/****************************************************************************
 *
 *   Copyright (c) 2012-2019 PX4 Development Team. All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in
 *    the documentation and/or other materials provided with the
 *    distribution.
 * 3. Neither the name PX4 nor the names of its contributors may be
 *    used to endorse or promote products derived from this software
 *    without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
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/**
 * @file mavlink_receiver.cpp
 * MAVLink protocol message receive and dispatch
 *
 * @author Lorenz Meier <lorenz@px4.io>
 * @author Anton Babushkin <anton@px4.io>
 * @author Thomas Gubler <thomas@px4.io>
 */

#include <airspeed/airspeed.h>
#include <conversion/rotation.h>
#include <drivers/drv_rc_input.h>
#include <ecl/geo/geo.h>
#include <systemlib/px4_macros.h>

#include <math.h>
#include <poll.h>

#ifdef CONFIG_NET
#include <net/if.h>
#include <arpa/inet.h>
#include <netinet/in.h>
#endif

#ifndef __PX4_POSIX
#include <termios.h>
#endif

#include "mavlink_command_sender.h"
#include "mavlink_main.h"
#include "mavlink_receiver.h"

#include <lib/drivers/device/Device.hpp> // For DeviceId union

#ifdef CONFIG_NET
#define MAVLINK_RECEIVER_NET_ADDED_STACK 1360
#else
#define MAVLINK_RECEIVER_NET_ADDED_STACK 0
#endif

using matrix::wrap_2pi;

MavlinkReceiver::~MavlinkReceiver()
{
	delete _tune_publisher;
	delete _px4_accel;
	delete _px4_baro;
	delete _px4_gyro;
	delete _px4_mag;
}

MavlinkReceiver::MavlinkReceiver(Mavlink *parent) :
	ModuleParams(nullptr),
	_mavlink(parent),
	_mavlink_ftp(parent),
	_mavlink_log_handler(parent),
	_mission_manager(parent),
	_parameters_manager(parent),
	_mavlink_timesync(parent)
{
}

void
MavlinkReceiver::acknowledge(uint8_t sysid, uint8_t compid, uint16_t command, uint8_t result)
{
	vehicle_command_ack_s command_ack{};

	command_ack.timestamp = hrt_absolute_time();
	command_ack.command = command;
	command_ack.result = result;
	command_ack.target_system = sysid;
	command_ack.target_component = compid;

	_cmd_ack_pub.publish(command_ack);
}

void
MavlinkReceiver::handle_message(mavlink_message_t *msg)
{
	switch (msg->msgid) {
	case MAVLINK_MSG_ID_COMMAND_LONG:
		handle_message_command_long(msg);
		break;

	case MAVLINK_MSG_ID_COMMAND_INT:
		handle_message_command_int(msg);
		break;

	case MAVLINK_MSG_ID_COMMAND_ACK:
		handle_message_command_ack(msg);
		break;

	case MAVLINK_MSG_ID_OPTICAL_FLOW_RAD:
		handle_message_optical_flow_rad(msg);
		break;

	case MAVLINK_MSG_ID_PING:
		handle_message_ping(msg);
		break;

	case MAVLINK_MSG_ID_SET_MODE:
		handle_message_set_mode(msg);
		break;

	case MAVLINK_MSG_ID_ATT_POS_MOCAP:
		handle_message_att_pos_mocap(msg);
		break;

	case MAVLINK_MSG_ID_SET_POSITION_TARGET_LOCAL_NED:
		handle_message_set_position_target_local_ned(msg);
		break;

	case MAVLINK_MSG_ID_SET_POSITION_TARGET_GLOBAL_INT:
		handle_message_set_position_target_global_int(msg);
		break;

	case MAVLINK_MSG_ID_SET_ATTITUDE_TARGET:
		handle_message_set_attitude_target(msg);
		break;

	case MAVLINK_MSG_ID_SET_ACTUATOR_CONTROL_TARGET:
		handle_message_set_actuator_control_target(msg);
		break;

	case MAVLINK_MSG_ID_VISION_POSITION_ESTIMATE:
		handle_message_vision_position_estimate(msg);
		break;

	case MAVLINK_MSG_ID_ODOMETRY:
		handle_message_odometry(msg);
		break;

	case MAVLINK_MSG_ID_SET_GPS_GLOBAL_ORIGIN:
		handle_message_set_gps_global_origin(msg);
		break;

	case MAVLINK_MSG_ID_RADIO_STATUS:
		handle_message_radio_status(msg);
		break;

	case MAVLINK_MSG_ID_MANUAL_CONTROL:
		handle_message_manual_control(msg);
		break;

	case MAVLINK_MSG_ID_RC_CHANNELS_OVERRIDE:
		handle_message_rc_channels_override(msg);
		break;

	case MAVLINK_MSG_ID_HEARTBEAT:
		handle_message_heartbeat(msg);
		break;

	case MAVLINK_MSG_ID_DISTANCE_SENSOR:
		handle_message_distance_sensor(msg);
		break;

	case MAVLINK_MSG_ID_FOLLOW_TARGET:
		handle_message_follow_target(msg);
		break;

	case MAVLINK_MSG_ID_LANDING_TARGET:
		handle_message_landing_target(msg);
		break;

	case MAVLINK_MSG_ID_CELLULAR_STATUS:
		handle_message_cellular_status(msg);
		break;

	case MAVLINK_MSG_ID_ADSB_VEHICLE:
		handle_message_adsb_vehicle(msg);
		break;

	case MAVLINK_MSG_ID_UTM_GLOBAL_POSITION:
		handle_message_utm_global_position(msg);
		break;

	case MAVLINK_MSG_ID_COLLISION:
		handle_message_collision(msg);
		break;

	case MAVLINK_MSG_ID_GPS_RTCM_DATA:
		handle_message_gps_rtcm_data(msg);
		break;

	case MAVLINK_MSG_ID_BATTERY_STATUS:
		handle_message_battery_status(msg);
		break;

	case MAVLINK_MSG_ID_SERIAL_CONTROL:
		handle_message_serial_control(msg);
		break;

	case MAVLINK_MSG_ID_LOGGING_ACK:
		handle_message_logging_ack(msg);
		break;

	case MAVLINK_MSG_ID_PLAY_TUNE:
		handle_message_play_tune(msg);
		break;

	case MAVLINK_MSG_ID_PLAY_TUNE_V2:
		handle_message_play_tune_v2(msg);
		break;

	case MAVLINK_MSG_ID_OBSTACLE_DISTANCE:
		handle_message_obstacle_distance(msg);
		break;

	case MAVLINK_MSG_ID_TRAJECTORY_REPRESENTATION_BEZIER:
		handle_message_trajectory_representation_bezier(msg);
		break;

	case MAVLINK_MSG_ID_TRAJECTORY_REPRESENTATION_WAYPOINTS:
		handle_message_trajectory_representation_waypoints(msg);
		break;

	case MAVLINK_MSG_ID_ONBOARD_COMPUTER_STATUS:
		handle_message_onboard_computer_status(msg);
		break;

	case MAVLINK_MSG_ID_GENERATOR_STATUS:
		handle_message_generator_status(msg);
		break;

	case MAVLINK_MSG_ID_STATUSTEXT:
		handle_message_statustext(msg);
		break;

#if !defined(CONSTRAINED_FLASH)

	case MAVLINK_MSG_ID_NAMED_VALUE_FLOAT:
		handle_message_named_value_float(msg);
		break;

	case MAVLINK_MSG_ID_DEBUG:
		handle_message_debug(msg);
		break;

	case MAVLINK_MSG_ID_DEBUG_VECT:
		handle_message_debug_vect(msg);
		break;

	case MAVLINK_MSG_ID_DEBUG_FLOAT_ARRAY:
		handle_message_debug_float_array(msg);
		break;
#endif // !CONSTRAINED_FLASH

	case MAVLINK_MSG_ID_GIMBAL_MANAGER_SET_ATTITUDE:
		handle_message_gimbal_manager_set_attitude(msg);
		break;

	case MAVLINK_MSG_ID_GIMBAL_MANAGER_SET_MANUAL_CONTROL:
		handle_message_gimbal_manager_set_manual_control(msg);
		break;

	case MAVLINK_MSG_ID_GIMBAL_DEVICE_INFORMATION:
		handle_message_gimbal_device_information(msg);
		break;

	default:
		break;
	}

	/*
	 * Only decode hil messages in HIL mode.
	 *
	 * The HIL mode is enabled by the HIL bit flag
	 * in the system mode. Either send a set mode
	 * COMMAND_LONG message or a SET_MODE message
	 *
	 * Accept HIL GPS messages if use_hil_gps flag is true.
	 * This allows to provide fake gps measurements to the system.
	 */
	if (_mavlink->get_hil_enabled()) {
		switch (msg->msgid) {
		case MAVLINK_MSG_ID_HIL_SENSOR:
			handle_message_hil_sensor(msg);
			break;

		case MAVLINK_MSG_ID_HIL_STATE_QUATERNION:
			handle_message_hil_state_quaternion(msg);
			break;

		case MAVLINK_MSG_ID_HIL_OPTICAL_FLOW:
			handle_message_hil_optical_flow(msg);
			break;

		default:
			break;
		}
	}


	if (_mavlink->get_hil_enabled() || (_mavlink->get_use_hil_gps() && msg->sysid == mavlink_system.sysid)) {
		switch (msg->msgid) {
		case MAVLINK_MSG_ID_HIL_GPS:
			handle_message_hil_gps(msg);
			break;

		default:
			break;
		}

	}

	/* If we've received a valid message, mark the flag indicating so.
	   This is used in the '-w' command-line flag. */
	_mavlink->set_has_received_messages(true);
}

bool
MavlinkReceiver::evaluate_target_ok(int command, int target_system, int target_component)
{
	/* evaluate if this system should accept this command */
	bool target_ok = false;

	switch (command) {

	case MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES:
	case MAV_CMD_REQUEST_PROTOCOL_VERSION:
		/* broadcast and ignore component */
		target_ok = (target_system == 0) || (target_system == mavlink_system.sysid);
		break;

	default:
		target_ok = (target_system == mavlink_system.sysid) && ((target_component == mavlink_system.compid)
				|| (target_component == MAV_COMP_ID_ALL));
		break;
	}

	return target_ok;
}

void
MavlinkReceiver::handle_message_command_long(mavlink_message_t *msg)
{
	/* command */
	mavlink_command_long_t cmd_mavlink;
	mavlink_msg_command_long_decode(msg, &cmd_mavlink);

	vehicle_command_s vcmd{};

	vcmd.timestamp = hrt_absolute_time();

	/* Copy the content of mavlink_command_long_t cmd_mavlink into command_t cmd */
	vcmd.param1 = cmd_mavlink.param1;
	vcmd.param2 = cmd_mavlink.param2;
	vcmd.param3 = cmd_mavlink.param3;
	vcmd.param4 = cmd_mavlink.param4;
	vcmd.param5 = (double)cmd_mavlink.param5;
	vcmd.param6 = (double)cmd_mavlink.param6;
	vcmd.param7 = cmd_mavlink.param7;
	vcmd.command = cmd_mavlink.command;
	vcmd.target_system = cmd_mavlink.target_system;
	vcmd.target_component = cmd_mavlink.target_component;
	vcmd.source_system = msg->sysid;
	vcmd.source_component = msg->compid;
	vcmd.confirmation = cmd_mavlink.confirmation;
	vcmd.from_external = true;

	handle_message_command_both(msg, cmd_mavlink, vcmd);
}

void
MavlinkReceiver::handle_message_command_int(mavlink_message_t *msg)
{
	/* command */
	mavlink_command_int_t cmd_mavlink;
	mavlink_msg_command_int_decode(msg, &cmd_mavlink);

	vehicle_command_s vcmd{};
	vcmd.timestamp = hrt_absolute_time();

	/* Copy the content of mavlink_command_int_t cmd_mavlink into command_t cmd */
	vcmd.param1 = cmd_mavlink.param1;
	vcmd.param2 = cmd_mavlink.param2;
	vcmd.param3 = cmd_mavlink.param3;
	vcmd.param4 = cmd_mavlink.param4;
	vcmd.param5 = ((double)cmd_mavlink.x) / 1e7;
	vcmd.param6 = ((double)cmd_mavlink.y) / 1e7;
	vcmd.param7 = cmd_mavlink.z;
	vcmd.command = cmd_mavlink.command;
	vcmd.target_system = cmd_mavlink.target_system;
	vcmd.target_component = cmd_mavlink.target_component;
	vcmd.source_system = msg->sysid;
	vcmd.source_component = msg->compid;
	vcmd.confirmation = false;
	vcmd.from_external = true;

	handle_message_command_both(msg, cmd_mavlink, vcmd);
}

template <class T>
void MavlinkReceiver::handle_message_command_both(mavlink_message_t *msg, const T &cmd_mavlink,
		const vehicle_command_s &vehicle_command)
{
	bool target_ok = evaluate_target_ok(cmd_mavlink.command, cmd_mavlink.target_system, cmd_mavlink.target_component);
	bool send_ack = true;
	uint8_t result = vehicle_command_ack_s::VEHICLE_RESULT_ACCEPTED;

	if (!target_ok) {
		acknowledge(msg->sysid, msg->compid, cmd_mavlink.command, vehicle_command_ack_s::VEHICLE_RESULT_FAILED);
		return;
	}

