into.writeAttr(SUMO_ATTR_SHAPE, n.getShape());
    // write optional radius
    if (n.getRadius() != NBNode::UNSPECIFIED_RADIUS) {
        into.writeAttr(SUMO_ATTR_RADIUS, n.getRadius());
    }
    // specify whether a custom shape was used
    if (n.hasCustomShape()) {
        into.writeAttr(SUMO_ATTR_CUSTOMSHAPE, true);
    }
    if (n.getType() == NODETYPE_DEAD_END) {
        into.closeTag();
    } else {
        // write right-of-way logics
        n.writeLogic(into, checkLaneFoes);
        into.closeTag();
    }
}
Exemple #14
0
void
NWWriter_DlrNavteq::writeNodesUnsplitted(const OptionsCont& oc, NBNodeCont& nc, NBEdgeCont& ec, std::map<NBEdge*, std::string>& internalNodes) {
    // For "real" nodes we simply use the node id.
    // For internal nodes (geometry vectors describing edge geometry in the parlance of this format)
    // we use the id of the edge and do not bother with
    // compression (each direction gets its own internal node).
    OutputDevice& device = OutputDevice::getDevice(oc.getString("dlr-navteq-output") + "_nodes_unsplitted.txt");
    writeHeader(device, oc);
    const GeoConvHelper& gch = GeoConvHelper::getFinal();
    const bool haveGeo = gch.usingGeoProjection();
    const double geoScale = pow(10.0f, haveGeo ? 5 : 2); // see NIImporter_DlrNavteq::GEO_SCALE
    device.setPrecision(oc.getInt("dlr-navteq.precision"));
    if (!haveGeo) {
        WRITE_WARNING("DlrNavteq node data will be written in (floating point) cartesian coordinates");
    }
    // write format specifier
    device << "# NODE_ID\tIS_BETWEEN_NODE\tamount_of_geocoordinates\tx1\ty1\t[x2 y2  ... xn  yn]\n";
    // write header
    Boundary boundary = gch.getConvBoundary();
    Position min(boundary.xmin(), boundary.ymin());
    Position max(boundary.xmax(), boundary.ymax());
    gch.cartesian2geo(min);
    min.mul(geoScale);
    gch.cartesian2geo(max);
    max.mul(geoScale);
    int multinodes = 0;
    for (std::map<std::string, NBEdge*>::const_iterator i = ec.begin(); i != ec.end(); ++i) {
        if ((*i).second->getGeometry().size() > 2) {
            multinodes++;
        }
    }
    device << "# [xmin_region] " << min.x() << "\n";
    device << "# [xmax_region] " << max.x() << "\n";
    device << "# [ymin_region] " << min.y() << "\n";
    device << "# [ymax_region] " << max.y() << "\n";
    device << "# [elements_multinode] " << multinodes << "\n";
    device << "# [elements_normalnode] " << nc.size() << "\n";
    device << "# [xmin] " << min.x() << "\n";
    device << "# [xmax] " << max.x() << "\n";
    device << "# [ymin] " << min.y() << "\n";
    device << "# [ymax] " << max.y() << "\n";
    // write normal nodes
    for (std::map<std::string, NBNode*>::const_iterator i = nc.begin(); i != nc.end(); ++i) {
        NBNode* n = (*i).second;
        Position pos = n->getPosition();
        gch.cartesian2geo(pos);
        pos.mul(geoScale);
        device << n->getID() << "\t0\t1\t" << pos.x() << "\t" << pos.y() << "\n";
    }
    // write "internal" nodes
    std::vector<std::string> avoid;
    std::set<std::string> reservedNodeIDs;
    const bool numericalIDs = oc.getBool("numerical-ids");
    if (oc.isSet("reserved-ids")) {
        NBHelpers::loadPrefixedIDsFomFile(oc.getString("reserved-ids"), "node:", reservedNodeIDs); // backward compatibility
        NBHelpers::loadPrefixedIDsFomFile(oc.getString("reserved-ids"), "junction:", reservedNodeIDs); // selection format
    }
    if (numericalIDs) {
        avoid = nc.getAllNames();
        std::vector<std::string> avoid2 = ec.getAllNames();
        avoid.insert(avoid.end(), avoid2.begin(), avoid2.end());
        avoid.insert(avoid.end(), reservedNodeIDs.begin(), reservedNodeIDs.end());
    }
    IDSupplier idSupplier("", avoid);
    for (std::map<std::string, NBEdge*>::const_iterator i = ec.begin(); i != ec.end(); ++i) {
        NBEdge* e = (*i).second;
        PositionVector geom = e->getGeometry();
        if (geom.size() > 2) {
            // the import NIImporter_DlrNavteq checks for the presence of a
            // negated edge id to determine spread type. We may need to do some
            // shifting to make this consistent
            const bool hasOppositeID = ec.getOppositeByID(e->getID()) != nullptr;
            if (e->getLaneSpreadFunction() == LANESPREAD_RIGHT && !hasOppositeID) {
                // need to write center-line geometry instead
                try {
                    geom.move2side(e->getTotalWidth() / 2);
                } catch (InvalidArgument& exception) {
                    WRITE_WARNING("Could not reconstruct shape for edge:'" + e->getID() + "' (" + exception.what() + ").");
                }
            } else if (e->getLaneSpreadFunction() == LANESPREAD_CENTER && hasOppositeID) {
                // need to write left-border geometry instead
                try {
                    geom.move2side(-e->getTotalWidth() / 2);
                } catch (InvalidArgument& exception) {
                    WRITE_WARNING("Could not reconstruct shape for edge:'" + e->getID() + "' (" + exception.what() + ").");
                }
            }

            std::string internalNodeID = e->getID();
            if (internalNodeID == UNDEFINED
                    || (nc.retrieve(internalNodeID) != nullptr)
                    || reservedNodeIDs.count(internalNodeID) > 0
               ) {
                // need to invent a new name to avoid clashing with the id of a 'real' node or a reserved name
                if (numericalIDs) {
                    internalNodeID = idSupplier.getNext();
                } else {
                    internalNodeID += "_geometry";
                }
            }
            internalNodes[e] = internalNodeID;
            device << internalNodeID << "\t1\t" << geom.size() - 2;
            for (int ii = 1; ii < (int)geom.size() - 1; ++ii) {
                Position pos = geom[(int)ii];
                gch.cartesian2geo(pos);
                pos.mul(geoScale);
                device << "\t" << pos.x() << "\t" << pos.y();
            }
            device << "\n";
        }
    }
    device.close();
}