void applySetupCallback::execute (XmlRpc::XmlRpcValue& params, XmlRpc::XmlRpcValue& result)
{

    if(params.valid()) {

        if(params.size() != 1) {
            result = -1;
            return;
        }

        XmlRpc::XmlRpcValue p = params[0];
        if(p.size() % 2 != 0) {
            result = -1;
            fflush(stdout);
            return;
        }

        for(int i=0; i<p.size(); i+= 2) {
            if(0 > ctrl_xmlrpc->addModule(p[i], p[i+1])) {
                result = i+1;
                fflush(stdout);
                return;
            }
        }
    }
    result = 0;
    fflush(stdout);

    return;
}
void Costmap2DROS::readFootprintFromXMLRPC( XmlRpc::XmlRpcValue& footprint_xmlrpc,
                                            const std::string& full_param_name )
{
  // Make sure we have an array of at least 3 elements.
  if( footprint_xmlrpc.getType() != XmlRpc::XmlRpcValue::TypeArray ||
      footprint_xmlrpc.size() < 3 )
  {
    ROS_FATAL( "The footprint must be specified as list of lists on the parameter server, %s was specified as %s",
               full_param_name.c_str(), std::string( footprint_xmlrpc ).c_str() );
    throw std::runtime_error( "The footprint must be specified as list of lists on the parameter server with at least 3 points eg: [[x1, y1], [x2, y2], ..., [xn, yn]]");
  }

  std::vector<geometry_msgs::Point> footprint;  
  geometry_msgs::Point pt;

  for( int i = 0; i < footprint_xmlrpc.size(); ++i )
  {
    // Make sure each element of the list is an array of size 2. (x and y coordinates)
    XmlRpc::XmlRpcValue point = footprint_xmlrpc[ i ];
    if( point.getType() != XmlRpc::XmlRpcValue::TypeArray ||
        point.size() != 2 )
    {
      ROS_FATAL( "The footprint (parameter %s) must be specified as list of lists on the parameter server eg: [[x1, y1], [x2, y2], ..., [xn, yn]], but this spec is not of that form.",
                 full_param_name.c_str() );
      throw std::runtime_error( "The footprint must be specified as list of lists on the parameter server eg: [[x1, y1], [x2, y2], ..., [xn, yn]], but this spec is not of that form" );
    }
       
    pt.x = getNumberFromXMLRPC( point[ 0 ], full_param_name );
    pt.y = getNumberFromXMLRPC( point[ 1 ], full_param_name );
       
    footprint.push_back( pt );
  }

  setUnpaddedRobotFootprint( footprint );
}
  void NavSatTransform::run()
  {
    ros::Time::init();

    double frequency = 10.0;
    double delay = 0.0;

    ros::NodeHandle nh;
    ros::NodeHandle nhPriv("~");

    // Load the parameters we need
    nhPriv.getParam("magnetic_declination_radians", magneticDeclination_);
    nhPriv.param("yaw_offset", yawOffset_, 0.0);
    nhPriv.param("broadcast_utm_transform", broadcastUtmTransform_, false);
    nhPriv.param("zero_altitude", zeroAltitude_, false);
    nhPriv.param("publish_filtered_gps", publishGps_, false);
    nhPriv.param("use_odometry_yaw", useOdometryYaw_, false);
    nhPriv.param("wait_for_datum", useManualDatum_, false);
    nhPriv.param("frequency", frequency, 10.0);
    nhPriv.param("delay", delay, 0.0);

    // Subscribe to the messages and services we need
    ros::ServiceServer datumServ = nh.advertiseService("datum", &NavSatTransform::datumCallback, this);

    if (useManualDatum_ && nhPriv.hasParam("datum"))
    {
      XmlRpc::XmlRpcValue datumConfig;

      try
      {
        double datumLat;
        double datumLon;
        double datumYaw;

        nhPriv.getParam("datum", datumConfig);

        // Handle datum specification. Users should always specify a baseLinkFrameId_ in the
        // datum config, but we had a release where it wasn't used, so we'll maintain compatibility.
        ROS_ASSERT(datumConfig.getType() == XmlRpc::XmlRpcValue::TypeArray);
        ROS_ASSERT(datumConfig.size() == 4 || datumConfig.size() == 5);

        useManualDatum_ = true;

        std::ostringstream ostr;
        if (datumConfig.size() == 4)
        {
          ROS_WARN_STREAM("No base_link_frame specified for the datum (parameter 5).");
          ostr << datumConfig[0] << " " << datumConfig[1] << " " << datumConfig[2] << " " << datumConfig[3];
          std::istringstream istr(ostr.str());
          istr >> datumLat >> datumLon >> datumYaw >> worldFrameId_;
        }
        else if (datumConfig.size() == 5)
        {
          ostr << datumConfig[0] << " " << datumConfig[1] << " " << datumConfig[2] <<
                  " " << datumConfig[3] << " " << datumConfig[4];
          std::istringstream istr(ostr.str());
          istr >> datumLat >> datumLon >> datumYaw >> worldFrameId_ >> baseLinkFrameId_;
        }
int main(int argc, char* argv[])
{
    std::vector<ros::Subscriber> subs;

    ros::init(argc, argv, "Navi2");
    ros::NodeHandle nh;
    
    XmlRpc::XmlRpcValue topicList;
    ros::param::get("~inputTopics", topicList);
    