	// First we handle legacy support requests which were used before we had
	// the generic MAV_CMD_REQUEST_MESSAGE.
	if (cmd_mavlink.command == MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES) {
		result = handle_request_message_command(MAVLINK_MSG_ID_AUTOPILOT_VERSION);

	} else if (cmd_mavlink.command == MAV_CMD_REQUEST_PROTOCOL_VERSION) {
		result = handle_request_message_command(MAVLINK_MSG_ID_PROTOCOL_VERSION);

	} else if (cmd_mavlink.command == MAV_CMD_GET_HOME_POSITION) {
		result = handle_request_message_command(MAVLINK_MSG_ID_HOME_POSITION);

	} else if (cmd_mavlink.command == MAV_CMD_REQUEST_FLIGHT_INFORMATION) {
		result = handle_request_message_command(MAVLINK_MSG_ID_FLIGHT_INFORMATION);

	} else if (cmd_mavlink.command == MAV_CMD_REQUEST_STORAGE_INFORMATION) {
		result = handle_request_message_command(MAVLINK_MSG_ID_STORAGE_INFORMATION);

	} else if (cmd_mavlink.command == MAV_CMD_SET_MESSAGE_INTERVAL) {
		if (set_message_interval((int)roundf(cmd_mavlink.param1), cmd_mavlink.param2, cmd_mavlink.param3)) {
			result = vehicle_command_ack_s::VEHICLE_RESULT_FAILED;
		}

	} else if (cmd_mavlink.command == MAV_CMD_GET_MESSAGE_INTERVAL) {
		get_message_interval((int)roundf(cmd_mavlink.param1));

	} else if (cmd_mavlink.command == MAV_CMD_REQUEST_MESSAGE) {

		uint16_t message_id = (uint16_t)roundf(vehicle_command.param1);
		result = handle_request_message_command(message_id,
							vehicle_command.param2, vehicle_command.param3, vehicle_command.param4,
							vehicle_command.param5, vehicle_command.param6, vehicle_command.param7);

	} else if (cmd_mavlink.command == MAV_CMD_SET_CAMERA_ZOOM) {
		struct actuator_controls_s actuator_controls = {};
		actuator_controls.timestamp = hrt_absolute_time();

		for (size_t i = 0; i < 8; i++) {
			actuator_controls.control[i] = NAN;
		}

		switch ((int)(cmd_mavlink.param1 + 0.5f)) {
		case vehicle_command_s::VEHICLE_CAMERA_ZOOM_TYPE_RANGE:
			actuator_controls.control[actuator_controls_s::INDEX_CAMERA_ZOOM] = cmd_mavlink.param2 / 50.0f - 1.0f;
			break;

		case vehicle_command_s::VEHICLE_CAMERA_ZOOM_TYPE_STEP:
		case vehicle_command_s::VEHICLE_CAMERA_ZOOM_TYPE_CONTINUOUS:
		case vehicle_command_s::VEHICLE_CAMERA_ZOOM_TYPE_FOCAL_LENGTH:
		default:
			send_ack = false;
		}

		_actuator_controls_pubs[actuator_controls_s::GROUP_INDEX_GIMBAL].publish(actuator_controls);

	} else if (cmd_mavlink.command == MAV_CMD_INJECT_FAILURE) {
		if (_mavlink->failure_injection_enabled()) {
			_cmd_pub.publish(vehicle_command);
			send_ack = false;

		} else {
			result = vehicle_command_ack_s::VEHICLE_RESULT_DENIED;
			send_ack = true;
		}

	} else if (cmd_mavlink.command == MAV_CMD_DO_SET_ACTUATOR) {
		// since we're only paying attention to 3 AUX outputs, the
		// index should be 0, otherwise ignore the message
		if (((int) vehicle_command.param7) == 0) {
			actuator_controls_s actuator_controls{};
			// update with existing values to avoid changing unspecified controls
			_actuator_controls_3_sub.update(&actuator_controls);

			actuator_controls.timestamp = hrt_absolute_time();

			bool updated = false;

			if (PX4_ISFINITE(vehicle_command.param1)) {
				actuator_controls.control[5] = vehicle_command.param1;
				updated = true;
			}

			if (PX4_ISFINITE(vehicle_command.param2)) {
				actuator_controls.control[6] = vehicle_command.param2;
				updated = true;
			}

			if (PX4_ISFINITE(vehicle_command.param3)) {
				actuator_controls.control[7] = vehicle_command.param3;
				updated = true;
			}

			if (updated) {
				_actuator_controls_pubs[3].publish(actuator_controls);
			}
		}

	} else {
		send_ack = false;

		if (msg->sysid == mavlink_system.sysid && msg->compid == mavlink_system.compid) {
			PX4_WARN("ignoring CMD with same SYS/COMP (%d/%d) ID", mavlink_system.sysid, mavlink_system.compid);
			return;
		}

		if (cmd_mavlink.command == MAV_CMD_LOGGING_START) {
			// check that we have enough bandwidth available: this is given by the configured logger topics
			// and rates. The 5000 is somewhat arbitrary, but makes sure that we cannot enable log streaming
			// on a radio link
			if (_mavlink->get_data_rate() < 5000) {
				send_ack = true;
				result = vehicle_command_ack_s::VEHICLE_RESULT_DENIED;
				_mavlink->send_statustext_critical("Not enough bandwidth to enable log streaming");

			} else {
				// we already instanciate the streaming object, because at this point we know on which
				// mavlink channel streaming was requested. But in fact it's possible that the logger is
				// not even running. The main mavlink thread takes care of this by waiting for an ack
				// from the logger.
				_mavlink->try_start_ulog_streaming(msg->sysid, msg->compid);
			}

		} else if (cmd_mavlink.command == MAV_CMD_LOGGING_STOP) {
			_mavlink->request_stop_ulog_streaming();
		}

		if (!send_ack) {
			_cmd_pub.publish(vehicle_command);
		}
	}

	if (send_ack) {
		acknowledge(msg->sysid, msg->compid, cmd_mavlink.command, result);
	}
}

uint8_t MavlinkReceiver::handle_request_message_command(uint16_t message_id, float param2, float param3, float param4,
		float param5, float param6, float param7)
{
	bool stream_found = false;
	bool message_sent = false;

	for (const auto &stream : _mavlink->get_streams()) {
		if (stream->get_id() == message_id) {
			stream_found = true;
			message_sent = stream->request_message(param2, param3, param4, param5, param6, param7);
			break;
		}
	}

	if (!stream_found) {
		// If we don't find the stream, we can configure it with rate 0 and then trigger it once.
		const char *stream_name = get_stream_name(message_id);

		if (stream_name != nullptr) {
			_mavlink->configure_stream_threadsafe(stream_name, 0.0f);

			// Now we try again to send it.
			for (const auto &stream : _mavlink->get_streams()) {
				if (stream->get_id() == message_id) {
					message_sent = stream->request_message(param2, param3, param4, param5, param6, param7);
					break;
				}
			}
		}
	}

	return (message_sent ? vehicle_command_ack_s::VEHICLE_RESULT_ACCEPTED : vehicle_command_ack_s::VEHICLE_RESULT_DENIED);
}


void
MavlinkReceiver::handle_message_command_ack(mavlink_message_t *msg)
{
	mavlink_command_ack_t ack;
	mavlink_msg_command_ack_decode(msg, &ack);

	MavlinkCommandSender::instance().handle_mavlink_command_ack(ack, msg->sysid, msg->compid, _mavlink->get_channel());

	vehicle_command_ack_s command_ack{};

	command_ack.timestamp = hrt_absolute_time();
	command_ack.result_param2 = ack.result_param2;
	command_ack.command = ack.command;
	command_ack.result = ack.result;
	command_ack.from_external = true;
	command_ack.result_param1 = ack.progress;
	command_ack.target_system = ack.target_system;
	command_ack.target_component = ack.target_component;

	_cmd_ack_pub.publish(command_ack);

	// TODO: move it to the same place that sent the command
	if (ack.result != MAV_RESULT_ACCEPTED && ack.result != MAV_RESULT_IN_PROGRESS) {
		if (msg->compid == MAV_COMP_ID_CAMERA) {
			PX4_WARN("Got unsuccessful result %d from camera", ack.result);
		}
	}
}

void
MavlinkReceiver::handle_message_optical_flow_rad(mavlink_message_t *msg)
{
	/* optical flow */
	mavlink_optical_flow_rad_t flow;
	mavlink_msg_optical_flow_rad_decode(msg, &flow);

	optical_flow_s f{};

	f.timestamp = hrt_absolute_time();
	f.time_since_last_sonar_update = flow.time_delta_distance_us;
	f.integration_timespan  = flow.integration_time_us;
	f.pixel_flow_x_integral = flow.integrated_x;
	f.pixel_flow_y_integral = flow.integrated_y;
	f.gyro_x_rate_integral  = flow.integrated_xgyro;
	f.gyro_y_rate_integral  = flow.integrated_ygyro;
	f.gyro_z_rate_integral  = flow.integrated_zgyro;
	f.gyro_temperature      = flow.temperature;
	f.ground_distance_m     = flow.distance;
	f.quality               = flow.quality;
	f.sensor_id             = flow.sensor_id;
	f.max_flow_rate         = _param_sens_flow_maxr.get();
	f.min_ground_distance   = _param_sens_flow_minhgt.get();
	f.max_ground_distance   = _param_sens_flow_maxhgt.get();

	/* read flow sensor parameters */
	const Rotation flow_rot = (Rotation)_param_sens_flow_rot.get();

	/* rotate measurements according to parameter */
	float zero_val = 0.0f;
	rotate_3f(flow_rot, f.pixel_flow_x_integral, f.pixel_flow_y_integral, zero_val);
	rotate_3f(flow_rot, f.gyro_x_rate_integral, f.gyro_y_rate_integral, f.gyro_z_rate_integral);

	_flow_pub.publish(f);

	/* Use distance value for distance sensor topic */
	if (flow.distance > 0.0f) { // negative values signal invalid data

		distance_sensor_s d{};

		device::Device::DeviceId device_id;
		device_id.devid_s.bus = device::Device::DeviceBusType::DeviceBusType_MAVLINK;
		device_id.devid_s.devtype = DRV_DIST_DEVTYPE_MAVLINK;
		device_id.devid_s.address = msg->sysid;

		d.timestamp = f.timestamp;
		d.min_distance = 0.3f;
		d.max_distance = 5.0f;
		d.current_distance = flow.distance; /* both are in m */
		d.type = distance_sensor_s::MAV_DISTANCE_SENSOR_ULTRASOUND;
		d.device_id = device_id.devid;
		d.orientation = distance_sensor_s::ROTATION_DOWNWARD_FACING;
		d.variance = 0.0;

		_flow_distance_sensor_pub.publish(d);
	}
}

void
MavlinkReceiver::handle_message_hil_optical_flow(mavlink_message_t *msg)
{
	/* optical flow */
	mavlink_hil_optical_flow_t flow;
	mavlink_msg_hil_optical_flow_decode(msg, &flow);

	optical_flow_s f{};

	f.timestamp = hrt_absolute_time(); // XXX we rely on the system time for now and not flow.time_usec;
	f.integration_timespan = flow.integration_time_us;
	f.pixel_flow_x_integral = flow.integrated_x;
	f.pixel_flow_y_integral = flow.integrated_y;
	f.gyro_x_rate_integral = flow.integrated_xgyro;
	f.gyro_y_rate_integral = flow.integrated_ygyro;
	f.gyro_z_rate_integral = flow.integrated_zgyro;
	f.time_since_last_sonar_update = flow.time_delta_distance_us;
	f.ground_distance_m = flow.distance;
	f.quality = flow.quality;
	f.sensor_id = flow.sensor_id;
	f.gyro_temperature = flow.temperature;

	_flow_pub.publish(f);

	/* Use distance value for distance sensor topic */
	distance_sensor_s d{};

	device::Device::DeviceId device_id;
	device_id.devid_s.bus = device::Device::DeviceBusType::DeviceBusType_MAVLINK;
	device_id.devid_s.devtype = DRV_DIST_DEVTYPE_MAVLINK;
	device_id.devid_s.address = msg->sysid;

	d.timestamp = hrt_absolute_time();
	d.min_distance = 0.3f;
	d.max_distance = 5.0f;
	d.current_distance = flow.distance; /* both are in m */
	d.type = distance_sensor_s::MAV_DISTANCE_SENSOR_LASER;
	d.device_id = device_id.devid;
	d.orientation = distance_sensor_s::ROTATION_DOWNWARD_FACING;
	d.variance = 0.0;

	_flow_distance_sensor_pub.publish(d);
}

void
MavlinkReceiver::handle_message_set_mode(mavlink_message_t *msg)
{
	mavlink_set_mode_t new_mode;
	mavlink_msg_set_mode_decode(msg, &new_mode);

	union px4_custom_mode custom_mode;
	custom_mode.data = new_mode.custom_mode;

	vehicle_command_s vcmd{};

	vcmd.timestamp = hrt_absolute_time();

