void
TraCIServerAPI_Simulation::writeStage(tcpip::Storage& outputStorage, const libsumo::TraCIStage& stage) {
    outputStorage.writeUnsignedByte(TYPE_COMPOUND);
    outputStorage.writeInt(6);
    outputStorage.writeUnsignedByte(TYPE_INTEGER);
    outputStorage.writeInt(stage.type);
    outputStorage.writeUnsignedByte(TYPE_STRING);
    outputStorage.writeString(stage.line);
    outputStorage.writeUnsignedByte(TYPE_STRING);
    outputStorage.writeString(stage.destStop);
    outputStorage.writeUnsignedByte(TYPE_STRINGLIST);
    outputStorage.writeStringList(stage.edges);
    outputStorage.writeUnsignedByte(TYPE_DOUBLE);
    outputStorage.writeDouble(stage.travelTime);
    outputStorage.writeUnsignedByte(TYPE_DOUBLE);
    outputStorage.writeDouble(stage.cost);
    outputStorage.writeUnsignedByte(TYPE_STRING);
    outputStorage.writeString(stage.intended);
    outputStorage.writeUnsignedByte(TYPE_DOUBLE);
    outputStorage.writeDouble(stage.depart);
}
Beispiel #2
0
bool
TraCIServerAPI_Simulation::commandDistanceRequest(TraCIServer& server, tcpip::Storage& inputStorage,
        tcpip::Storage& outputStorage, int commandId) {
    Position pos1;
    Position pos2;
    std::pair<const MSLane*, SUMOReal> roadPos1;
    std::pair<const MSLane*, SUMOReal> roadPos2;

    // read position 1
    int posType = inputStorage.readUnsignedByte();
    switch (posType) {
        case POSITION_ROADMAP:
            try {
                std::string roadID = inputStorage.readString();
                roadPos1.second = inputStorage.readDouble();
                roadPos1.first = getLaneChecking(roadID, inputStorage.readUnsignedByte(), roadPos1.second);
                pos1 = roadPos1.first->getShape().positionAtOffset(roadPos1.second);
            } catch (TraCIException& e) {
                server.writeStatusCmd(commandId, RTYPE_ERR, e.what());
                return false;
            }
            break;
        case POSITION_2D:
        case POSITION_3D: {
            SUMOReal p1x = inputStorage.readDouble();
            SUMOReal p1y = inputStorage.readDouble();
            pos1.set(p1x, p1y);
        }
        if (posType == POSITION_3D) {
            inputStorage.readDouble();		// z value is ignored
        }
        roadPos1 = convertCartesianToRoadMap(pos1);
        break;
        default:
            server.writeStatusCmd(commandId, RTYPE_ERR, "Unknown position format used for distance request");
            return false;
    }

    // read position 2
    posType = inputStorage.readUnsignedByte();
    switch (posType) {
        case POSITION_ROADMAP:
            try {
                std::string roadID = inputStorage.readString();
                roadPos2.second = inputStorage.readDouble();
                roadPos2.first = getLaneChecking(roadID, inputStorage.readUnsignedByte(), roadPos2.second);
                pos2 = roadPos2.first->getShape().positionAtOffset(roadPos2.second);
            } catch (TraCIException& e) {
                server.writeStatusCmd(commandId, RTYPE_ERR, e.what());
                return false;
            }
            break;
        case POSITION_2D:
        case POSITION_3D: {
            SUMOReal p2x = inputStorage.readDouble();
            SUMOReal p2y = inputStorage.readDouble();
            pos2.set(p2x, p2y);
        }
        if (posType == POSITION_3D) {
            inputStorage.readDouble();		// z value is ignored
        }
        roadPos2 = convertCartesianToRoadMap(pos2);
        break;
        default:
            server.writeStatusCmd(commandId, RTYPE_ERR, "Unknown position format used for distance request");
            return false;
    }

    // read distance type
    int distType = inputStorage.readUnsignedByte();

    SUMOReal distance = 0.0;
    if (distType == REQUEST_DRIVINGDIST) {
        // compute driving distance
        if ((roadPos1.first == roadPos2.first) && (roadPos1.second <= roadPos2.second)) {
            // same edge
            distance = roadPos2.second - roadPos1.second;
        } else {
            MSEdgeVector newRoute;
            MSNet::getInstance()->getRouterTT().compute(
                &roadPos1.first->getEdge(), &roadPos2.first->getEdge(), 0, MSNet::getInstance()->getCurrentTimeStep(), newRoute);
            MSRoute route("", newRoute, false, 0, std::vector<SUMOVehicleParameter::Stop>());
            distance = route.getDistanceBetween(roadPos1.second, roadPos2.second, &roadPos1.first->getEdge(), &roadPos2.first->getEdge());
        }
    } else {
        // compute air distance (default)
        distance = pos1.distanceTo(pos2);
    }
    // write response command
    outputStorage.writeUnsignedByte(TYPE_DOUBLE);
    outputStorage.writeDouble(distance);
    return true;
}
Beispiel #3
0
bool
TraCIServerAPI_Simulation::commandPositionConversion(TraCIServer& server, tcpip::Storage& inputStorage,
        tcpip::Storage& outputStorage, int commandId) {
    std::pair<MSLane*, SUMOReal> roadPos;
    Position cartesianPos;
    Position geoPos;
    SUMOReal z = 0;