    ROS_ASSERT(topicList.size() > 0);
    ROS_ASSERT(topicList.getType() == XmlRpc::XmlRpcValue::TypeArray);
    
    
    for (int i = 0; i < topicList.size(); ++i) 
    {
        ROS_ASSERT(topicList[i].getType() == XmlRpc::XmlRpcValue::TypeString);
        std::string topic = static_cast<std::string>(topicList[i]);
        
        maps.push_back(nav_msgs::OccupancyGrid());
        flags.push_back(0);
        
        subs.push_back(nh.subscribe<nav_msgs::OccupancyGrid>(topic, 1, boost::bind(mapCallback, _1, i)));
    }
    
    ros::Publisher mapPub = nh.advertise<nav_msgs::OccupancyGrid>("output", 1);
    ros::Rate rate(20);
    
    while (ros::ok())
    {
        rate.sleep();
        ros::spinOnce();
        
        //Everyone ready?
        if ((unsigned int)std::count(flags.begin(), flags.end(), 1) == flags.size())
        {
            //merge
            nav_msgs::OccupancyGrid map;
            
            map.info = maps.front().info;
            
            for (unsigned int i = 0; i < map.info.height * map.info.width; ++i)
            {
                map.data.push_back(-1);
                
                for (std::vector<nav_msgs::OccupancyGrid>::iterator j = maps.begin(); j != maps.end(); ++j)
                {
                    map.data[i] = std::max(map.data[i], j->data[i]);
                }
            }
            
            mapPub.publish(map);
            
            //Make not ready
            std::fill(flags.begin(), flags.end(), 0);
        }
    }
}
void PoseTracker::parseParameters(const XmlRpc::XmlRpcValue &leds)
{
	ROS_ASSERT(leds.getType() == XmlRpc::XmlRpcValue::TypeArray);

	// if parameters is good, resize the matrix to account for number of leds used to track 
	// 4 =  id + 3Dposition
	local_points_=Eigen::MatrixXd::Zero(leds.size(),4);
	Nleds_ = leds.size();

	for( int i = 0; i < Nleds_; ++i)
	{
		XmlRpc::XmlRpcValue current_led = leds[i];

		// parse ID
		ROS_ASSERT(current_led.getType() == XmlRpc::XmlRpcValue::TypeStruct);
    		if( current_led.hasMember("id") )
    		{
    			ROS_ASSERT(current_led["id"].getType() == XmlRpc::XmlRpcValue::TypeInt);
    			int id = current_led["id"];
    			local_points_(i, 0) = (double) id;
    		}
    		else
    		{
    			ROS_ERROR("No id value for the current led. Check the yaml configuration for this object");
    			return;
    		}

	    	// parse position
	    	std::vector<double> position;
	    	if( current_led.hasMember("position") )
	    	{
			for (int j = 0; j < current_led["position"].size(); ++j) 
			{
				ROS_ASSERT(current_led["position"][j].getType() == XmlRpc::XmlRpcValue::TypeDouble);
				position.push_back( current_led["position"][j] );
			}
			local_points_(i, 1) = position[0];
			local_points_(i, 2) = position[1];
			local_points_(i, 3) = position[2];
	    	}
    		else
		{
			ROS_ERROR("No double value for the position current led. Check the yaml configuration for this object, remember to use . dots to ensure double format");
			return;
		}
	}

	ROS_INFO("Succesfully parsed all LED parameters!");
	// std::cout << local_points_ << std::endl;

	return;
}
Example #6
0
bool HmValue::ListConnections( XmlRpc::XmlRpcValue& list )
{
	if( _sendingChannel )
	{
		XmlRpcValue dict;
		dict["Alias"] = _sendingChannel->GetAlias();
		dict["Name"] = _sendingChannel->GetName();
		dict["DisplayName"] = _sendingChannel->GetDisplayName();
		if( _channel->GetDevice()->GetInterface() )
		{
			dict["XmlRpcInterfaceId"] = _channel->GetDevice()->GetInterface()->GetId();
			dict["XmlRpcInterfaceUrl"] = _channel->GetDevice()->GetInterface()->GetUrl();
			dict["XmlRpcDevice"] = _channel->GetDevice()->GetSerial();
			dict["XmlRpcChannel"] = _channel->GetSerial();
			dict["XmlRpcValue"] = GetId();
		}
		dict["Device"] = _channel->GetDevice()->GetId();
		dict["DeviceDisplayName"] = _channel->GetDevice()->GetDisplayName();
		dict["ChannelIndex"] = _channel->GetIndex();
		dict["Terminal"] = _channel->GetTerminal();
		dict["Direction"] = "Input";
		list[list.size()] = dict;
	}
	if( _receivingConnection )
	{
		std::vector<IcChannel*> receivingChannels = _receivingConnection->GetReceivingChannels();
		for( unsigned int i=0; i<receivingChannels.size(); i++ )
		{
			XmlRpcValue dict;
			dict["Alias"] = receivingChannels[i]->GetAlias();
			dict["Name"] = receivingChannels[i]->GetName();
			dict["DisplayName"] = receivingChannels[i]->GetDisplayName();
			if( _channel->GetDevice()->GetInterface() )
			{
				dict["XmlRpcInterfaceId"] = _channel->GetDevice()->GetInterface()->GetId();
				dict["XmlRpcInterfaceUrl"] = _channel->GetDevice()->GetInterface()->GetUrl();
				dict["XmlRpcDevice"] = _channel->GetDevice()->GetSerial();
				dict["XmlRpcChannel"] = _channel->GetSerial();
				dict["XmlRpcValue"] = GetId();
			}
			dict["Device"] = _channel->GetDevice()->GetId();
			dict["DeviceDisplayName"] = _channel->GetDevice()->GetDisplayName();
			dict["ChannelIndex"] = _channel->GetIndex();
			dict["Terminal"] = _channel->GetTerminal();
			dict["Direction"] = "Output";
			list[list.size()] = dict;
		}
	}
	return true;
}
bool SensorConfiguration::XmlRpcValueToEigenXd(XmlRpc::XmlRpcValue& field,
    Eigen::VectorXd *target) {

  target->resize(field.size());

  for (int k = 0; k < field.size(); k++) {
    if (field[k].getType() != XmlRpc::XmlRpcValue::TypeDouble) {
      return false;
    }