	/* copy the content of mavlink_command_long_t cmd_mavlink into command_t cmd */
	vcmd.param1 = (float)new_mode.base_mode;
	vcmd.param2 = (float)custom_mode.main_mode;
	vcmd.param3 = (float)custom_mode.sub_mode;

	vcmd.command = vehicle_command_s::VEHICLE_CMD_DO_SET_MODE;
	vcmd.target_system = new_mode.target_system;
	vcmd.target_component = MAV_COMP_ID_ALL;
	vcmd.source_system = msg->sysid;
	vcmd.source_component = msg->compid;
	vcmd.confirmation = true;
	vcmd.from_external = true;

	_cmd_pub.publish(vcmd);
}

void
MavlinkReceiver::handle_message_distance_sensor(mavlink_message_t *msg)
{
	mavlink_distance_sensor_t dist_sensor;
	mavlink_msg_distance_sensor_decode(msg, &dist_sensor);

	distance_sensor_s ds{};

	device::Device::DeviceId device_id;
	device_id.devid_s.bus = device::Device::DeviceBusType::DeviceBusType_MAVLINK;
	device_id.devid_s.devtype = DRV_DIST_DEVTYPE_MAVLINK;
	device_id.devid_s.address = dist_sensor.id;

	ds.timestamp        = hrt_absolute_time(); /* Use system time for now, don't trust sender to attach correct timestamp */
	ds.min_distance     = static_cast<float>(dist_sensor.min_distance) * 1e-2f;     /* cm to m */
	ds.max_distance     = static_cast<float>(dist_sensor.max_distance) * 1e-2f;     /* cm to m */
	ds.current_distance = static_cast<float>(dist_sensor.current_distance) * 1e-2f; /* cm to m */
	ds.variance         = dist_sensor.covariance * 1e-4f;                           /* cm^2 to m^2 */
	ds.h_fov            = dist_sensor.horizontal_fov;
	ds.v_fov            = dist_sensor.vertical_fov;
	ds.q[0]             = dist_sensor.quaternion[0];
	ds.q[1]             = dist_sensor.quaternion[1];
	ds.q[2]             = dist_sensor.quaternion[2];
	ds.q[3]             = dist_sensor.quaternion[3];
	ds.type             = dist_sensor.type;
	ds.device_id        = device_id.devid;
	ds.orientation      = dist_sensor.orientation;

	// MAVLink DISTANCE_SENSOR signal_quality value of 0 means unset/unknown
	// quality value. Also it comes normalised between 1 and 100 while the uORB
	// signal quality is normalised between 0 and 100.
	ds.signal_quality = dist_sensor.signal_quality == 0 ? -1 : 100 * (dist_sensor.signal_quality - 1) / 99;

	_distance_sensor_pub.publish(ds);
}

void
MavlinkReceiver::handle_message_att_pos_mocap(mavlink_message_t *msg)
{
	mavlink_att_pos_mocap_t mocap;
	mavlink_msg_att_pos_mocap_decode(msg, &mocap);

	vehicle_odometry_s mocap_odom{};

	mocap_odom.timestamp = hrt_absolute_time();
	mocap_odom.timestamp_sample = _mavlink_timesync.sync_stamp(mocap.time_usec);

	mocap_odom.x = mocap.x;
	mocap_odom.y = mocap.y;
	mocap_odom.z = mocap.z;
	mocap_odom.q[0] = mocap.q[0];
	mocap_odom.q[1] = mocap.q[1];
	mocap_odom.q[2] = mocap.q[2];
	mocap_odom.q[3] = mocap.q[3];

	const size_t URT_SIZE = sizeof(mocap_odom.pose_covariance) / sizeof(mocap_odom.pose_covariance[0]);
	static_assert(URT_SIZE == (sizeof(mocap.covariance) / sizeof(mocap.covariance[0])),
		      "Odometry Pose Covariance matrix URT array size mismatch");

	for (size_t i = 0; i < URT_SIZE; i++) {
		mocap_odom.pose_covariance[i] = mocap.covariance[i];
	}

	mocap_odom.velocity_frame = vehicle_odometry_s::LOCAL_FRAME_FRD;
	mocap_odom.vx = NAN;
	mocap_odom.vy = NAN;
	mocap_odom.vz = NAN;
	mocap_odom.rollspeed = NAN;
	mocap_odom.pitchspeed = NAN;
	mocap_odom.yawspeed = NAN;
	mocap_odom.velocity_covariance[0] = NAN;

	_mocap_odometry_pub.publish(mocap_odom);
}

void
MavlinkReceiver::handle_message_set_position_target_local_ned(mavlink_message_t *msg)
{
	mavlink_set_position_target_local_ned_t target_local_ned;
	mavlink_msg_set_position_target_local_ned_decode(msg, &target_local_ned);

	/* Only accept messages which are intended for this system */
	if (_mavlink->get_forward_externalsp() &&
	    (mavlink_system.sysid == target_local_ned.target_system || target_local_ned.target_system == 0) &&
	    (mavlink_system.compid == target_local_ned.target_component || target_local_ned.target_component == 0)) {

		vehicle_local_position_setpoint_s setpoint{};

		const uint16_t type_mask = target_local_ned.type_mask;

		if (target_local_ned.coordinate_frame == MAV_FRAME_LOCAL_NED) {
			setpoint.x = (type_mask & POSITION_TARGET_TYPEMASK_X_IGNORE) ? NAN : target_local_ned.x;
			setpoint.y = (type_mask & POSITION_TARGET_TYPEMASK_Y_IGNORE) ? NAN : target_local_ned.y;
			setpoint.z = (type_mask & POSITION_TARGET_TYPEMASK_Z_IGNORE) ? NAN : target_local_ned.z;

			setpoint.vx = (type_mask & POSITION_TARGET_TYPEMASK_VX_IGNORE) ? NAN : target_local_ned.vx;
			setpoint.vy = (type_mask & POSITION_TARGET_TYPEMASK_VY_IGNORE) ? NAN : target_local_ned.vy;
			setpoint.vz = (type_mask & POSITION_TARGET_TYPEMASK_VZ_IGNORE) ? NAN : target_local_ned.vz;

			setpoint.acceleration[0] = (type_mask & POSITION_TARGET_TYPEMASK_AX_IGNORE) ? NAN : target_local_ned.afx;
			setpoint.acceleration[1] = (type_mask & POSITION_TARGET_TYPEMASK_AY_IGNORE) ? NAN : target_local_ned.afy;
			setpoint.acceleration[2] = (type_mask & POSITION_TARGET_TYPEMASK_AZ_IGNORE) ? NAN : target_local_ned.afz;

		} else if (target_local_ned.coordinate_frame == MAV_FRAME_BODY_NED) {

			vehicle_attitude_s vehicle_attitude{};
			_vehicle_attitude_sub.copy(&vehicle_attitude);
			const matrix::Dcmf R{matrix::Quatf{vehicle_attitude.q}};

			const bool ignore_velocity = type_mask & (POSITION_TARGET_TYPEMASK_VX_IGNORE | POSITION_TARGET_TYPEMASK_VY_IGNORE |
						     POSITION_TARGET_TYPEMASK_VZ_IGNORE);

			if (!ignore_velocity) {
				const matrix::Vector3f velocity_body_sp{
					(type_mask & POSITION_TARGET_TYPEMASK_VX_IGNORE) ? 0.f : target_local_ned.vx,
					(type_mask & POSITION_TARGET_TYPEMASK_VY_IGNORE) ? 0.f : target_local_ned.vy,
					(type_mask & POSITION_TARGET_TYPEMASK_VZ_IGNORE) ? 0.f : target_local_ned.vz
				};

				const matrix::Vector3f velocity_setpoint{R * velocity_body_sp};
				setpoint.vx = velocity_setpoint(0);
				setpoint.vy = velocity_setpoint(1);
				setpoint.vz = velocity_setpoint(2);

			} else {
				setpoint.vx = NAN;
				setpoint.vy = NAN;
				setpoint.vz = NAN;
			}

			const bool ignore_acceleration = type_mask & (POSITION_TARGET_TYPEMASK_AX_IGNORE | POSITION_TARGET_TYPEMASK_AY_IGNORE |
							 POSITION_TARGET_TYPEMASK_AZ_IGNORE);

			if (!ignore_acceleration) {
				const matrix::Vector3f acceleration_body_sp{
					(type_mask & POSITION_TARGET_TYPEMASK_AX_IGNORE) ? 0.f : target_local_ned.afx,
					(type_mask & POSITION_TARGET_TYPEMASK_AY_IGNORE) ? 0.f : target_local_ned.afy,
					(type_mask & POSITION_TARGET_TYPEMASK_AZ_IGNORE) ? 0.f : target_local_ned.afz
				};

				const matrix::Vector3f acceleration_setpoint{R * acceleration_body_sp};
				acceleration_setpoint.copyTo(setpoint.acceleration);

			} else {
				setpoint.acceleration[0] = NAN;
				setpoint.acceleration[1] = NAN;
				setpoint.acceleration[2] = NAN;
			}

			setpoint.x = NAN;
			setpoint.y = NAN;
			setpoint.z = NAN;

		} else {
			mavlink_log_critical(&_mavlink_log_pub, "SET_POSITION_TARGET_LOCAL_NED coordinate frame %d unsupported",
					     target_local_ned.coordinate_frame);
			return;
		}

		setpoint.thrust[0] = NAN;
		setpoint.thrust[1] = NAN;
		setpoint.thrust[2] = NAN;

		setpoint.yaw      = (type_mask & POSITION_TARGET_TYPEMASK_YAW_IGNORE)      ? NAN : target_local_ned.yaw;
		setpoint.yawspeed = (type_mask & POSITION_TARGET_TYPEMASK_YAW_RATE_IGNORE) ? NAN : target_local_ned.yaw_rate;


		offboard_control_mode_s ocm{};
		ocm.position = PX4_ISFINITE(setpoint.x) || PX4_ISFINITE(setpoint.y) || PX4_ISFINITE(setpoint.z);
		ocm.velocity = PX4_ISFINITE(setpoint.vx) || PX4_ISFINITE(setpoint.vy) || PX4_ISFINITE(setpoint.vz);
		ocm.acceleration = PX4_ISFINITE(setpoint.acceleration[0]) || PX4_ISFINITE(setpoint.acceleration[1])
				   || PX4_ISFINITE(setpoint.acceleration[2]);

		if (ocm.acceleration && (type_mask & POSITION_TARGET_TYPEMASK_FORCE_SET)) {
			mavlink_log_critical(&_mavlink_log_pub, "SET_POSITION_TARGET_LOCAL_NED force not supported");
			return;
		}

		if (ocm.position || ocm.velocity || ocm.acceleration) {
			// publish offboard_control_mode
			ocm.timestamp = hrt_absolute_time();
			_offboard_control_mode_pub.publish(ocm);

			vehicle_status_s vehicle_status{};
			_vehicle_status_sub.copy(&vehicle_status);

			if (vehicle_status.nav_state == vehicle_status_s::NAVIGATION_STATE_OFFBOARD) {
				// only publish setpoint once in OFFBOARD
				setpoint.timestamp = hrt_absolute_time();
				_trajectory_setpoint_pub.publish(setpoint);
			}

		} else {
			mavlink_log_critical(&_mavlink_log_pub, "SET_POSITION_TARGET_LOCAL_NED invalid");
		}
	}
}

void
MavlinkReceiver::handle_message_set_position_target_global_int(mavlink_message_t *msg)
{
	mavlink_set_position_target_global_int_t target_global_int;
	mavlink_msg_set_position_target_global_int_decode(msg, &target_global_int);

	/* Only accept messages which are intended for this system */
	if (_mavlink->get_forward_externalsp() &&
	    (mavlink_system.sysid == target_global_int.target_system || target_global_int.target_system == 0) &&
	    (mavlink_system.compid == target_global_int.target_component || target_global_int.target_component == 0)) {

		vehicle_local_position_setpoint_s setpoint{};

		const uint16_t type_mask = target_global_int.type_mask;

		// position
		if (!(type_mask & (POSITION_TARGET_TYPEMASK_X_IGNORE | POSITION_TARGET_TYPEMASK_Y_IGNORE |
				   POSITION_TARGET_TYPEMASK_Z_IGNORE))) {

			vehicle_local_position_s local_pos{};
			_vehicle_local_position_sub.copy(&local_pos);

			if (!local_pos.xy_global || !local_pos.z_global) {
				return;
			}

			map_projection_reference_s global_local_proj_ref{};
			map_projection_init_timestamped(&global_local_proj_ref, local_pos.ref_lat, local_pos.ref_lon, local_pos.ref_timestamp);

			// global -> local
			const double lat = target_global_int.lat_int / 1e7;
			const double lon = target_global_int.lon_int / 1e7;
			map_projection_project(&global_local_proj_ref, lat, lon, &setpoint.x, &setpoint.y);

			if (target_global_int.coordinate_frame == MAV_FRAME_GLOBAL_INT) {
				setpoint.z = local_pos.ref_alt - target_global_int.alt;

			} else if (target_global_int.coordinate_frame == MAV_FRAME_GLOBAL_RELATIVE_ALT_INT) {
				home_position_s home_position{};
				_home_position_sub.copy(&home_position);

				if (home_position.valid_alt) {
					const float alt = home_position.alt - target_global_int.alt;
					setpoint.z = alt - local_pos.ref_alt;