    // actual position type that will be converted
    int srcPosType = inputStorage.readUnsignedByte();

    switch (srcPosType) {
        case POSITION_2D:
        case POSITION_3D:
        case POSITION_LON_LAT:
        case POSITION_LON_LAT_ALT: {
            SUMOReal x = inputStorage.readDouble();
            SUMOReal y = inputStorage.readDouble();
            if (srcPosType != POSITION_2D && srcPosType != POSITION_LON_LAT) {
                z = inputStorage.readDouble();
            }
            geoPos.set(x, y);
            cartesianPos.set(x, y);
            if (srcPosType == POSITION_LON_LAT || srcPosType == POSITION_LON_LAT_ALT) {
                GeoConvHelper::getFinal().x2cartesian_const(cartesianPos);
            } else {
                GeoConvHelper::getFinal().cartesian2geo(geoPos);
            }
        }
        break;
        case POSITION_ROADMAP: {
            std::string roadID = inputStorage.readString();
            SUMOReal pos = inputStorage.readDouble();
            int laneIdx = inputStorage.readUnsignedByte();
            try {
                // convert edge,offset,laneIdx to cartesian position
                cartesianPos = geoPos = getLaneChecking(roadID, laneIdx, pos)->getShape().positionAtOffset(pos);
                z = cartesianPos.z();
                GeoConvHelper::getFinal().cartesian2geo(geoPos);
            } catch (TraCIException& e) {
                server.writeStatusCmd(commandId, RTYPE_ERR, e.what());
                return false;
            }
        }
        break;
        default:
            server.writeStatusCmd(commandId, RTYPE_ERR, "Source position type not supported");
            return false;
    }

    int destPosType = 0;
    if (!server.readTypeCheckingUnsignedByte(inputStorage, destPosType)) {
        server.writeStatusCmd(commandId, RTYPE_ERR, "Destination position type must be of type ubyte.");
        return false;
    }

    switch (destPosType) {
        case POSITION_ROADMAP: {
            // convert cartesion position to edge,offset,lane_index
            roadPos = convertCartesianToRoadMap(cartesianPos);
            // write result that is added to response msg
            outputStorage.writeUnsignedByte(POSITION_ROADMAP);
            outputStorage.writeString(roadPos.first->getEdge().getID());
            outputStorage.writeDouble(roadPos.second);
            const std::vector<MSLane*> lanes = roadPos.first->getEdge().getLanes();
            outputStorage.writeUnsignedByte((int)distance(lanes.begin(), find(lanes.begin(), lanes.end(), roadPos.first)));
        }
        break;
        case POSITION_2D:
        case POSITION_3D:
        case POSITION_LON_LAT:
        case POSITION_LON_LAT_ALT:
            outputStorage.writeUnsignedByte(destPosType);
            if (destPosType == POSITION_LON_LAT || destPosType == POSITION_LON_LAT_ALT) {
                outputStorage.writeDouble(geoPos.x());
                outputStorage.writeDouble(geoPos.y());
            } else {
                outputStorage.writeDouble(cartesianPos.x());
                outputStorage.writeDouble(cartesianPos.y());
            }
            if (destPosType != POSITION_2D && destPosType != POSITION_LON_LAT) {
                outputStorage.writeDouble(z);
            }
            break;
        default:
            server.writeStatusCmd(commandId, RTYPE_ERR, "Destination position type not supported");
            return false;
    }
    return true;
}
bool
TraCIServerAPI_VehicleType::getVariable(const int variable, const MSVehicleType& v, tcpip::Storage& tempMsg) {
    switch (variable) {
        case VAR_LENGTH:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getLength());
            break;
        case VAR_MINGAP:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getMinGap());
            break;
        case VAR_MAXSPEED:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getMaxSpeed());
            break;
        case VAR_ACCEL:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getCarFollowModel().getMaxAccel());
            break;
        case VAR_DECEL:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getCarFollowModel().getMaxDecel());
            break;
        case VAR_IMPERFECTION:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getCarFollowModel().getImperfection());
            break;
        case VAR_TAU:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getCarFollowModel().getHeadwayTime());
            break;
        case VAR_SPEED_FACTOR:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getSpeedFactor());
            break;
        case VAR_SPEED_DEVIATION:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getSpeedDeviation());
            break;
        case VAR_VEHICLECLASS:
            tempMsg.writeUnsignedByte(TYPE_STRING);
            tempMsg.writeString(toString(v.getVehicleClass()));
            break;
        case VAR_EMISSIONCLASS:
            tempMsg.writeUnsignedByte(TYPE_STRING);
            tempMsg.writeString(getVehicleEmissionTypeName(v.getEmissionClass()));
            break;
        case VAR_SHAPECLASS:
            tempMsg.writeUnsignedByte(TYPE_STRING);
            tempMsg.writeString(getVehicleShapeName(v.getGuiShape()));
            break;
        case VAR_WIDTH:
            tempMsg.writeUnsignedByte(TYPE_DOUBLE);
            tempMsg.writeDouble(v.getGuiWidth());
            break;
        case VAR_COLOR:
            tempMsg.writeUnsignedByte(TYPE_COLOR);
            tempMsg.writeUnsignedByte(static_cast<int>(v.getColor().red() * 255. + 0.5));
            tempMsg.writeUnsignedByte(static_cast<int>(v.getColor().green() * 255. + 0.5));
            tempMsg.writeUnsignedByte(static_cast<int>(v.getColor().blue() * 255. + 0.5));
            tempMsg.writeUnsignedByte(255);
            break;
        default:
            break;
    }
    return true;
}