    (*target)[k] = static_cast<double>(field[k]);
  }

  return true;
}
Example #8
0
void TeleopCOB::getConfigurationFromParameters()
{
	//std::map<std::string,joint_module> joint_modules; //std::vector<std::string> module_names;
	if(n_.hasParam("modules"))
	{
		XmlRpc::XmlRpcValue modules;
		ROS_DEBUG("modules found ");
		n_.getParam("modules", modules);
		if(modules.getType() == XmlRpc::XmlRpcValue::TypeStruct)
		{
			ROS_DEBUG("modules are of type struct with size %d",(int)modules.size());

			for(std::map<std::string,XmlRpc::XmlRpcValue>::iterator p=modules.begin();p!=modules.end();++p)
			{
				std::string mod_name = p->first;
				ROS_DEBUG("module name: %s",mod_name.c_str());
				XmlRpc::XmlRpcValue mod_struct = p->second;
				if(mod_struct.getType() != XmlRpc::XmlRpcValue::TypeStruct)
					ROS_WARN("invalid module, name: %s",mod_name.c_str());
				// search for joint_name parameter in current module struct to determine which type of module
				// only joint mods or wheel mods supported
				// which mens that is no joint names are found, then the module is a wheel module
				// TODO replace with build in find, but could not get it to work
				if(!assign_joint_module(mod_name, mod_struct))
				{
					// add wheel module struct
					ROS_DEBUG("wheel module found");
					assign_base_module(mod_struct);
				}
			}
		}
	}
}
template <typename T> bool read_vector(ros::NodeHandle &n_, const std::string &key, std::vector<T> & res){
    XmlRpc::XmlRpcValue namesXmlRpc;
    if (!n_.hasParam(key))
    {
	return false;
    }

    n_.getParam(key, namesXmlRpc);
    /// Resize and assign of values to the vector
    res.resize(namesXmlRpc.size());
    for (int i = 0; i < namesXmlRpc.size(); i++)
    {
    	res[i] = (T)namesXmlRpc[i];
    }
    return true;
}
Example #10
0
bool FTParamsInternal::getDoubleArray(XmlRpc::XmlRpcValue params, const char* name, double *results, unsigned len)
{
  if(!params.hasMember(name))
  {
    ROS_ERROR("Expected ft_param to have '%s' element", name);
    return false;
  }

  XmlRpc::XmlRpcValue values = params[name];
  if (values.getType() != XmlRpc::XmlRpcValue::TypeArray)
  {
    ROS_ERROR("Expected FT param '%s' to be list type", name);
    return false;
  }
  if (values.size() != int(len))
  {
    ROS_ERROR("Expected FT param '%s' to have %d elements", name, len);
    return false;
  }
  for (unsigned i=0; i<len; ++i)
  {
    if (values[i].getType() != XmlRpc::XmlRpcValue::TypeDouble)
    {
      ROS_ERROR("Expected FT param %s[%d] to be floating point type", name, i);
      return false;
    } else {
      results[i] = static_cast<double>(values[i]);
    }
  }

  return true;
}
void startWorkingCallback::execute (XmlRpc::XmlRpcValue& params, XmlRpc::XmlRpcValue& result)
{
    // if no arguments were received
    if (!params.valid())
    {
        result = ctrl_xmlrpc->startProcessing();
    }
    else
    {
        switch(params.size())
        {
        // start the server in online mode with port and blocksize
        case 2:
            ctrl_xmlrpc->startEegServer((int) params[0], (int) params[1]);
            result = 0;
            break;
        case 3:
            ctrl_xmlrpc->startEegServer((std::string) params[0], (int) params[1], (int) params[2]);
            result = 0;
            break;
        default:
            OMG("WARNING! Server got wrong number of arguments!");
            break;
        }
    }
    fflush(stdout);
}
Example #12
0
/*generateConfigVector stores the pinging sensors, to which pinging sensor is a listening
 * sensor bound to in a cycle and which sensors are not used at all.
 * In the output, the pinging sensors are represented by PINGING_SENSOR, location of
 * each listening sensor holds the address of its corresponding pinging sensor
 * and the sensors not used at all are represented by SENSOR_NOT_USED.
 */
std::vector <std::vector<int> > generateConfigVector(XmlRpc::XmlRpcValue config_list)
{
	std::vector<std::vector<int> > config;
	XmlRpc::XmlRpcValue current_cycle;
	ROS_ASSERT(config_list.getType() == XmlRpc::XmlRpcValue::TypeArray);

	for(int i = 0; i < config_list.size(); i++)
	{
		ROS_ASSERT(config_list[i].getType() == XmlRpc::XmlRpcValue::TypeStruct);
		std::vector<int> cycle_vector; //For holding configuration for each cycle.
		cycle_vector.resize(MAX_SENSORS);
		for (int j=0; j<MAX_SENSORS; j++)
			cycle_vector[j]=SENSOR_NOT_USED;