				} else {
					// home altitude required
					return;
				}

			} else if (target_global_int.coordinate_frame == MAV_FRAME_GLOBAL_TERRAIN_ALT_INT) {
				vehicle_global_position_s vehicle_global_position{};
				_vehicle_global_position_sub.copy(&vehicle_global_position);

				if (vehicle_global_position.terrain_alt_valid) {
					const float alt = target_global_int.alt + vehicle_global_position.terrain_alt;
					setpoint.z = local_pos.ref_alt - alt;

				} else {
					// valid terrain alt required
					return;
				}

			} else {
				mavlink_log_critical(&_mavlink_log_pub, "SET_POSITION_TARGET_GLOBAL_INT invalid coordinate frame %d",
						     target_global_int.coordinate_frame);
				return;
			}

		} else {
			setpoint.x = NAN;
			setpoint.y = NAN;
			setpoint.z = NAN;
		}

		// velocity
		setpoint.vx = (type_mask & POSITION_TARGET_TYPEMASK_VX_IGNORE) ? NAN : target_global_int.vx;
		setpoint.vy = (type_mask & POSITION_TARGET_TYPEMASK_VY_IGNORE) ? NAN : target_global_int.vy;
		setpoint.vz = (type_mask & POSITION_TARGET_TYPEMASK_VZ_IGNORE) ? NAN : target_global_int.vz;

		// acceleration
		setpoint.acceleration[0] = (type_mask & POSITION_TARGET_TYPEMASK_AX_IGNORE) ? NAN : target_global_int.afx;
		setpoint.acceleration[1] = (type_mask & POSITION_TARGET_TYPEMASK_AY_IGNORE) ? NAN : target_global_int.afy;
		setpoint.acceleration[2] = (type_mask & POSITION_TARGET_TYPEMASK_AZ_IGNORE) ? NAN : target_global_int.afz;

		setpoint.thrust[0] = NAN;
		setpoint.thrust[1] = NAN;
		setpoint.thrust[2] = NAN;

		setpoint.yaw      = (type_mask & POSITION_TARGET_TYPEMASK_YAW_IGNORE)      ? NAN : target_global_int.yaw;
		setpoint.yawspeed = (type_mask & POSITION_TARGET_TYPEMASK_YAW_RATE_IGNORE) ? NAN : target_global_int.yaw_rate;


		offboard_control_mode_s ocm{};
		ocm.position = PX4_ISFINITE(setpoint.x) || PX4_ISFINITE(setpoint.y) || PX4_ISFINITE(setpoint.z);
		ocm.velocity = PX4_ISFINITE(setpoint.vx) || PX4_ISFINITE(setpoint.vy) || PX4_ISFINITE(setpoint.vz);
		ocm.acceleration = PX4_ISFINITE(setpoint.acceleration[0]) || PX4_ISFINITE(setpoint.acceleration[1])
				   || PX4_ISFINITE(setpoint.acceleration[2]);

		if (ocm.acceleration && (type_mask & POSITION_TARGET_TYPEMASK_FORCE_SET)) {
			mavlink_log_critical(&_mavlink_log_pub, "SET_POSITION_TARGET_LOCAL_NED force not supported");
			return;
		}

		if (ocm.position || ocm.velocity || ocm.acceleration) {
			// publish offboard_control_mode
			ocm.timestamp = hrt_absolute_time();
			_offboard_control_mode_pub.publish(ocm);

			vehicle_status_s vehicle_status{};
			_vehicle_status_sub.copy(&vehicle_status);

			if (vehicle_status.nav_state == vehicle_status_s::NAVIGATION_STATE_OFFBOARD) {
				// only publish setpoint once in OFFBOARD
				setpoint.timestamp = hrt_absolute_time();
				_trajectory_setpoint_pub.publish(setpoint);
			}
		}
	}
}

void
MavlinkReceiver::handle_message_set_actuator_control_target(mavlink_message_t *msg)
{
	// TODO
#if defined(ENABLE_LOCKSTEP_SCHEDULER)
	PX4_ERR("SET_ACTUATOR_CONTROL_TARGET not supported with lockstep enabled");
	PX4_ERR("Please disable lockstep for actuator offboard control:");
	PX4_ERR("https://dev.px4.io/master/en/simulation/#disable-lockstep-simulation");
	return;
#endif

	mavlink_set_actuator_control_target_t actuator_target;
	mavlink_msg_set_actuator_control_target_decode(msg, &actuator_target);

	if (_mavlink->get_forward_externalsp() &&
	    (mavlink_system.sysid == actuator_target.target_system || actuator_target.target_system == 0) &&
	    (mavlink_system.compid == actuator_target.target_component || actuator_target.target_component == 0)
	   ) {
		/* Ignore all setpoints except when controlling the gimbal(group_mlx==2) as we are setting raw actuators here */
		//bool ignore_setpoints = bool(actuator_target.group_mlx != 2);

		offboard_control_mode_s offboard_control_mode{};
		offboard_control_mode.timestamp = hrt_absolute_time();
		_offboard_control_mode_pub.publish(offboard_control_mode);

		vehicle_status_s vehicle_status{};
		_vehicle_status_sub.copy(&vehicle_status);

		// Publish actuator controls only once in OFFBOARD
		if (vehicle_status.nav_state == vehicle_status_s::NAVIGATION_STATE_OFFBOARD) {

			actuator_controls_s actuator_controls{};
			actuator_controls.timestamp = hrt_absolute_time();

			/* Set duty cycles for the servos in the actuator_controls message */
			for (size_t i = 0; i < 8; i++) {
				actuator_controls.control[i] = actuator_target.controls[i];
			}

			switch (actuator_target.group_mlx) {
			case 0:
				_actuator_controls_pubs[0].publish(actuator_controls);
				break;

			case 1:
				_actuator_controls_pubs[1].publish(actuator_controls);
				break;

			case 2:
				_actuator_controls_pubs[2].publish(actuator_controls);
				break;

			case 3:
				_actuator_controls_pubs[3].publish(actuator_controls);
				break;

			default:
				break;
			}
		}
	}
}

void
MavlinkReceiver::handle_message_set_gps_global_origin(mavlink_message_t *msg)
{
	mavlink_set_gps_global_origin_t gps_global_origin;
	mavlink_msg_set_gps_global_origin_decode(msg, &gps_global_origin);

	if (gps_global_origin.target_system == _mavlink->get_system_id()) {
		vehicle_command_s vcmd{};
		vcmd.param5 = (double)gps_global_origin.latitude * 1.e-7;
		vcmd.param6 = (double)gps_global_origin.longitude * 1.e-7;
		vcmd.param7 = (float)gps_global_origin.altitude * 1.e-3f;
		vcmd.command = vehicle_command_s::VEHICLE_CMD_SET_GPS_GLOBAL_ORIGIN;
		vcmd.target_system = _mavlink->get_system_id();
		vcmd.target_component = MAV_COMP_ID_ALL;
		vcmd.source_system = msg->sysid;
		vcmd.source_component = msg->compid;
		vcmd.confirmation = false;
		vcmd.from_external = true;
		vcmd.timestamp = hrt_absolute_time();
		_cmd_pub.publish(vcmd);
	}

	handle_request_message_command(MAVLINK_MSG_ID_GPS_GLOBAL_ORIGIN);
}

void
MavlinkReceiver::handle_message_vision_position_estimate(mavlink_message_t *msg)
{
	mavlink_vision_position_estimate_t ev;
	mavlink_msg_vision_position_estimate_decode(msg, &ev);

	vehicle_odometry_s visual_odom{};

	visual_odom.timestamp = hrt_absolute_time();
	visual_odom.timestamp_sample = _mavlink_timesync.sync_stamp(ev.usec);

	visual_odom.x = ev.x;
	visual_odom.y = ev.y;
	visual_odom.z = ev.z;
	matrix::Quatf q(matrix::Eulerf(ev.roll, ev.pitch, ev.yaw));
	q.copyTo(visual_odom.q);

	visual_odom.local_frame = vehicle_odometry_s::LOCAL_FRAME_NED;

	const size_t URT_SIZE = sizeof(visual_odom.pose_covariance) / sizeof(visual_odom.pose_covariance[0]);
	static_assert(URT_SIZE == (sizeof(ev.covariance) / sizeof(ev.covariance[0])),
		      "Odometry Pose Covariance matrix URT array size mismatch");

	for (size_t i = 0; i < URT_SIZE; i++) {
		visual_odom.pose_covariance[i] = ev.covariance[i];
	}

	visual_odom.velocity_frame = vehicle_odometry_s::LOCAL_FRAME_FRD;
	visual_odom.vx = NAN;
	visual_odom.vy = NAN;
	visual_odom.vz = NAN;
	visual_odom.rollspeed = NAN;
	visual_odom.pitchspeed = NAN;
	visual_odom.yawspeed = NAN;
	visual_odom.velocity_covariance[0] = NAN;

	_visual_odometry_pub.publish(visual_odom);
}

void
MavlinkReceiver::handle_message_odometry(mavlink_message_t *msg)
{
	mavlink_odometry_t odom;
	mavlink_msg_odometry_decode(msg, &odom);

	vehicle_odometry_s odometry{};

	odometry.timestamp = hrt_absolute_time();
	odometry.timestamp_sample = _mavlink_timesync.sync_stamp(odom.time_usec);

	/* The position is in a local FRD frame */
	odometry.x = odom.x;
	odometry.y = odom.y;
	odometry.z = odom.z;

	/**
	 * The quaternion of the ODOMETRY msg represents a rotation from body frame
	 * to a local frame
	 */
	matrix::Quatf q_body_to_local(odom.q);
	q_body_to_local.normalize();
	q_body_to_local.copyTo(odometry.q);

	// pose_covariance
	static constexpr size_t POS_URT_SIZE = sizeof(odometry.pose_covariance) / sizeof(odometry.pose_covariance[0]);
	static_assert(POS_URT_SIZE == (sizeof(odom.pose_covariance) / sizeof(odom.pose_covariance[0])),
		      "Odometry Pose Covariance matrix URT array size mismatch");

	// velocity_covariance
	static constexpr size_t VEL_URT_SIZE = sizeof(odometry.velocity_covariance) / sizeof(odometry.velocity_covariance[0]);
	static_assert(VEL_URT_SIZE == (sizeof(odom.velocity_covariance) / sizeof(odom.velocity_covariance[0])),
		      "Odometry Velocity Covariance matrix URT array size mismatch");

	// TODO: create a method to simplify covariance copy
	for (size_t i = 0; i < POS_URT_SIZE; i++) {
		odometry.pose_covariance[i] = odom.pose_covariance[i];
	}

	/**
	 * PX4 expects the body's linear velocity in the local frame,
	 * the linear velocity is rotated from the odom child_frame to the
	 * local NED frame. The angular velocity needs to be expressed in the
	 * body (fcu_frd) frame.
	 */
	if (odom.child_frame_id == MAV_FRAME_BODY_FRD) {

		odometry.velocity_frame = vehicle_odometry_s::BODY_FRAME_FRD;
		odometry.vx = odom.vx;
		odometry.vy = odom.vy;
		odometry.vz = odom.vz;

		odometry.rollspeed = odom.rollspeed;
		odometry.pitchspeed = odom.pitchspeed;
		odometry.yawspeed = odom.yawspeed;

		for (size_t i = 0; i < VEL_URT_SIZE; i++) {
			odometry.velocity_covariance[i] = odom.velocity_covariance[i];
		}

	} else {
		PX4_ERR("Body frame %u not supported. Unable to publish velocity", odom.child_frame_id);
	}

	/**
	 * Supported local frame of reference is MAV_FRAME_LOCAL_NED or MAV_FRAME_LOCAL_FRD
	 * The supported sources of the data/tesimator type are MAV_ESTIMATOR_TYPE_VISION,
	 * MAV_ESTIMATOR_TYPE_VIO and MAV_ESTIMATOR_TYPE_MOCAP
	 *
	 * @note Regarding the local frames of reference, the appropriate EKF_AID_MASK
	 * should be set in order to match a frame aligned (NED) or not aligned (FRD)
	 * with true North
	 */
	if (odom.frame_id == MAV_FRAME_LOCAL_NED || odom.frame_id == MAV_FRAME_LOCAL_FRD) {

		if (odom.frame_id == MAV_FRAME_LOCAL_NED) {
			odometry.local_frame = vehicle_odometry_s::LOCAL_FRAME_NED;

		} else {
			odometry.local_frame = vehicle_odometry_s::LOCAL_FRAME_FRD;
		}

		if ((odom.estimator_type == MAV_ESTIMATOR_TYPE_VISION)
		    || (odom.estimator_type == MAV_ESTIMATOR_TYPE_VIO)
		    || (odom.estimator_type == MAV_ESTIMATOR_TYPE_UNKNOWN)) {
			// accept MAV_ESTIMATOR_TYPE_UNKNOWN for legacy support
			_visual_odometry_pub.publish(odometry);

		} else if (odom.estimator_type == MAV_ESTIMATOR_TYPE_MOCAP) {
			_mocap_odometry_pub.publish(odometry);

		} else {
			PX4_ERR("Estimator source %u not supported. Unable to publish pose and velocity", odom.estimator_type);
		}

