Exemple #1
0
/**
 * loads the net
 * The net is in this meaning made up by the net itself and the dynamic
 * weights which may be supplied in a separate file
 */
void
initNet(RONet& net, ROLoader& loader,
        const std::vector<double>& turnDefs) {
    // load the net
    ROJTREdgeBuilder builder;
    loader.loadNet(net, builder);
    // set the turn defaults
    for (const auto& i : net.getEdgeMap()) {
        static_cast<ROJTREdge*>(i.second)->setTurnDefaults(turnDefs);
    }
}
Exemple #2
0
/**
 * loads the net
 * The net is in this meaning made up by the net itself and the dynamic
 * weights which may be supplied in a separate file
 */
void
initNet(RONet& net, ROLoader& loader,
        const std::vector<SUMOReal>& turnDefs) {
    // load the net
    ROJTREdgeBuilder builder;
    loader.loadNet(net, builder);
    // set the turn defaults
    const std::map<std::string, ROEdge*>& edges = net.getEdgeMap();
    for (std::map<std::string, ROEdge*>::const_iterator i = edges.begin(); i != edges.end(); ++i) {
        static_cast<ROJTREdge*>((*i).second)->setTurnDefaults(turnDefs);
    }
}
Exemple #3
0
/**
 * loads the net
 * The net is in this meaning made up by the net itself and the dynamic
 * weights which may be supplied in a separate file
 */
void
initNet(RONet &net, ROLoader &loader, OptionsCont &oc,
        const std::vector<SUMOReal> &turnDefs) {
    // load the net
    ROJTREdgeBuilder builder;
    loader.loadNet(net, builder);
    // set the turn defaults
    const std::map<std::string, ROEdge*> &edges = net.getEdgeMap();
    for (std::map<std::string, ROEdge*>::const_iterator i=edges.begin(); i!=edges.end(); ++i) {
        static_cast<ROJTREdge*>((*i).second)->setTurnDefaults(turnDefs);
    }
    // load the weights when wished/available
    if (oc.isSet("weights")) {
        loader.loadWeights(net, "weights", oc.getString("measure"), false);
    }
    if (oc.isSet("lane-weights")) {
        loader.loadWeights(net, "lane-weights", oc.getString("measure"), true);
    }
}
Exemple #4
0
bool
ROLoader::loadWeights(RONet& net, const std::string& optionName,
                      const std::string& measure, bool useLanes) {
    // check whether the file exists
    if (!myOptions.isUsableFileList(optionName)) {
        return false;
    }
    // build and prepare the weights handler
    std::vector<SAXWeightsHandler::ToRetrieveDefinition*> retrieverDefs;
    //  travel time, first (always used)
    EdgeFloatTimeLineRetriever_EdgeTravelTime ttRetriever(net);
    retrieverDefs.push_back(new SAXWeightsHandler::ToRetrieveDefinition("traveltime", !useLanes, ttRetriever));
    //  the measure to use, then
    EdgeFloatTimeLineRetriever_EdgeWeight eRetriever(net);
    if (measure != "traveltime") {
        std::string umeasure = measure;
        if (measure == "CO" || measure == "CO2" || measure == "HC" || measure == "PMx" || measure == "NOx" || measure == "fuel") {
            umeasure = measure + "_perVeh";
        }
        retrieverDefs.push_back(new SAXWeightsHandler::ToRetrieveDefinition(umeasure, !useLanes, eRetriever));
    }
    //  set up handler
    SAXWeightsHandler handler(retrieverDefs, "");
    // go through files
    std::vector<std::string> files = myOptions.getStringVector(optionName);
    for (std::vector<std::string>::const_iterator fileIt = files.begin(); fileIt != files.end(); ++fileIt) {
        PROGRESS_BEGIN_MESSAGE("Loading precomputed net weights from '" + *fileIt + "'");
        if (XMLSubSys::runParser(handler, *fileIt)) {
            PROGRESS_DONE_MESSAGE();
        } else {
            WRITE_MESSAGE("failed.");
            return false;
        }
    }
    // build edge-internal time lines
    const std::map<std::string, ROEdge*>& edges = net.getEdgeMap();
    for (std::map<std::string, ROEdge*>::const_iterator i = edges.begin(); i != edges.end(); ++i) {
        (*i).second->buildTimeLines(measure);
    }
    return true;
}