		//better to keep it dynamic
		for (int j = 0; j<MAX_SENSORS; j++){
			char str_index[3] = {'\0','\0', '\0'}; // for storing int to hex conv. 
			sprintf(str_index,"%d", j); // Unsure if yamlcpp parser reads hexadecimal values
			if(config_list[i].hasMember(str_index))
			{
				cycle_vector[j]=PINGING_SENSOR; //Set -1 for pinging sensor
				current_cycle = (config_list[i]).operator[](str_index);
				ROS_ASSERT(current_cycle.getType() == XmlRpc::XmlRpcValue::TypeArray);
				ROS_ASSERT(current_cycle.size()>0);
				//Assign address of pinging sensor to each listening sensor
				for (int k = 0; k<current_cycle.size(); k++){
					cycle_vector[static_cast<int>(current_cycle[k])]=((static_cast<int>(current_cycle[k])!=j)?j:PINGING_AND_LISTENING_SENSOR);
				}
			}
		}
		config.push_back(cycle_vector);
	}
	return config;
}
bool TestCollisionWorld::readDoubleArray(XmlRpc::XmlRpcValue& list, std::vector<double>& array)
{
    if (list.getType() != XmlRpc::XmlRpcValue::TypeArray)
    {
        ROS_ERROR("Parameter needs to be an *array* of doubles");
        return false;
    }

    array.clear();
    for (int32_t i = 0; i < list.size(); ++i)
    {
        if (list[i].getType() != XmlRpc::XmlRpcValue::TypeDouble &&
                list[i].getType() != XmlRpc::XmlRpcValue::TypeInt)
        {
            ROS_ERROR("Parameter needs to be an array of *doubles*");
            return false;
        }
        double value=0.0;
        if (list[i].getType() == XmlRpc::XmlRpcValue::TypeInt)
            value = static_cast<double>(static_cast<int>(list[i]));
        else value = static_cast<double>(list[i]);
        array.push_back(value);
    }
    return true;
}
void BeaconKFNode::getCovarianceMatrix(std::string param_name, MatrixWrapper::SymmetricMatrix& m)
{
    ros::NodeHandle private_nh("~");

    XmlRpc::XmlRpcValue values;
    private_nh.getParam(param_name, values);
    if( values.getType() != XmlRpc::XmlRpcValue::TypeArray )
    {
        ROS_ERROR("BEACON LOCALIZER Unable to read covariance %s, not an array", param_name.c_str());
        return;
    }
    if( values.size() < 6 )
    {
        ROS_ERROR("BEACON LOCALIZER Unable to read covariance %s, array too short: %d", param_name.c_str(), values.size());
        return;
    }
    int i=0;
    for (uint32_t row = 1; row <= m.rows(); ++row)
    {
        for (uint32_t column = row; column <= m.columns(); ++column)
        {
            double x;
            if(i>=values.size())
            {
                ROS_ERROR("BEACON LOCALIZER Need at least 6 values, have %d", i);
                return;
            }
            XmlRpc::XmlRpcValue value=values[i++];
            if( value.getType() == XmlRpc::XmlRpcValue::TypeInt )
            {
                x=int(value);
            }
            else if(value.getType() == XmlRpc::XmlRpcValue::TypeDouble )
            {
                x=double(value);
            }
            else
            {
                std::string vstr = value;
                ROS_ERROR("BEACON LOCALIZER Unable to read covariance matrix %s, value at %d is not a number: %s",
                        param_name.c_str(), i, vstr.c_str());
                return;
            }
            m(row, column) = x;
        }
    }
}
bool PTPFollowJointTrajectoryController::init(hardware_interface::PositionJointInterface* hw, ros::NodeHandle &root_nh, ros::NodeHandle& controller_nh)
{
  nh_ = controller_nh;

  // get all joint states from the hardware interface
  const std::vector<std::string>& joint_names = hw->getNames();
  for (unsigned i = 0; i < joint_names.size(); i++)
    ROS_DEBUG_NAMED("PTPFollowJointController", "Got joint %s", joint_names[i].c_str());

  XmlRpc::XmlRpcValue joints;
  if (!controller_nh.getParam("joints", joints))
  {
    ROS_ERROR("No joints array setting");
    return false;
  }
  if (joints.getType() != XmlRpc::XmlRpcValue::TypeArray)
  {
    ROS_ERROR("Joints array setting setting type mismatched");
    return false;
  }

  for (size_t i = 0; i < joints.size(); i++)
  {
    std::string joint_name;
    ROS_ASSERT(joints[i].getType() == XmlRpc::XmlRpcValue::TypeString);
    joint_name = static_cast<std::string>(joints[i]);

    for(size_t j = 0; j < joint_names.size(); j++)
    {
      if(joint_name == joint_names[i])
      {
        ROS_DEBUG("Add joint %s to PTPFollowJointController", joint_name.c_str());
        joints_.push_back(hw->getHandle(joint_name));
        break;
      }
    }
  }

  q.resize(joints_.size());
  qd.resize(joints_.size());
  qdd.resize(joints_.size());