	} else {
		PX4_ERR("Local frame %u not supported. Unable to publish pose and velocity", odom.frame_id);
	}
}

void MavlinkReceiver::fill_thrust(float *thrust_body_array, uint8_t vehicle_type, float thrust)
{
	// Fill correct field by checking frametype
	// TODO: add as needed
	switch (_mavlink->get_system_type()) {
	case MAV_TYPE_GENERIC:
		break;

	case MAV_TYPE_FIXED_WING:
	case MAV_TYPE_GROUND_ROVER:
		thrust_body_array[0] = thrust;
		break;

	case MAV_TYPE_QUADROTOR:
	case MAV_TYPE_HEXAROTOR:
	case MAV_TYPE_OCTOROTOR:
	case MAV_TYPE_TRICOPTER:
	case MAV_TYPE_HELICOPTER:
	case MAV_TYPE_COAXIAL:
		thrust_body_array[2] = -thrust;
		break;

	case MAV_TYPE_SUBMARINE:
		thrust_body_array[0] = thrust;
		break;

	case MAV_TYPE_VTOL_DUOROTOR:
	case MAV_TYPE_VTOL_QUADROTOR:
	case MAV_TYPE_VTOL_TILTROTOR:
	case MAV_TYPE_VTOL_RESERVED2:
	case MAV_TYPE_VTOL_RESERVED3:
	case MAV_TYPE_VTOL_RESERVED4:
	case MAV_TYPE_VTOL_RESERVED5:
		switch (vehicle_type) {
		case vehicle_status_s::VEHICLE_TYPE_FIXED_WING:
			thrust_body_array[0] = thrust;

			break;

		case vehicle_status_s::VEHICLE_TYPE_ROTARY_WING:
			thrust_body_array[2] = -thrust;

			break;

		default:
			// This should never happen
			break;
		}

		break;
	}
}

void
MavlinkReceiver::handle_message_set_attitude_target(mavlink_message_t *msg)
{
	mavlink_set_attitude_target_t attitude_target;
	mavlink_msg_set_attitude_target_decode(msg, &attitude_target);

	/* Only accept messages which are intended for this system */
	if (_mavlink->get_forward_externalsp() &&
	    (mavlink_system.sysid == attitude_target.target_system || attitude_target.target_system == 0) &&
	    (mavlink_system.compid == attitude_target.target_component || attitude_target.target_component == 0)) {

		const uint8_t type_mask = attitude_target.type_mask;

		const bool attitude = !(type_mask & ATTITUDE_TARGET_TYPEMASK_ATTITUDE_IGNORE);
		const bool body_rates = !(type_mask & ATTITUDE_TARGET_TYPEMASK_BODY_ROLL_RATE_IGNORE)
					&& !(type_mask & ATTITUDE_TARGET_TYPEMASK_BODY_PITCH_RATE_IGNORE);

		vehicle_status_s vehicle_status{};
		_vehicle_status_sub.copy(&vehicle_status);

		if (attitude) {
			vehicle_attitude_setpoint_s attitude_setpoint{};

			const matrix::Quatf q{attitude_target.q};
			q.copyTo(attitude_setpoint.q_d);

			matrix::Eulerf euler{q};
			attitude_setpoint.roll_body = euler.phi();
			attitude_setpoint.pitch_body = euler.theta();
			attitude_setpoint.yaw_body = euler.psi();

			// TODO: review use case
			attitude_setpoint.yaw_sp_move_rate = (type_mask & ATTITUDE_TARGET_TYPEMASK_BODY_YAW_RATE_IGNORE) ?
							     NAN : attitude_target.body_yaw_rate;

			if (!(attitude_target.type_mask & ATTITUDE_TARGET_TYPEMASK_THROTTLE_IGNORE)) {
				fill_thrust(attitude_setpoint.thrust_body, vehicle_status.vehicle_type, attitude_target.thrust);
			}

			// publish offboard_control_mode
			offboard_control_mode_s ocm{};
			ocm.attitude = true;
			ocm.timestamp = hrt_absolute_time();
			_offboard_control_mode_pub.publish(ocm);

			// Publish attitude setpoint only once in OFFBOARD
			if (vehicle_status.nav_state == vehicle_status_s::NAVIGATION_STATE_OFFBOARD) {
				attitude_setpoint.timestamp = hrt_absolute_time();

				if (vehicle_status.is_vtol && (vehicle_status.vehicle_type == vehicle_status_s::VEHICLE_TYPE_ROTARY_WING)) {
					_mc_virtual_att_sp_pub.publish(attitude_setpoint);

				} else if (vehicle_status.is_vtol && (vehicle_status.vehicle_type == vehicle_status_s::VEHICLE_TYPE_FIXED_WING)) {
					_fw_virtual_att_sp_pub.publish(attitude_setpoint);

				} else {
					_att_sp_pub.publish(attitude_setpoint);
				}
			}

		} else if (body_rates) {
			vehicle_rates_setpoint_s setpoint{};
			setpoint.roll  = (type_mask & ATTITUDE_TARGET_TYPEMASK_BODY_ROLL_RATE_IGNORE)  ? NAN : attitude_target.body_roll_rate;
			setpoint.pitch = (type_mask & ATTITUDE_TARGET_TYPEMASK_BODY_PITCH_RATE_IGNORE) ? NAN : attitude_target.body_pitch_rate;
			setpoint.yaw   = (type_mask & ATTITUDE_TARGET_TYPEMASK_BODY_YAW_RATE_IGNORE)   ? NAN : attitude_target.body_yaw_rate;

			if (!(attitude_target.type_mask & ATTITUDE_TARGET_TYPEMASK_THROTTLE_IGNORE)) {
				fill_thrust(setpoint.thrust_body, vehicle_status.vehicle_type, attitude_target.thrust);
			}

			// publish offboard_control_mode
			offboard_control_mode_s ocm{};
			ocm.body_rate = true;
			ocm.timestamp = hrt_absolute_time();
			_offboard_control_mode_pub.publish(ocm);

			// Publish rate setpoint only once in OFFBOARD
			if (vehicle_status.nav_state == vehicle_status_s::NAVIGATION_STATE_OFFBOARD) {
				setpoint.timestamp = hrt_absolute_time();
				_rates_sp_pub.publish(setpoint);
			}
		}
	}
}

void
MavlinkReceiver::handle_message_radio_status(mavlink_message_t *msg)
{
	/* telemetry status supported only on first ORB_MULTI_MAX_INSTANCES mavlink channels */
	if (_mavlink->get_channel() < (mavlink_channel_t)ORB_MULTI_MAX_INSTANCES) {
		mavlink_radio_status_t rstatus;
		mavlink_msg_radio_status_decode(msg, &rstatus);

		radio_status_s status{};

		status.timestamp = hrt_absolute_time();
		status.rssi = rstatus.rssi;
		status.remote_rssi = rstatus.remrssi;
		status.txbuf = rstatus.txbuf;
		status.noise = rstatus.noise;
		status.remote_noise = rstatus.remnoise;
		status.rxerrors = rstatus.rxerrors;
		status.fix = rstatus.fixed;

		_mavlink->update_radio_status(status);

		_radio_status_pub.publish(status);
	}
}

void
MavlinkReceiver::handle_message_ping(mavlink_message_t *msg)
{
	mavlink_ping_t ping;
	mavlink_msg_ping_decode(msg, &ping);

	if ((ping.target_system == 0) &&
	    (ping.target_component == 0)) {	   // This is a ping request. Return it to the system which requested the ping.

		ping.target_system = msg->sysid;
		ping.target_component = msg->compid;
		mavlink_msg_ping_send_struct(_mavlink->get_channel(), &ping);

	} else if ((ping.target_system == mavlink_system.sysid) &&
		   (ping.target_component ==
		    mavlink_system.compid)) { // This is a returned ping message from this system. Calculate latency from it.

		const hrt_abstime now = hrt_absolute_time();

		// Calculate round trip time
		float rtt_ms = (now - ping.time_usec) / 1000.0f;

		// Update ping statistics
		struct Mavlink::ping_statistics_s &pstats = _mavlink->get_ping_statistics();

		pstats.last_ping_time = now;

		if (pstats.last_ping_seq == 0 && ping.seq > 0) {
			// This is the first reply we are receiving from an offboard system.
			// We may have been broadcasting pings for some time before it came online,
			// and these do not count as dropped packets.

			// Reset last_ping_seq counter for correct packet drop detection
			pstats.last_ping_seq = ping.seq - 1;
		}

		// We can only count dropped packets after the first message
		if (ping.seq > pstats.last_ping_seq) {
			pstats.dropped_packets += ping.seq - pstats.last_ping_seq - 1;
		}

		pstats.last_ping_seq = ping.seq;
		pstats.last_rtt = rtt_ms;
		pstats.mean_rtt = (rtt_ms + pstats.mean_rtt) / 2.0f;
		pstats.max_rtt = fmaxf(rtt_ms, pstats.max_rtt);
		pstats.min_rtt = pstats.min_rtt > 0.0f ? fminf(rtt_ms, pstats.min_rtt) : rtt_ms;

		/* Ping status is supported only on first ORB_MULTI_MAX_INSTANCES mavlink channels */
		if (_mavlink->get_channel() < (mavlink_channel_t)ORB_MULTI_MAX_INSTANCES) {

			ping_s uorb_ping_msg{};

			uorb_ping_msg.timestamp = now;
			uorb_ping_msg.ping_time = ping.time_usec;
			uorb_ping_msg.ping_sequence = ping.seq;
			uorb_ping_msg.dropped_packets = pstats.dropped_packets;
			uorb_ping_msg.rtt_ms = rtt_ms;
			uorb_ping_msg.system_id = msg->sysid;
			uorb_ping_msg.component_id = msg->compid;

			_ping_pub.publish(uorb_ping_msg);
		}
	}
}

void
MavlinkReceiver::handle_message_battery_status(mavlink_message_t *msg)
{
	if ((msg->sysid != mavlink_system.sysid) || (msg->compid == mavlink_system.compid)) {
		// ignore battery status coming from other systems or from the autopilot itself
		return;
	}

	// external battery measurements
	mavlink_battery_status_t battery_mavlink;
	mavlink_msg_battery_status_decode(msg, &battery_mavlink);

	battery_status_s battery_status{};
	battery_status.timestamp = hrt_absolute_time();

	float voltage_sum = 0.0f;
	uint8_t cell_count = 0;

	while (battery_mavlink.voltages[cell_count] < UINT16_MAX && cell_count < 10) {
		battery_status.voltage_cell_v[cell_count] = (float)(battery_mavlink.voltages[cell_count]) / 1000.0f;
		voltage_sum += battery_status.voltage_cell_v[cell_count];
		cell_count++;
	}

	battery_status.voltage_v = voltage_sum;
	battery_status.voltage_filtered_v  = voltage_sum;
	battery_status.current_a = battery_status.current_filtered_a = (float)(battery_mavlink.current_battery) / 100.0f;
	battery_status.current_filtered_a = battery_status.current_a;
	battery_status.remaining = (float)battery_mavlink.battery_remaining / 100.0f;
	battery_status.discharged_mah = (float)battery_mavlink.current_consumed;
	battery_status.cell_count = cell_count;
	battery_status.temperature = (float)battery_mavlink.temperature;
	battery_status.connected = true;

	// Set the battery warning based on remaining charge.
	//  Note: Smallest values must come first in evaluation.
	if (battery_status.remaining < _param_bat_emergen_thr.get()) {
		battery_status.warning = battery_status_s::BATTERY_WARNING_EMERGENCY;

	} else if (battery_status.remaining < _param_bat_crit_thr.get()) {
		battery_status.warning = battery_status_s::BATTERY_WARNING_CRITICAL;

	} else if (battery_status.remaining < _param_bat_low_thr.get()) {
		battery_status.warning = battery_status_s::BATTERY_WARNING_LOW;
	}

	_battery_pub.publish(battery_status);
}

void
MavlinkReceiver::handle_message_serial_control(mavlink_message_t *msg)
{
	mavlink_serial_control_t serial_control_mavlink;
	mavlink_msg_serial_control_decode(msg, &serial_control_mavlink);

	// we only support shell commands
	if (serial_control_mavlink.device != SERIAL_CONTROL_DEV_SHELL
	    || (serial_control_mavlink.flags & SERIAL_CONTROL_FLAG_REPLY)) {
		return;
	}

	MavlinkShell *shell = _mavlink->get_shell();

	if (shell) {
		// we ignore the timeout, EXCLUSIVE & BLOCKING flags of the SERIAL_CONTROL message
		if (serial_control_mavlink.count > 0) {
			shell->write(serial_control_mavlink.data, serial_control_mavlink.count);
		}

		// if no response requested, assume the shell is no longer used
		if ((serial_control_mavlink.flags & SERIAL_CONTROL_FLAG_RESPOND) == 0) {
			_mavlink->close_shell();
		}
	}
}

void
MavlinkReceiver::handle_message_logging_ack(mavlink_message_t *msg)
{
	mavlink_logging_ack_t logging_ack;
	mavlink_msg_logging_ack_decode(msg, &logging_ack);

	MavlinkULog *ulog_streaming = _mavlink->get_ulog_streaming();

	if (ulog_streaming) {
		ulog_streaming->handle_ack(logging_ack);
	}
}

void
MavlinkReceiver::handle_message_play_tune(mavlink_message_t *msg)
{
	mavlink_play_tune_t play_tune;
	mavlink_msg_play_tune_decode(msg, &play_tune);

	if ((mavlink_system.sysid == play_tune.target_system || play_tune.target_system == 0) &&
	    (mavlink_system.compid == play_tune.target_component || play_tune.target_component == 0)) {

