void NWWriter_SUMO::writeEdge(OutputDevice& into, const NBEdge& e, bool noNames, bool origNames) { // write the edge's begin into.openTag(SUMO_TAG_EDGE).writeAttr(SUMO_ATTR_ID, e.getID()); into.writeAttr(SUMO_ATTR_FROM, e.getFromNode()->getID()); into.writeAttr(SUMO_ATTR_TO, e.getToNode()->getID()); if (!noNames && e.getStreetName() != "") { into.writeAttr(SUMO_ATTR_NAME, StringUtils::escapeXML(e.getStreetName())); } into.writeAttr(SUMO_ATTR_PRIORITY, e.getPriority()); if (e.getTypeID() != "") { into.writeAttr(SUMO_ATTR_TYPE, e.getTypeID()); } if (e.isMacroscopicConnector()) { into.writeAttr(SUMO_ATTR_FUNCTION, EDGEFUNC_CONNECTOR); } // write the spread type if not default ("right") if (e.getLaneSpreadFunction() != LANESPREAD_RIGHT) { into.writeAttr(SUMO_ATTR_SPREADTYPE, e.getLaneSpreadFunction()); } if (e.hasLoadedLength()) { into.writeAttr(SUMO_ATTR_LENGTH, e.getLoadedLength()); } if (!e.hasDefaultGeometry()) { into.writeAttr(SUMO_ATTR_SHAPE, e.getGeometry()); } // write the lanes const std::vector<NBEdge::Lane>& lanes = e.getLanes(); SUMOReal length = e.getLoadedLength(); if (OptionsCont::getOptions().getBool("no-internal-links") && !e.hasLoadedLength()) { // use length to junction center even if a modified geometry was given PositionVector geom = e.cutAtIntersection(e.getGeometry()); geom.push_back_noDoublePos(e.getToNode()->getCenter()); geom.push_front_noDoublePos(e.getFromNode()->getCenter()); length = geom.length(); } if (length <= 0) { length = POSITION_EPS; } for (unsigned int i = 0; i < (unsigned int) lanes.size(); i++) { const NBEdge::Lane& l = lanes[i]; writeLane(into, e.getID(), e.getLaneID(i), l.speed, l.permissions, l.preferred, l.endOffset, l.width, l.shape, l.origID, length, i, origNames); } // close the edge into.closeTag(); }
void NWWriter_SUMO::writeEdge(OutputDevice& into, const NBEdge& e, bool noNames, bool origNames) { // write the edge's begin into.openTag(SUMO_TAG_EDGE).writeAttr(SUMO_ATTR_ID, e.getID()); into.writeAttr(SUMO_ATTR_FROM, e.getFromNode()->getID()); into.writeAttr(SUMO_ATTR_TO, e.getToNode()->getID()); if (!noNames && e.getStreetName() != "") { into.writeAttr(SUMO_ATTR_NAME, StringUtils::escapeXML(e.getStreetName())); } into.writeAttr(SUMO_ATTR_PRIORITY, e.getPriority()); if (e.getTypeName() != "") { into.writeAttr(SUMO_ATTR_TYPE, e.getTypeName()); } if (e.isMacroscopicConnector()) { into.writeAttr(SUMO_ATTR_FUNCTION, EDGEFUNC_CONNECTOR); } // write the spread type if not default ("right") if (e.getLaneSpreadFunction() != LANESPREAD_RIGHT) { into.writeAttr(SUMO_ATTR_SPREADTYPE, e.getLaneSpreadFunction()); } if (e.hasLoadedLength()) { into.writeAttr(SUMO_ATTR_LENGTH, e.getLoadedLength()); } if (!e.hasDefaultGeometry()) { into.writeAttr(SUMO_ATTR_SHAPE, e.getGeometry()); } // write the lanes const std::vector<NBEdge::Lane>& lanes = e.getLanes(); SUMOReal length = e.getLoadedLength(); if (length <= 0) { length = (SUMOReal) .1; } for (unsigned int i = 0; i < (unsigned int) lanes.size(); i++) { writeLane(into, e.getID(), e.getLaneID(i), lanes[i], length, i, origNames); } // close the edge into.closeTag(); }
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 NWWriter_XML::writeEdgesAndConnections(const OptionsCont& oc, NBNodeCont& nc, NBEdgeCont& ec) { const GeoConvHelper& gch = GeoConvHelper::getFinal(); bool useGeo = oc.exists("proj.plain-geo") && oc.getBool("proj.plain-geo"); const bool geoAccuracy = useGeo || gch.usingInverseGeoProjection(); OutputDevice& edevice = OutputDevice::getDevice(oc.getString("plain-output-prefix") + ".edg.xml"); edevice.writeXMLHeader("edges", NWFrame::MAJOR_VERSION + " xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\" xsi:noNamespaceSchemaLocation=\"http://sumo-sim.org/xsd/edges_file.xsd\""); OutputDevice& cdevice = OutputDevice::getDevice(oc.getString("plain-output-prefix") + ".con.xml"); cdevice.writeXMLHeader("connections", NWFrame::MAJOR_VERSION + " xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\" xsi:noNamespaceSchemaLocation=\"http://sumo-sim.org/xsd/connections_file.xsd\""); bool noNames = !oc.getBool("output.street-names"); for (std::map<std::string, NBEdge*>::const_iterator i = ec.begin(); i != ec.end(); ++i) { // write the edge itself to the edges-files NBEdge* e = (*i).second; edevice.openTag(SUMO_TAG_EDGE); edevice.writeAttr(SUMO_ATTR_ID, e->getID()); edevice.writeAttr(SUMO_ATTR_FROM, e->getFromNode()->getID()); edevice.writeAttr(SUMO_ATTR_TO, e->getToNode()->getID()); if (!noNames && e->getStreetName() != "") { edevice.writeAttr(SUMO_ATTR_NAME, StringUtils::escapeXML(e->getStreetName())); } edevice.writeAttr(SUMO_ATTR_PRIORITY, e->getPriority()); // write the type if given if (e->getTypeID() != "") { edevice.writeAttr(SUMO_ATTR_TYPE, e->getTypeID()); } edevice.writeAttr(SUMO_ATTR_NUMLANES, e->getNumLanes()); if (!e->hasLaneSpecificSpeed()) { edevice.writeAttr(SUMO_ATTR_SPEED, e->getSpeed()); } // write non-default geometry if (!e->hasDefaultGeometry()) { PositionVector geom = e->getGeometry(); if (useGeo) { for (int i = 0; i < (int) geom.size(); i++) { gch.cartesian2geo(geom[i]); } } if (geoAccuracy) { edevice.setPrecision(GEO_OUTPUT_ACCURACY); } edevice.writeAttr(SUMO_ATTR_SHAPE, geom); if (geoAccuracy) { edevice.setPrecision(); } } // write the spread type if not default ("right") if (e->getLaneSpreadFunction() != LANESPREAD_RIGHT) { edevice.writeAttr(SUMO_ATTR_SPREADTYPE, toString(e->getLaneSpreadFunction())); } // write the length if it was specified if (e->hasLoadedLength()) { edevice.writeAttr(SUMO_ATTR_LENGTH, e->getLoadedLength()); } // some attributes can be set by edge default or per lane. Write as default if possible (efficiency) if (e->getLaneWidth() != NBEdge::UNSPECIFIED_WIDTH && !e->hasLaneSpecificWidth()) { edevice.writeAttr(SUMO_ATTR_WIDTH, e->getLaneWidth()); } if (e->getOffset() != NBEdge::UNSPECIFIED_OFFSET && !e->hasLaneSpecificOffset()) { edevice.writeAttr(SUMO_ATTR_OFFSET, e->getOffset()); } if (!e->needsLaneSpecificOutput()) { edevice.closeTag(); } else { for (unsigned int i = 0; i < e->getLanes().size(); ++i) { const NBEdge::Lane& lane = e->getLanes()[i]; edevice.openTag(SUMO_TAG_LANE); edevice.writeAttr(SUMO_ATTR_INDEX, i); // write allowed lanes NWWriter_SUMO::writePermissions(edevice, lane.permissions); NWWriter_SUMO::writePreferences(edevice, lane.preferred); // write other attributes if (lane.width != NBEdge::UNSPECIFIED_WIDTH && e->hasLaneSpecificWidth()) { edevice.writeAttr(SUMO_ATTR_WIDTH, lane.width); } if (lane.offset != NBEdge::UNSPECIFIED_OFFSET && e->hasLaneSpecificOffset()) { edevice.writeAttr(SUMO_ATTR_OFFSET, lane.offset); } if (e->hasLaneSpecificSpeed()) { edevice.writeAttr(SUMO_ATTR_SPEED, lane.speed); } edevice.closeTag(); } edevice.closeTag(); } // write this edge's connections to the connections-files e->sortOutgoingConnectionsByIndex(); const std::vector<NBEdge::Connection> connections = e->getConnections(); for (std::vector<NBEdge::Connection>::const_iterator c = connections.begin(); c != connections.end(); ++c) { NWWriter_SUMO::writeConnection(cdevice, *e, *c, false, NWWriter_SUMO::PLAIN); } if (connections.size() > 0) { cdevice << "\n"; } } // write loaded prohibitions to the connections-file for (std::map<std::string, NBNode*>::const_iterator i = nc.begin(); i != nc.end(); ++i) { NWWriter_SUMO::writeProhibitions(cdevice, i->second->getProhibitions()); } edevice.close(); cdevice.close(); }