  // Creates a dummy trajectory
  boost::shared_ptr<SpecifiedTrajectory> traj_ptr(new SpecifiedTrajectory(1));
  SpecifiedTrajectory &traj = *traj_ptr;
  traj[0].duration = 0.0;
  traj[0].splines.resize(joints_.size());
  for (size_t j = 0; j < joints_.size(); ++j)
    traj[0].splines[j].coef[0] = 0.0;
  current_trajectory_box_.set(traj_ptr);


  action_server_follow_.reset(new FJTAS(controller_nh, "ptp_follow_joint_trajectory",
                                        boost::bind(&PTPFollowJointTrajectoryController::goalCBFollow, this, _1),
                                        boost::bind(&PTPFollowJointTrajectoryController::cancelCBFollow, this, _1),
                                        false));
  action_server_follow_->start();
  return true;
}
Example #16
0
    void
    onInit()
    {
        n_ = getNodeHandle();

        ros::NodeHandle pn = getPrivateNodeHandle();
        pn.getParam("target_frame_id", target_frame_id_);
        pn.getParam("table_frame_id", table_frame_id_);
        pn.getParam("height_min", height_min_);
        pn.getParam("height_max", height_max_);
        XmlRpc::XmlRpcValue v;
        pn.getParam("table_dimensions", v);
        if( v.size() < 3)
        {
            ROS_ERROR("Hull points not set correctly, nodelet will not work");
            return;
        }
        double x ,y, z;
        x = (double)v[0];
        y = (double)v[1];
        z = (double)v[2];
        Eigen::Vector3d p;
        p << -x/2, -y/2, z;
        hull_points_[0] = p;
        p << -x/2, y/2, z;
        hull_points_[1] = p;
        p << x/2, y/2, z;
        hull_points_[2] = p;
        p << x/2, -y/2, z;
        hull_points_[3] = p;

        tf::StampedTransform trf_table;
        try
        {
            tf_listener_.waitForTransform(target_frame_id_, table_frame_id_, ros::Time(), ros::Duration(2));
            tf_listener_.lookupTransform(target_frame_id_, table_frame_id_, ros::Time(), trf_table);
        }
        catch (tf::TransformException& ex) {
            ROS_ERROR("[transform region crop] : %s",ex.what());
            return;
        }
        Eigen::Affine3d ad;
        tf::transformTFToEigen(trf_table, ad);

        for(int i = 0; i < hull_points_.size(); i++)
        {
            Point p;
            p.getVector3fMap() = (ad*hull_points_[i]).cast<float>();
            hull_->points[i] = p;
        }

        pc_sub_ = n_.subscribe<PointCloud>("point_cloud_in", 1, boost::bind(&TableRegionCropNodelet::topicCallback, this, _1));
        pc_pub_ = n_.advertise<PointCloud>("point_cloud_out", 1);

        eppd_.setInputPlanarHull(hull_);
        eppd_.setHeightLimits(height_min_, height_max_);
        eppd_.setViewPoint(0,0,5);
    }
Example #17
0
void ServoInterface::loadServoParams()
{
  //read in servo settings
  ros::NodeHandle nhPvt = getPrivateNodeHandle();
  XmlRpc::XmlRpcValue v;
  nhPvt.param("servos", v, v);
  if(v.getType() == XmlRpc::XmlRpcValue::TypeStruct)
  {
    XmlRpc::XmlRpcValue servoInfo;
    ServoSettings toAdd;
    for(int i = 0; i < v.size(); i++)
    {
      servoInfo = v[boost::lexical_cast<std::string>(i)];

      if(servoInfo.getType() == XmlRpc::XmlRpcValue::TypeStruct &&
         servoInfo.size() == 5)
      {
        toAdd.center = static_cast<int>(servoInfo["center"]);
        toAdd.min = static_cast<int>(servoInfo["min"]);
        toAdd.max = static_cast<int>(servoInfo["max"]);
        toAdd.range = toAdd.max-toAdd.min;
        toAdd.port = i;
        toAdd.reverse = static_cast<bool>(servoInfo["reverse"]);
        m_servoSettings[servoInfo["name"]] = toAdd;
      } else
      {
        NODELET_ERROR("ServoInterface: XmlRpc servo settings formatted incorrectly");
      }
    }
  } else
  {
    NODELET_ERROR("ServoInterface: Couldn't retreive servo settings");
  }
  NODELET_INFO("ServoInterface: Loaded %lu servos", m_servoSettings.size());

  if(m_servoSettings.find("frontBrake") != m_servoSettings.end())
  {
    m_brakeSetup.independentFront = true;
  }
  if(m_servoSettings.find("backBrake") != m_servoSettings.end())
  {
    m_brakeSetup.independentBack = true;
  }
}
Example #18
0
// Replacement "shutdown" XMLRPC callback
void shutdownCallback( XmlRpc::XmlRpcValue& params, XmlRpc::XmlRpcValue& result )
{
	if( (params.getType() == XmlRpc::XmlRpcValue::TypeArray)
			&& (params.size() > 1) ) {
		std::string reason = params[1];
		ROS_WARN( "Shutdown request received. Reason: [%s]", reason.c_str() );
		g_request_shutdown = 1;
	}
	result = ros::xmlrpc::responseInt( 1, "", 0 );
}
Example #19
0
// Constructor
Propulsion::Propulsion(ModelPlane * parent, int ID)
{
	parentObj = parent;
	id = ID;
	XmlRpc::XmlRpcValue list;
	int i;
	char paramMsg[50];
	sprintf(paramMsg, "motor%i/CGOffset", id);
	if(!ros::param::getCached(paramMsg, list)) {ROS_FATAL("Invalid parameters for -%s- in param server!", paramMsg); ros::shutdown();}
	for (i = 0; i < list.size(); ++i) {
		ROS_ASSERT(list[i].getType() == XmlRpc::XmlRpcValue::TypeDouble);
	}
	CGOffset.x = list[0];
	CGOffset.y = list[1];
	CGOffset.z = list[2];