		// Let's make sure the input is 0 terminated, so we don't ever overrun it.
		play_tune.tune2[sizeof(play_tune.tune2) - 1] = '\0';

		schedule_tune(play_tune.tune);
	}
}

void
MavlinkReceiver::handle_message_play_tune_v2(mavlink_message_t *msg)
{
	mavlink_play_tune_v2_t play_tune_v2;
	mavlink_msg_play_tune_v2_decode(msg, &play_tune_v2);

	if ((mavlink_system.sysid == play_tune_v2.target_system || play_tune_v2.target_system == 0) &&
	    (mavlink_system.compid == play_tune_v2.target_component || play_tune_v2.target_component == 0)) {

		if (play_tune_v2.format != TUNE_FORMAT_QBASIC1_1) {
			PX4_ERR("Tune format %d not supported", play_tune_v2.format);
			return;
		}

		// Let's make sure the input is 0 terminated, so we don't ever overrun it.
		play_tune_v2.tune[sizeof(play_tune_v2.tune) - 1] = '\0';

		schedule_tune(play_tune_v2.tune);
	}
}

void MavlinkReceiver::schedule_tune(const char *tune)
{
	// We only allocate the TunePublisher object if we ever use it but we
	// don't remove it to avoid fragmentation over time.
	if (_tune_publisher == nullptr) {
		_tune_publisher = new TunePublisher();

		if (_tune_publisher == nullptr) {
			PX4_ERR("Could not allocate tune publisher");
			return;
		}
	}

	const hrt_abstime now = hrt_absolute_time();

	_tune_publisher->set_tune_string(tune, now);
	// Send first one straightaway.
	_tune_publisher->publish_next_tune(now);
}


void
MavlinkReceiver::handle_message_obstacle_distance(mavlink_message_t *msg)
{
	mavlink_obstacle_distance_t mavlink_obstacle_distance;
	mavlink_msg_obstacle_distance_decode(msg, &mavlink_obstacle_distance);

	obstacle_distance_s obstacle_distance{};

	obstacle_distance.timestamp = hrt_absolute_time();
	obstacle_distance.sensor_type = mavlink_obstacle_distance.sensor_type;
	memcpy(obstacle_distance.distances, mavlink_obstacle_distance.distances, sizeof(obstacle_distance.distances));

	if (mavlink_obstacle_distance.increment_f > 0.f) {
		obstacle_distance.increment = mavlink_obstacle_distance.increment_f;

	} else {
		obstacle_distance.increment = (float)mavlink_obstacle_distance.increment;
	}

	obstacle_distance.min_distance = mavlink_obstacle_distance.min_distance;
	obstacle_distance.max_distance = mavlink_obstacle_distance.max_distance;
	obstacle_distance.angle_offset = mavlink_obstacle_distance.angle_offset;
	obstacle_distance.frame = mavlink_obstacle_distance.frame;

	_obstacle_distance_pub.publish(obstacle_distance);
}

void
MavlinkReceiver::handle_message_trajectory_representation_bezier(mavlink_message_t *msg)
{
	mavlink_trajectory_representation_bezier_t trajectory;
	mavlink_msg_trajectory_representation_bezier_decode(msg, &trajectory);

	vehicle_trajectory_bezier_s trajectory_bezier{};

	trajectory_bezier.timestamp =  _mavlink_timesync.sync_stamp(trajectory.time_usec);

	for (int i = 0; i < vehicle_trajectory_bezier_s::NUMBER_POINTS; ++i) {
		trajectory_bezier.control_points[i].position[0] = trajectory.pos_x[i];
		trajectory_bezier.control_points[i].position[1] = trajectory.pos_y[i];
		trajectory_bezier.control_points[i].position[2] = trajectory.pos_z[i];

		trajectory_bezier.control_points[i].delta = trajectory.delta[i];
		trajectory_bezier.control_points[i].yaw = trajectory.pos_yaw[i];
	}

	trajectory_bezier.bezier_order = math::min(trajectory.valid_points, vehicle_trajectory_bezier_s::NUMBER_POINTS);
	_trajectory_bezier_pub.publish(trajectory_bezier);
}

void
MavlinkReceiver::handle_message_trajectory_representation_waypoints(mavlink_message_t *msg)
{
	mavlink_trajectory_representation_waypoints_t trajectory;
	mavlink_msg_trajectory_representation_waypoints_decode(msg, &trajectory);

	vehicle_trajectory_waypoint_s trajectory_waypoint{};

	trajectory_waypoint.timestamp = hrt_absolute_time();
	const int number_valid_points = trajectory.valid_points;

	for (int i = 0; i < vehicle_trajectory_waypoint_s::NUMBER_POINTS; ++i) {
		trajectory_waypoint.waypoints[i].position[0] = trajectory.pos_x[i];
		trajectory_waypoint.waypoints[i].position[1] = trajectory.pos_y[i];
		trajectory_waypoint.waypoints[i].position[2] = trajectory.pos_z[i];

		trajectory_waypoint.waypoints[i].velocity[0] = trajectory.vel_x[i];
		trajectory_waypoint.waypoints[i].velocity[1] = trajectory.vel_y[i];
		trajectory_waypoint.waypoints[i].velocity[2] = trajectory.vel_z[i];

		trajectory_waypoint.waypoints[i].acceleration[0] = trajectory.acc_x[i];
		trajectory_waypoint.waypoints[i].acceleration[1] = trajectory.acc_y[i];
		trajectory_waypoint.waypoints[i].acceleration[2] = trajectory.acc_z[i];

		trajectory_waypoint.waypoints[i].yaw = trajectory.pos_yaw[i];
		trajectory_waypoint.waypoints[i].yaw_speed = trajectory.vel_yaw[i];

		trajectory_waypoint.waypoints[i].type = UINT8_MAX;
	}

	for (int i = 0; i < number_valid_points; ++i) {
		trajectory_waypoint.waypoints[i].point_valid = true;
	}

	for (int i = number_valid_points; i < vehicle_trajectory_waypoint_s::NUMBER_POINTS; ++i) {
		trajectory_waypoint.waypoints[i].point_valid = false;
	}

	_trajectory_waypoint_pub.publish(trajectory_waypoint);
}

int
MavlinkReceiver::decode_switch_pos_n(uint16_t buttons, unsigned sw)
{
	bool on = (buttons & (1 << sw));

	if (sw < MOM_SWITCH_COUNT) {

		bool last_on = (_mom_switch_state & (1 << sw));

		/* first switch is 2-pos, rest is 2 pos */
		unsigned state_count = (sw == 0) ? 3 : 2;

		/* only transition on low state */
		if (!on && (on != last_on)) {

			_mom_switch_pos[sw]++;

			if (_mom_switch_pos[sw] == state_count) {
				_mom_switch_pos[sw] = 0;
			}
		}

		/* state_count - 1 is the number of intervals and 1000 is the range,
		 * with 2 states 0 becomes 0, 1 becomes 1000. With
		 * 3 states 0 becomes 0, 1 becomes 500, 2 becomes 1000,
		 * and so on for more states.
		 */
		return (_mom_switch_pos[sw] * 1000) / (state_count - 1) + 1000;

	} else {
		/* return the current state */
		return on * 1000 + 1000;
	}
}

void
MavlinkReceiver::handle_message_rc_channels_override(mavlink_message_t *msg)
{
	mavlink_rc_channels_override_t man;
	mavlink_msg_rc_channels_override_decode(msg, &man);

	// Check target
	if (man.target_system != 0 && man.target_system != _mavlink->get_system_id()) {
		return;
	}

	// fill uORB message
	input_rc_s rc{};

	// metadata
	rc.timestamp = hrt_absolute_time();
	rc.timestamp_last_signal = rc.timestamp;
	rc.rssi = RC_INPUT_RSSI_MAX;
	rc.rc_failsafe = false;
	rc.rc_lost = false;
	rc.rc_lost_frame_count = 0;
	rc.rc_total_frame_count = 1;
	rc.rc_ppm_frame_length = 0;
	rc.input_source = input_rc_s::RC_INPUT_SOURCE_MAVLINK;

	// channels
	rc.values[0] = man.chan1_raw;
	rc.values[1] = man.chan2_raw;
	rc.values[2] = man.chan3_raw;
	rc.values[3] = man.chan4_raw;
	rc.values[4] = man.chan5_raw;
	rc.values[5] = man.chan6_raw;
	rc.values[6] = man.chan7_raw;
	rc.values[7] = man.chan8_raw;
	rc.values[8] = man.chan9_raw;
	rc.values[9] = man.chan10_raw;
	rc.values[10] = man.chan11_raw;
	rc.values[11] = man.chan12_raw;
	rc.values[12] = man.chan13_raw;
	rc.values[13] = man.chan14_raw;
	rc.values[14] = man.chan15_raw;
	rc.values[15] = man.chan16_raw;
	rc.values[16] = man.chan17_raw;
	rc.values[17] = man.chan18_raw;

	// check how many channels are valid
	for (int i = 17; i >= 0; i--) {
		const bool ignore_max = rc.values[i] == UINT16_MAX; // ignore any channel with value UINT16_MAX
		const bool ignore_zero = (i > 7) && (rc.values[i] == 0); // ignore channel 8-18 if value is 0

		if (ignore_max || ignore_zero) {
			// set all ignored values to zero
			rc.values[i] = 0;

		} else {
			// first channel to not ignore -> set count considering zero-based index
			rc.channel_count = i + 1;
			break;
		}
	}

	// publish uORB message
	_rc_pub.publish(rc);
}

void
MavlinkReceiver::handle_message_manual_control(mavlink_message_t *msg)
{
	mavlink_manual_control_t man;
	mavlink_msg_manual_control_decode(msg, &man);

	// Check target
	if (man.target != 0 && man.target != _mavlink->get_system_id()) {
		return;
	}

	if (_mavlink->should_generate_virtual_rc_input()) {

		input_rc_s rc{};
		rc.timestamp = hrt_absolute_time();
		rc.timestamp_last_signal = rc.timestamp;

		rc.channel_count = 8;
		rc.rc_failsafe = false;
		rc.rc_lost = false;
		rc.rc_lost_frame_count = 0;
		rc.rc_total_frame_count = 1;
		rc.rc_ppm_frame_length = 0;
		rc.input_source = input_rc_s::RC_INPUT_SOURCE_MAVLINK;
		rc.rssi = RC_INPUT_RSSI_MAX;

		rc.values[0] = man.x / 2 + 1500;	// roll
		rc.values[1] = man.y / 2 + 1500;	// pitch
		rc.values[2] = man.r / 2 + 1500;	// yaw
		rc.values[3] = math::constrain(man.z / 0.9f + 800.0f, 1000.0f, 2000.0f);	// throttle

		/* decode all switches which fit into the channel mask */
		unsigned max_switch = (sizeof(man.buttons) * 8);
		unsigned max_channels = (sizeof(rc.values) / sizeof(rc.values[0]));

		if (max_switch > (max_channels - 4)) {
			max_switch = (max_channels - 4);
		}

		/* fill all channels */
		for (unsigned i = 0; i < max_switch; i++) {
			rc.values[i + 4] = decode_switch_pos_n(man.buttons, i);
		}

		_mom_switch_state = man.buttons;

		_rc_pub.publish(rc);

	} else {
		manual_control_setpoint_s manual{};

		manual.timestamp = hrt_absolute_time();
		manual.x = man.x / 1000.0f;
		manual.y = man.y / 1000.0f;
		manual.r = man.r / 1000.0f;
		manual.z = man.z / 1000.0f;
		manual.data_source = manual_control_setpoint_s::SOURCE_MAVLINK_0 + _mavlink->get_instance_id();

		_manual_control_setpoint_pub.publish(manual);
	}
}

void
MavlinkReceiver::handle_message_heartbeat(mavlink_message_t *msg)
{
	/* telemetry status supported only on first TELEMETRY_STATUS_ORB_ID_NUM mavlink channels */
	if (_mavlink->get_channel() < (mavlink_channel_t)ORB_MULTI_MAX_INSTANCES) {

		const hrt_abstime now = hrt_absolute_time();

		mavlink_heartbeat_t hb;
		mavlink_msg_heartbeat_decode(msg, &hb);

		const bool same_system = (msg->sysid == mavlink_system.sysid);

		if (same_system || hb.type == MAV_TYPE_GCS) {

			switch (hb.type) {
			case MAV_TYPE_ANTENNA_TRACKER:
				_heartbeat_type_antenna_tracker = now;
				break;

			case MAV_TYPE_GCS:
				_heartbeat_type_gcs = now;
				break;

			case MAV_TYPE_ONBOARD_CONTROLLER:
				_heartbeat_type_onboard_controller = now;
				break;

			case MAV_TYPE_GIMBAL:
				_heartbeat_type_gimbal = now;
				break;

			case MAV_TYPE_ADSB:
				_heartbeat_type_adsb = now;
				break;

			case MAV_TYPE_CAMERA:
				_heartbeat_type_camera = now;
				break;

			default:
				PX4_DEBUG("unhandled HEARTBEAT MAV_TYPE: %d from SYSID: %d, COMPID: %d", hb.type, msg->sysid, msg->compid);
			}


			switch (msg->compid) {
			case MAV_COMP_ID_TELEMETRY_RADIO:
				_heartbeat_component_telemetry_radio = now;
				break;

			case MAV_COMP_ID_LOG:
				_heartbeat_component_log = now;
				break;

			case MAV_COMP_ID_OSD:
				_heartbeat_component_osd = now;
				break;

			case MAV_COMP_ID_OBSTACLE_AVOIDANCE:
				_heartbeat_component_obstacle_avoidance = now;
				_mavlink->telemetry_status().avoidance_system_healthy = (hb.system_status == MAV_STATE_ACTIVE);
				break;

			case MAV_COMP_ID_VISUAL_INERTIAL_ODOMETRY:
				_heartbeat_component_visual_inertial_odometry = now;
				break;

			case MAV_COMP_ID_PAIRING_MANAGER:
				_heartbeat_component_pairing_manager = now;
				break;

			case MAV_COMP_ID_UDP_BRIDGE:
				_heartbeat_component_udp_bridge = now;
				break;

			case MAV_COMP_ID_UART_BRIDGE:
				_heartbeat_component_uart_bridge = now;
				break;

			default:
				PX4_DEBUG("unhandled HEARTBEAT MAV_TYPE: %d from SYSID: %d, COMPID: %d", hb.type, msg->sysid, msg->compid);
			}

			CheckHeartbeats(now, true);
		}
	}
}

int
MavlinkReceiver::set_message_interval(int msgId, float interval, int data_rate)
{
	if (msgId == MAVLINK_MSG_ID_HEARTBEAT) {
		return PX4_ERROR;
	}

	if (data_rate > 0) {
		_mavlink->set_data_rate(data_rate);
	}

	// configure_stream wants a rate (msgs/second), so convert here.
	float rate = 0.f;

	if (interval < -0.00001f) {
		rate = 0.f; // stop the stream

	} else if (interval > 0.00001f) {
		rate = 1000000.0f / interval;

	} else {
		rate = -2.f; // set default rate
	}

	bool found_id = false;

	if (msgId != 0) {
		const char *stream_name = get_stream_name(msgId);

		if (stream_name != nullptr) {
			_mavlink->configure_stream_threadsafe(stream_name, rate);
			found_id = true;
		}
	}

	return (found_id ? PX4_OK : PX4_ERROR);
}

void
MavlinkReceiver::get_message_interval(int msgId)
{
	unsigned interval = 0;

	for (const auto &stream : _mavlink->get_streams()) {
		if (stream->get_id() == msgId) {
			interval = stream->get_interval();
			break;
		}
	}

	// send back this value...
	mavlink_msg_message_interval_send(_mavlink->get_channel(), msgId, interval);
}

void
MavlinkReceiver::handle_message_hil_sensor(mavlink_message_t *msg)
{
	mavlink_hil_sensor_t hil_sensor;
	mavlink_msg_hil_sensor_decode(msg, &hil_sensor);

	const uint64_t timestamp = hrt_absolute_time();

	// temperature only updated with baro
	float temperature = NAN;

	if ((hil_sensor.fields_updated & SensorSource::BARO) == SensorSource::BARO) {
		temperature = hil_sensor.temperature;
	}

	// gyro
	if ((hil_sensor.fields_updated & SensorSource::GYRO) == SensorSource::GYRO) {
		if (_px4_gyro == nullptr) {
			// 1310988: DRV_IMU_DEVTYPE_SIM, BUS: 1, ADDR: 1, TYPE: SIMULATION
			_px4_gyro = new PX4Gyroscope(1310988);
		}

		if (_px4_gyro != nullptr) {
			if (PX4_ISFINITE(temperature)) {
				_px4_gyro->set_temperature(temperature);
			}

			_px4_gyro->update(timestamp, hil_sensor.xgyro, hil_sensor.ygyro, hil_sensor.zgyro);
		}
	}

	// accelerometer
	if ((hil_sensor.fields_updated & SensorSource::ACCEL) == SensorSource::ACCEL) {
		if (_px4_accel == nullptr) {
			// 1310988: DRV_IMU_DEVTYPE_SIM, BUS: 1, ADDR: 1, TYPE: SIMULATION
			_px4_accel = new PX4Accelerometer(1310988);
		}

		if (_px4_accel != nullptr) {
			if (PX4_ISFINITE(temperature)) {
				_px4_accel->set_temperature(temperature);
			}

			_px4_accel->update(timestamp, hil_sensor.xacc, hil_sensor.yacc, hil_sensor.zacc);
		}
	}

	// magnetometer
	if ((hil_sensor.fields_updated & SensorSource::MAG) == SensorSource::MAG) {
		if (_px4_mag == nullptr) {
			// 197388: DRV_MAG_DEVTYPE_MAGSIM, BUS: 3, ADDR: 1, TYPE: SIMULATION
			_px4_mag = new PX4Magnetometer(197388);
		}

		if (_px4_mag != nullptr) {
			if (PX4_ISFINITE(temperature)) {
				_px4_mag->set_temperature(temperature);
			}

			_px4_mag->update(timestamp, hil_sensor.xmag, hil_sensor.ymag, hil_sensor.zmag);
		}
	}

	// baro
	if ((hil_sensor.fields_updated & SensorSource::BARO) == SensorSource::BARO) {
		if (_px4_baro == nullptr) {
			// 6620172: DRV_BARO_DEVTYPE_BAROSIM, BUS: 1, ADDR: 4, TYPE: SIMULATION
			_px4_baro = new PX4Barometer(6620172);
		}

		if (_px4_baro != nullptr) {
			_px4_baro->set_temperature(hil_sensor.temperature);
			_px4_baro->update(timestamp, hil_sensor.abs_pressure);
		}
	}

	// differential pressure
	if ((hil_sensor.fields_updated & SensorSource::DIFF_PRESS) == SensorSource::DIFF_PRESS) {
		differential_pressure_s report{};
		report.timestamp = timestamp;
		report.temperature = hil_sensor.temperature;
		report.differential_pressure_filtered_pa = hil_sensor.diff_pressure * 100.0f; // convert from millibar to bar;
		report.differential_pressure_raw_pa = hil_sensor.diff_pressure * 100.0f; // convert from millibar to bar;

		_differential_pressure_pub.publish(report);
	}

	// battery status
	{
		battery_status_s hil_battery_status{};

		hil_battery_status.timestamp = timestamp;
		hil_battery_status.voltage_v = 11.5f;
		hil_battery_status.voltage_filtered_v = 11.5f;
		hil_battery_status.current_a = 10.0f;
		hil_battery_status.discharged_mah = -1.0f;

		_battery_pub.publish(hil_battery_status);
	}
}

void
MavlinkReceiver::handle_message_hil_gps(mavlink_message_t *msg)
{
	mavlink_hil_gps_t gps;
	mavlink_msg_hil_gps_decode(msg, &gps);

	const uint64_t timestamp = hrt_absolute_time();

	sensor_gps_s hil_gps{};

	hil_gps.timestamp_time_relative = 0;
	hil_gps.time_utc_usec = gps.time_usec;

	hil_gps.timestamp = timestamp;
	hil_gps.lat = gps.lat;
	hil_gps.lon = gps.lon;
	hil_gps.alt = gps.alt;
	hil_gps.eph = (float)gps.eph * 1e-2f; // from cm to m
	hil_gps.epv = (float)gps.epv * 1e-2f; // from cm to m

	hil_gps.s_variance_m_s = 0.1f;

	hil_gps.vel_m_s = (float)gps.vel * 1e-2f; // from cm/s to m/s
	hil_gps.vel_n_m_s = gps.vn * 1e-2f; // from cm to m
	hil_gps.vel_e_m_s = gps.ve * 1e-2f; // from cm to m
	hil_gps.vel_d_m_s = gps.vd * 1e-2f; // from cm to m
	hil_gps.vel_ned_valid = true;
	hil_gps.cog_rad = ((gps.cog == 65535) ? NAN : wrap_2pi(math::radians(gps.cog * 1e-2f)));

	hil_gps.fix_type = gps.fix_type;
	hil_gps.satellites_used = gps.satellites_visible;  //TODO: rename mavlink_hil_gps_t sats visible to used?

	hil_gps.heading = NAN;
	hil_gps.heading_offset = NAN;

	_gps_pub.publish(hil_gps);
}

void
MavlinkReceiver::handle_message_follow_target(mavlink_message_t *msg)
{
	mavlink_follow_target_t follow_target_msg;
	mavlink_msg_follow_target_decode(msg, &follow_target_msg);

	follow_target_s follow_target_topic{};

	follow_target_topic.timestamp = hrt_absolute_time();
	follow_target_topic.lat = follow_target_msg.lat * 1e-7;
	follow_target_topic.lon = follow_target_msg.lon * 1e-7;
	follow_target_topic.alt = follow_target_msg.alt;

	_follow_target_pub.publish(follow_target_topic);
}

void
MavlinkReceiver::handle_message_landing_target(mavlink_message_t *msg)
{
	mavlink_landing_target_t landing_target;
	mavlink_msg_landing_target_decode(msg, &landing_target);

	if (landing_target.position_valid && landing_target.frame == MAV_FRAME_LOCAL_NED) {
		landing_target_pose_s landing_target_pose{};

		landing_target_pose.timestamp = _mavlink_timesync.sync_stamp(landing_target.time_usec);
		landing_target_pose.abs_pos_valid = true;
		landing_target_pose.x_abs = landing_target.x;
		landing_target_pose.y_abs = landing_target.y;
		landing_target_pose.z_abs = landing_target.z;

		_landing_target_pose_pub.publish(landing_target_pose);

	} else {
		irlock_report_s irlock_report{};

		irlock_report.timestamp = hrt_absolute_time();
		irlock_report.signature = landing_target.target_num;
		irlock_report.pos_x = landing_target.angle_x;
		irlock_report.pos_y = landing_target.angle_y;
		irlock_report.size_x = landing_target.size_x;
		irlock_report.size_y = landing_target.size_y;

		_irlock_report_pub.publish(irlock_report);
	}
}

void
MavlinkReceiver::handle_message_cellular_status(mavlink_message_t *msg)
{
	mavlink_cellular_status_t status;
	mavlink_msg_cellular_status_decode(msg, &status);

	cellular_status_s cellular_status{};

	cellular_status.timestamp = hrt_absolute_time();
	cellular_status.status = status.status;
	cellular_status.failure_reason = status.failure_reason;
	cellular_status.type = status.type;
	cellular_status.quality = status.quality;
	cellular_status.mcc = status.mcc;
	cellular_status.mnc = status.mnc;
	cellular_status.lac = status.lac;

	_cellular_status_pub.publish(cellular_status);
}

void
MavlinkReceiver::handle_message_adsb_vehicle(mavlink_message_t *msg)
{
	mavlink_adsb_vehicle_t adsb;
	mavlink_msg_adsb_vehicle_decode(msg, &adsb);

	transponder_report_s t{};

	t.timestamp = hrt_absolute_time();

	t.icao_address = adsb.ICAO_address;
	t.lat = adsb.lat * 1e-7;
	t.lon = adsb.lon * 1e-7;
	t.altitude_type = adsb.altitude_type;
	t.altitude = adsb.altitude / 1000.0f;
	t.heading = adsb.heading / 100.0f / 180.0f * M_PI_F - M_PI_F;
	t.hor_velocity = adsb.hor_velocity / 100.0f;
	t.ver_velocity = adsb.ver_velocity / 100.0f;
	memcpy(&t.callsign[0], &adsb.callsign[0], sizeof(t.callsign));
	t.emitter_type = adsb.emitter_type;
	t.tslc = adsb.tslc;
	t.squawk = adsb.squawk;

	t.flags = transponder_report_s::PX4_ADSB_FLAGS_RETRANSLATE;  //Unset in receiver already broadcast its messages

	if (adsb.flags & ADSB_FLAGS_VALID_COORDS) { t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_COORDS; }

	if (adsb.flags & ADSB_FLAGS_VALID_ALTITUDE) { t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_ALTITUDE; }

	if (adsb.flags & ADSB_FLAGS_VALID_HEADING) { t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_HEADING; }

	if (adsb.flags & ADSB_FLAGS_VALID_VELOCITY) { t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_VELOCITY; }

	if (adsb.flags & ADSB_FLAGS_VALID_CALLSIGN) { t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_CALLSIGN; }

	if (adsb.flags & ADSB_FLAGS_VALID_SQUAWK) { t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_SQUAWK; }

	//PX4_INFO("code: %d callsign: %s, vel: %8.4f, tslc: %d", (int)t.ICAO_address, t.callsign, (double)t.hor_velocity, (int)t.tslc);

	_transponder_report_pub.publish(t);
}

void
MavlinkReceiver::handle_message_utm_global_position(mavlink_message_t *msg)
{
	mavlink_utm_global_position_t utm_pos;
	mavlink_msg_utm_global_position_decode(msg, &utm_pos);

	bool is_self_published = false;


#ifndef BOARD_HAS_NO_UUID
	px4_guid_t px4_guid;
	board_get_px4_guid(px4_guid);
	is_self_published = sizeof(px4_guid) == sizeof(utm_pos.uas_id)
			    && memcmp(px4_guid, utm_pos.uas_id, sizeof(px4_guid_t)) == 0;
#else

	is_self_published = msg->sysid == _mavlink->get_system_id();
#endif /* BOARD_HAS_NO_UUID */


	//Ignore selfpublished UTM messages
	if (is_self_published) {
		return;
	}

	// Convert cm/s to m/s
	float vx = utm_pos.vx / 100.0f;
	float vy = utm_pos.vy / 100.0f;
	float vz = utm_pos.vz / 100.0f;

	transponder_report_s t{};
	t.timestamp = hrt_absolute_time();
	mav_array_memcpy(t.uas_id, utm_pos.uas_id, PX4_GUID_BYTE_LENGTH);
	t.lat = utm_pos.lat * 1e-7;
	t.lon = utm_pos.lon * 1e-7;
	t.altitude = utm_pos.alt / 1000.0f;
	t.altitude_type = ADSB_ALTITUDE_TYPE_GEOMETRIC;
	// UTM_GLOBAL_POSIION uses NED (north, east, down) coordinates for velocity, in cm / s.
	t.heading = atan2f(vy, vx);
	t.hor_velocity = sqrtf(vy * vy + vx * vx);
	t.ver_velocity = -vz;
	// TODO: Callsign
	// For now, set it to all 0s. This is a null-terminated string, so not explicitly giving it a null
	// terminator could cause problems.
	memset(&t.callsign[0], 0, sizeof(t.callsign));
	t.emitter_type = ADSB_EMITTER_TYPE_UAV;  // TODO: Is this correct?x2?