	sprintf(paramMsg, "motor%i/mountOrientation", id);
	if(!ros::param::getCached(paramMsg, list)) {ROS_FATAL("Invalid parameters for -%s- in param server!", paramMsg); ros::shutdown();}
	for (i = 0; i < list.size(); ++i) {
		ROS_ASSERT(list[i].getType() == XmlRpc::XmlRpcValue::TypeDouble);
	}
	// !!! Order mixed because tf::Quaternion::setEuler seems to work with PRY, instead of YPR
	mountOrientation.y = list[0];
	mountOrientation.z = list[1];
	mountOrientation.x = list[2];

	theta = 0; // Initialize propeller angle

	sprintf(paramMsg, "motor%i/chanMotor", id);
	if(!ros::param::getCached(paramMsg, chanMotor)) {ROS_INFO("No MOTOR%i channel selected", id); chanMotor=-1;}
	sprintf(paramMsg, "motor%i/chanGimbal", id);
	if(!ros::param::getCached(paramMsg, chanGimbal)) {ROS_INFO("No GIMBAL%i channel selected", id); chanGimbal=-1;}
	sprintf(paramMsg, "motor%i/gimbalAngle_max", id);
	if(!ros::param::getCached(paramMsg, gimbalAngle_max)) {ROS_INFO("No GIMBALANGLE_MAX%i value selected", id); gimbalAngle_max=0.0;}

	inputMotor = 0.0;
	inputGimbal = 0.0;

	sprintf(paramMsg, "motor%i/rotationDir", id);
	if(!ros::param::getCached(paramMsg, rotationDir)) {ROS_INFO("No ROTATION_DIR%i value selected", id); rotationDir=1.0;}

}
bool SensorConfiguration::XmlRpcValueToEigenXd(XmlRpc::XmlRpcValue& field,
    Eigen::MatrixXd *target) {

  int n = std::sqrt(field.size());
  if (field.size() != std::pow(n, 2)) {
    return false;
  }

  target->resize(n, n);

  for (int r = 0; r < n; r++) {
    for (int c = 0; c < n; c++) {
      if (field[r * n + c].getType() != XmlRpc::XmlRpcValue::TypeDouble) {
        return false;
      }
      (*target)(r, c) = static_cast<double>(field[r * n + c]);
    }
  }

  return true;
}
Example #21
0
QLearner::QLearner(ros::NodeHandle nh)
{
  n_ = nh;
  ros::NodeHandle n_private("~");
  n_private.param("num_states", num_states_, 8);
  n_private.param("num_actions", num_actions_, 3);
  n_private.param("learning_rate", learning_rate_, 0.3);
  n_private.param("discount_factor", discount_factor_, 0.5);
  n_private.param("temp_const", temp_const_, 5.0);
  n_private.param("temp_alpha", temp_alpha_, 0.85);
  
  temp_cnt_ = 0;
  temp_ = temp_const_ * pow(temp_alpha_, temp_cnt_);
  size_array_ = num_actions_ * num_states_;

  srand ( time(NULL) );
 	Init();
 	
  if (n_private.hasParam("qarray"))
  {
    learn_ = false;
    
    // Get the qtable
    XmlRpc::XmlRpcValue qtable;
	  n_private.getParam("qarray", qtable);
	  if (qtable.getType() != XmlRpc::XmlRpcValue::TypeArray)
		  ROS_ERROR("Error reading footsteps/x from config file.");
		  
    int size;
		try
		{
			size = qtable.size();
			
			if (size != (num_states_ * num_actions_))
			{
				ROS_ERROR("Size of array does not match num_states * num_actions = %d,\
				           exiting.", num_states_ * num_actions_);
				exit(0);
			}
		} 
		catch (const XmlRpc::XmlRpcException e)
		{
			ROS_ERROR("No table available, exiting.");
			exit(0);
		}

		// create qarray set
		for(int i=0; i < size; i++)
		{
			q_array_.push_back((double)qtable[i]);
		}
  }
 /*
   parameter format is:
   polygon_array: [[[0, 0, 0], [0, 0, 1], [1, 0, 0]], ...]
  */
 bool StaticPolygonArrayPublisher::readPolygonArray(const std::string& param_name)
 {
   if (pnh_->hasParam(param_name)) {
     XmlRpc::XmlRpcValue v;
     pnh_->param(param_name, v, v);
     if (v.getType() == XmlRpc::XmlRpcValue::TypeArray) {
       for (size_t toplevel_i = 0; toplevel_i < v.size(); toplevel_i++) { // polygons
         XmlRpc::XmlRpcValue polygon_v = v[toplevel_i];
         geometry_msgs::PolygonStamped polygon;
         if (polygon_v.getType() == XmlRpc::XmlRpcValue::TypeArray &&
             polygon_v.size() >= 3) {
           for (size_t secondlevel_i = 0; secondlevel_i < polygon_v.size(); secondlevel_i++) { // each polygon, vertices
             XmlRpc::XmlRpcValue vertex_v = polygon_v[secondlevel_i];
             if (vertex_v.getType() == XmlRpc::XmlRpcValue::TypeArray &&
                 vertex_v.size() == 3 ) { // vertex_v := [x, y, z]
               double x = getXMLDoubleValue(vertex_v[0]);
               double y = getXMLDoubleValue(vertex_v[1]);
               double z = getXMLDoubleValue(vertex_v[2]);
               geometry_msgs::Point32 point;
               point.x = x;
               point.y = y;
               point.z = z;
               polygon.polygon.points.push_back(point);
             }
             else {
               JSK_NODELET_FATAL("%s[%lu][%lu] is not array or the length is not 3",
                             param_name.c_str(), toplevel_i, secondlevel_i);
               return false;
             }
           }
           polygons_.polygons.push_back(polygon);
           // estimate model coefficients
           coefficients_.coefficients.push_back(polygonToModelCoefficients(polygon));
         }
         else {
           JSK_NODELET_FATAL("%s[%lu] is not array or not enough points", param_name.c_str(), toplevel_i);
           return false;
         }
       }
       return true;
     }
     else {
       JSK_NODELET_FATAL("%s is not array", param_name.c_str());
       return false;
     }
   }
   else {
     JSK_NODELET_FATAL("no %s is available on parameter server", param_name.c_str());
     return false;
   }
   return true;
 }
// Class constructor
PanosContactPoints::PanosContactPoints(ModelPlane * parent) : GroundReaction(parent)
{
	XmlRpc::XmlRpcValue list;
	int i, j, points;
	char paramMsg[50];
	double temp[6];
	// Read contact points number from parameter server
	if(!ros::param::getCached("airframe/contactPtsNo", contactPtsNo)) {ROS_FATAL("Invalid parameters for -/airframe/contactPtsNo- in param server!"); ros::shutdown();}
	// Create an appropriately sized matrix to contain contact point information
	pointCoords = (double*)malloc(sizeof(double) * contactPtsNo*3); // contact points coordinates in the body frame
	materialIndex = (double*)malloc(sizeof(double) * contactPtsNo*1); // contact points material type index
	springIndex = (double*)malloc(sizeof(double) * contactPtsNo*2); // contact points spring characteristics
	len=0.2;

	// Set coefficient of friction for each material
	frictForw[0] = 0.7; frictSide[0] = 0.7;
	frictForw[1] = 0.4; frictSide[1] = 0.4;
	frictForw[2] = 0.1; frictSide[2] = 1.0;
	frictForw[3] = 0.4; frictSide[3] = 0.4; //To update composite to ground firction coefficients!

	// Read contact points location and material from parameter server
	for (j = 0; j<contactPtsNo; j++) { //Distribute the data
		sprintf(paramMsg, "airframe/contactPoint%i", j+1);
		if(!ros::param::getCached(paramMsg, list)) {ROS_FATAL("Invalid parameters for -/airframe/contactPoint- in param server!"); ros::shutdown();}
		for (i = 0; i < list.size(); ++i) {
			ROS_ASSERT(list[i].getType() == XmlRpc::XmlRpcValue::TypeDouble);
			temp[i]=list[i];
		}
		pointCoords[j] = temp[0]; // Save body frame contact point coordinates
		pointCoords[j + contactPtsNo] = temp[1];
		pointCoords[j + contactPtsNo*2] = temp[2];
		materialIndex[j] = temp[3]; // A separate contact point material index array
		springIndex[j] = temp[4]; // And the spring constants
		springIndex[j + contactPtsNo] = temp[5];
	}

	// Create and initialize spring contraction container
	spp = (double*)malloc(sizeof(double) * contactPtsNo);
	memset(spp, 0, sizeof(spp));

	// Create and initialize previous spring contraction container
	sppprev = (double*)malloc(sizeof(double) * contactPtsNo);
	memset(sppprev, 0, sizeof(sppprev));

	contact = false;

	// Create other matrices needed for calculations
	cpi_up = (double*)malloc(sizeof(double) * contactPtsNo*3); // upper spring end matrix
	cpi_down = (double*)malloc(sizeof(double) * contactPtsNo*3); // lower spring end matrix
	spd = (double*)malloc(sizeof(double) * contactPtsNo); // spring contraction speed
}
Example #24
0
void shutdownCallback(XmlRpc::XmlRpcValue& params, XmlRpc::XmlRpcValue& result)
{
  int num_params = 0;
  if (params.getType() == XmlRpc::XmlRpcValue::TypeArray)
    num_params = params.size();
  if (num_params > 1)
  {
    std::string reason = params[1];
    ROS_WARN("Shutdown request received. Reason: [%s]", reason.c_str());
    ::gShutdownRequest = 1; // Set flag
  }

  result = ros::xmlrpc::responseInt(1, "", 0);
}
		/*!
		* \brief Routine for publishing joint_states.
		*
		* Gets current positions and velocities from the hardware and publishes them as joint_states.
		*/
		void publishJointState()
		{
			if (isInitialized_ == true)
			{
				// create joint_state message
				int DOF = ModIds_param_.size();
				std::vector<double> ActualPos;
				std::vector<double> ActualVel;
				ActualPos.resize(DOF);
				ActualVel.resize(DOF);

				PCube_->getConfig(ActualPos);
				PCube_->getJointVelocities(ActualVel);

				sensor_msgs::JointState msg;
				msg.header.stamp = ros::Time::now();
				msg.name.resize(DOF);
				msg.position.resize(DOF);
				msg.velocity.resize(DOF);

				msg.name = JointNames_;

				for (int i = 0; i<DOF; i++ )
				{
					msg.position[i] = ActualPos[i];
					msg.velocity[i] = ActualVel[i];
					//std::cout << "Joint " << msg.name[i] <<": pos="<<  msg.position[i] << "vel=" << msg.velocity[i] << std::endl;
				}
		
				// publish message
				topicPub_JointState_.publish(msg);

				pr2_controllers_msgs::JointTrajectoryControllerState controllermsg;
				controllermsg.header.stamp = ros::Time::now();
				controllermsg.joint_names.resize(DOF);
				controllermsg.actual.positions.resize(DOF);
				controllermsg.actual.velocities.resize(DOF);

				controllermsg.joint_names = JointNames_;

				for (int i = 0; i<DOF; i++ )
				{
					controllermsg.actual.positions[i] = ActualPos[i];
					controllermsg.actual.velocities[i] = ActualVel[i];
					//std::cout << "Joint " << msg.name[i] <<": pos="<<  msg.position[i] << "vel=" << msg.velocity[i] << std::endl;
				}
				topicPub_ControllerState_.publish(controllermsg);

			}
		}
Example #26
0
 std::vector<std::string> MUX::readStringArray(std::string param_name,
                                               ros::NodeHandle& handle)
 {
   // read string array
   std::vector<std::string> strings;
   XmlRpc::XmlRpcValue v;
   if (handle.hasParam(param_name)) {
     handle.param(param_name, v, v);
     for (size_t i = 0; i < v.size(); i++) {
       strings.push_back(v[i]);
     }
   }
   return strings;
 }
		/*!
		* \brief Executes the callback from the actionlib.
		*
		* Set the current goal to aborted after receiving a new goal and write new goal to a member variable. Wait for the goal to finish and set actionlib status to succeeded.
		* \param goal JointTrajectoryGoal
		*/
		void executeCB(const pr2_controllers_msgs::JointTrajectoryGoalConstPtr &goal)
		{
			ROS_INFO("Received new goal trajectory with %d points",goal->trajectory.points.size());
			if (!isInitialized_)
			{
				ROS_ERROR("%s: Rejected, powercubes not initialized", action_name_.c_str());
				as_.setAborted();
				return;
			}
			// saving goal into local variables
			traj_ = goal->trajectory;
			traj_point_nr_ = 0;
			traj_point_ = traj_.points[traj_point_nr_];
			finished_ = false;
			
			// stoping arm to prepare for new trajectory
			std::vector<double> VelZero;
			VelZero.resize(ModIds_param_.size());
			PCube_->MoveVel(VelZero);

			// check that preempt has not been requested by the client
			if (as_.isPreemptRequested())
			{
				ROS_INFO("%s: Preempted", action_name_.c_str());
				// set the action state to preempted
				as_.setPreempted();
			}
			
			usleep(500000); // needed sleep until powercubes starts to change status from idle to moving
			
			while(finished_ == false)
			{
				if (as_.isNewGoalAvailable())
				{
					ROS_WARN("%s: Aborted", action_name_.c_str());
					as_.setAborted();
					return;
				}
		   		usleep(10000);
				//feedback_ = 
				//as_.send feedback_
			}

			// set the action state to succeed			
			//result_.result.data = "executing trajectory";
			ROS_INFO("%s: Succeeded", action_name_.c_str());
			// set the action state to succeeded
			as_.setSucceeded(result_);
		}
Example #28
0
inline bool parameterToColor(const ros::NodeHandle& node, const
    std::string& key, float* color) {
  XmlRpc::XmlRpcValue value;
  node.getParam(key, value);
  if (value.getType() == XmlRpc::XmlRpcValue::TypeArray) {
    if (value.size() == 3) {
      color[0] = static_cast<double>(value[0]);
      color[1] = static_cast<double>(value[1]);
      color[2] = static_cast<double>(value[2]);
   }
    else {
      ROS_WARN("Invalid array size for color parameter %s: %d", key.c_str(),
        (unsigned int)value.size());
      return false;
    }
  }
  else {
    ROS_WARN("Invalid type for color parameter %s: expecting array",
      key.c_str(), (unsigned int)value.size());
    return false;
  }
  
  return true;
}
Example #29
-1
bool getNodes(V_string& nodes)
{
  XmlRpc::XmlRpcValue args, result, payload;
  args[0] = this_node::getName();

  if (!execute("getSystemState", args, result, payload, true))
  {
    return false;
  }

  S_string node_set;
  for (int i = 0; i < payload.size(); ++i)
  {
    for (int j = 0; j < payload[i].size(); ++j)
    {
      XmlRpc::XmlRpcValue val = payload[i][j][1];
      for (int k = 0; k < val.size(); ++k)
      {
        std::string name = payload[i][j][1][k];
        node_set.insert(name);
      }
    }
  }

  nodes.insert(nodes.end(), node_set.begin(), node_set.end());

  return true;
}
void FootstepMarker::readPoseParam(ros::NodeHandle& pnh, const std::string param,
                                   tf::Transform& offset) {
  XmlRpc::XmlRpcValue v;
  geometry_msgs::Pose pose;
  if (pnh.hasParam(param)) {
    pnh.param(param, v, v);
    // check if v is 7 length Array
    if (v.getType() == XmlRpc::XmlRpcValue::TypeArray &&
        v.size() == 7) {
      // safe parameter access by getXMLDoubleValue
      pose.position.x = getXMLDoubleValue(v[0]);
      pose.position.y = getXMLDoubleValue(v[1]);
      pose.position.z = getXMLDoubleValue(v[2]);
      pose.orientation.x = getXMLDoubleValue(v[3]);
      pose.orientation.y = getXMLDoubleValue(v[4]);
      pose.orientation.z = getXMLDoubleValue(v[5]);
      pose.orientation.w = getXMLDoubleValue(v[6]);
      // converst the message as following: msg -> eigen -> tf
      //void poseMsgToEigen(const geometry_msgs::Pose &m, Eigen::Affine3d &e);
      Eigen::Affine3d e;
      tf::poseMsgToEigen(pose, e); // msg -> eigen
      tf::transformEigenToTF(e, offset); // eigen -> tf
    }
    else {
      ROS_ERROR_STREAM(param << " is malformed, which should be 7 length array");
    }
  }
  else {
    ROS_WARN_STREAM("there is no parameter on " << param);
  }
}