	// The Mavlink docs do not specify what to do if tslc (time since last communication) is out of range of
	// an 8-bit int, or if this is the first communication.
	// Here, I assume that if this is the first communication, tslc = 0.
	// If tslc > 255, then tslc = 255.
	unsigned long time_passed = (t.timestamp - _last_utm_global_pos_com) / 1000000;

	if (_last_utm_global_pos_com == 0) {
		time_passed = 0;

	} else if (time_passed > UINT8_MAX) {
		time_passed = UINT8_MAX;
	}

	t.tslc = (uint8_t) time_passed;

	t.flags = 0;

	if (utm_pos.flags & UTM_DATA_AVAIL_FLAGS_POSITION_AVAILABLE) {
		t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_COORDS;
	}

	if (utm_pos.flags & UTM_DATA_AVAIL_FLAGS_ALTITUDE_AVAILABLE) {
		t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_ALTITUDE;
	}

	if (utm_pos.flags & UTM_DATA_AVAIL_FLAGS_HORIZONTAL_VELO_AVAILABLE) {
		t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_HEADING;
		t.flags |= transponder_report_s::PX4_ADSB_FLAGS_VALID_VELOCITY;
	}

	// Note: t.flags has deliberately NOT set VALID_CALLSIGN or VALID_SQUAWK, because UTM_GLOBAL_POSITION does not
	// provide these.
	_transponder_report_pub.publish(t);

	_last_utm_global_pos_com = t.timestamp;
}

void
MavlinkReceiver::handle_message_collision(mavlink_message_t *msg)
{
	mavlink_collision_t collision;
	mavlink_msg_collision_decode(msg, &collision);

	collision_report_s collision_report{};

	collision_report.timestamp = hrt_absolute_time();
	collision_report.src = collision.src;
	collision_report.id = collision.id;
	collision_report.action = collision.action;
	collision_report.threat_level = collision.threat_level;
	collision_report.time_to_minimum_delta = collision.time_to_minimum_delta;
	collision_report.altitude_minimum_delta = collision.altitude_minimum_delta;
	collision_report.horizontal_minimum_delta = collision.horizontal_minimum_delta;

	_collision_report_pub.publish(collision_report);
}

void
MavlinkReceiver::handle_message_gps_rtcm_data(mavlink_message_t *msg)
{
	mavlink_gps_rtcm_data_t gps_rtcm_data_msg;
	mavlink_msg_gps_rtcm_data_decode(msg, &gps_rtcm_data_msg);

	gps_inject_data_s gps_inject_data_topic{};

	gps_inject_data_topic.len = math::min((int)sizeof(gps_rtcm_data_msg.data),
					      (int)sizeof(uint8_t) * gps_rtcm_data_msg.len);
	gps_inject_data_topic.flags = gps_rtcm_data_msg.flags;
	memcpy(gps_inject_data_topic.data, gps_rtcm_data_msg.data,
	       math::min((int)sizeof(gps_inject_data_topic.data), (int)sizeof(uint8_t) * gps_inject_data_topic.len));

	_gps_inject_data_pub.publish(gps_inject_data_topic);
}

void
MavlinkReceiver::handle_message_hil_state_quaternion(mavlink_message_t *msg)
{
	mavlink_hil_state_quaternion_t hil_state;
	mavlink_msg_hil_state_quaternion_decode(msg, &hil_state);

	const uint64_t timestamp = hrt_absolute_time();

	/* airspeed */
	{
		airspeed_s airspeed{};

		airspeed.timestamp = timestamp;
		airspeed.indicated_airspeed_m_s = hil_state.ind_airspeed * 1e-2f;
		airspeed.true_airspeed_m_s = hil_state.true_airspeed * 1e-2f;

		_airspeed_pub.publish(airspeed);
	}

	/* attitude */
	{
		vehicle_attitude_s hil_attitude{};

		hil_attitude.timestamp = timestamp;

		matrix::Quatf q(hil_state.attitude_quaternion);
		q.copyTo(hil_attitude.q);

		_attitude_pub.publish(hil_attitude);
	}

	/* global position */
	{
		vehicle_global_position_s hil_global_pos{};

		hil_global_pos.timestamp = timestamp;
		hil_global_pos.lat = hil_state.lat / ((double)1e7);
		hil_global_pos.lon = hil_state.lon / ((double)1e7);
		hil_global_pos.alt = hil_state.alt / 1000.0f;
		hil_global_pos.eph = 2.0f;
		hil_global_pos.epv = 4.0f;

		_global_pos_pub.publish(hil_global_pos);
	}

	/* local position */
	{
		const double lat = hil_state.lat * 1e-7;
		const double lon = hil_state.lon * 1e-7;

		map_projection_reference_s global_local_proj_ref;
		map_projection_init(&global_local_proj_ref, lat, lon);

		float global_local_alt0 = hil_state.alt / 1000.f;

		float x = 0.0f;
		float y = 0.0f;
		map_projection_project(&global_local_proj_ref, lat, lon, &x, &y);

		vehicle_local_position_s hil_local_pos{};
		hil_local_pos.timestamp = timestamp;

		hil_local_pos.ref_timestamp = global_local_proj_ref.timestamp;
		hil_local_pos.ref_lat = math::degrees(global_local_proj_ref.lat_rad);
		hil_local_pos.ref_lon = math::degrees(global_local_proj_ref.lon_rad);
		hil_local_pos.ref_alt = global_local_alt0;
		hil_local_pos.xy_valid = true;
		hil_local_pos.z_valid = true;
		hil_local_pos.v_xy_valid = true;
		hil_local_pos.v_z_valid = true;
		hil_local_pos.x = x;
		hil_local_pos.y = y;
		hil_local_pos.z = global_local_alt0 - hil_state.alt / 1000.0f;
		hil_local_pos.vx = hil_state.vx / 100.0f;
		hil_local_pos.vy = hil_state.vy / 100.0f;
		hil_local_pos.vz = hil_state.vz / 100.0f;

		matrix::Eulerf euler{matrix::Quatf(hil_state.attitude_quaternion)};
		hil_local_pos.heading = euler.psi();
		hil_local_pos.xy_global = true;
		hil_local_pos.z_global = true;
		hil_local_pos.vxy_max = INFINITY;
		hil_local_pos.vz_max = INFINITY;
		hil_local_pos.hagl_min = INFINITY;
		hil_local_pos.hagl_max = INFINITY;

		_local_pos_pub.publish(hil_local_pos);
	}

	/* accelerometer */
	{
		if (_px4_accel == nullptr) {
			// 1310988: DRV_IMU_DEVTYPE_SIM, BUS: 1, ADDR: 1, TYPE: SIMULATION
			_px4_accel = new PX4Accelerometer(1310988);

			if (_px4_accel == nullptr) {
				PX4_ERR("PX4Accelerometer alloc failed");
			}
		}

		if (_px4_accel != nullptr) {
			// accel in mG
			_px4_accel->set_scale(CONSTANTS_ONE_G / 1000.0f);
			_px4_accel->update(timestamp, hil_state.xacc, hil_state.yacc, hil_state.zacc);
		}
	}

	/* gyroscope */
	{
		if (_px4_gyro == nullptr) {
			// 1310988: DRV_IMU_DEVTYPE_SIM, BUS: 1, ADDR: 1, TYPE: SIMULATION
			_px4_gyro = new PX4Gyroscope(1310988);

			if (_px4_gyro == nullptr) {
				PX4_ERR("PX4Gyroscope alloc failed");
			}
		}

		if (_px4_gyro != nullptr) {
			_px4_gyro->update(timestamp, hil_state.rollspeed, hil_state.pitchspeed, hil_state.yawspeed);
		}
	}

	/* battery status */
	{
		battery_status_s hil_battery_status{};

		hil_battery_status.timestamp = timestamp;
		hil_battery_status.voltage_v = 11.1f;
		hil_battery_status.voltage_filtered_v = 11.1f;
		hil_battery_status.current_a = 10.0f;
		hil_battery_status.discharged_mah = -1.0f;

		_battery_pub.publish(hil_battery_status);
	}
}

#if !defined(CONSTRAINED_FLASH)
void
MavlinkReceiver::handle_message_named_value_float(mavlink_message_t *msg)
{
	mavlink_named_value_float_t debug_msg;
	mavlink_msg_named_value_float_decode(msg, &debug_msg);

	debug_key_value_s debug_topic{};

	debug_topic.timestamp = hrt_absolute_time();
	memcpy(debug_topic.key, debug_msg.name, sizeof(debug_topic.key));
	debug_topic.key[sizeof(debug_topic.key) - 1] = '\0'; // enforce null termination
	debug_topic.value = debug_msg.value;

	_debug_key_value_pub.publish(debug_topic);
}

void
MavlinkReceiver::handle_message_debug(mavlink_message_t *msg)
{
	mavlink_debug_t debug_msg;
	mavlink_msg_debug_decode(msg, &debug_msg);

	debug_value_s debug_topic{};

	debug_topic.timestamp = hrt_absolute_time();
	debug_topic.ind = debug_msg.ind;
	debug_topic.value = debug_msg.value;

	_debug_value_pub.publish(debug_topic);
}

void
MavlinkReceiver::handle_message_debug_vect(mavlink_message_t *msg)
{
	mavlink_debug_vect_t debug_msg;
	mavlink_msg_debug_vect_decode(msg, &debug_msg);

	debug_vect_s debug_topic{};

	debug_topic.timestamp = hrt_absolute_time();
	memcpy(debug_topic.name, debug_msg.name, sizeof(debug_topic.name));
	debug_topic.name[sizeof(debug_topic.name) - 1] = '\0'; // enforce null termination
	debug_topic.x = debug_msg.x;
	debug_topic.y = debug_msg.y;
	debug_topic.z = debug_msg.z;

	_debug_vect_pub.publish(debug_topic);
}

void
MavlinkReceiver::handle_message_debug_float_array(mavlink_message_t *msg)
{
	mavlink_debug_float_array_t debug_msg;
	mavlink_msg_debug_float_array_decode(msg, &debug_msg);

	debug_array_s debug_topic{};

	debug_topic.timestamp = hrt_absolute_time();
	debug_topic.id = debug_msg.array_id;
	memcpy(debug_topic.name, debug_msg.name, sizeof(debug_topic.name));
	debug_topic.name[sizeof(debug_topic.name) - 1] = '\0'; // enforce null termination

	for (size_t i = 0; i < debug_array_s::ARRAY_SIZE; i++) {
		debug_topic.data[i] = debug_msg.data[i];
	}

	_debug_array_pub.publish(debug_topic);
}
#endif // !CONSTRAINED_FLASH

void
MavlinkReceiver::handle_message_onboard_computer_status(mavlink_message_t *msg)
{
	mavlink_onboard_computer_status_t status_msg;
	mavlink_msg_onboard_computer_status_decode(msg, &status_msg);

	onboard_computer_status_s onboard_computer_status_topic{};

	onboard_computer_status_topic.timestamp = hrt_absolute_time();
	onboard_computer_status_topic.uptime = status_msg.uptime;

	onboard_computer_status_topic.type = status_msg.type;

	memcpy(onboard_computer_status_topic.cpu_cores, status_msg.cpu_cores, sizeof(status_msg.cpu_cores));
	memcpy(onboard_computer_status_topic.cpu_combined, status_msg.cpu_combined, sizeof(status_msg.cpu_combined));
	memcpy(onboard_computer_status_topic.gpu_cores, status_msg.gpu_cores, sizeof(status_msg.gpu_cores));
	memcpy(onboard_computer_status_topic.gpu_combined, status_msg.gpu_combined, sizeof(status_msg.gpu_combined));
	onboard_computer_status_topic.temperature_board = status_msg.temperature_board;
	memcpy(onboard_computer_status_topic.temperature_core, status_msg.temperature_core,
	       sizeof(status_msg.temperature_core));
	memcpy(onboard_computer_status_topic.fan_speed, status_msg.fan_speed, sizeof(status_msg.fan_speed));
	onboard_computer_status_topic.ram_usage = status_msg.ram_usage;
	onboard_computer_status_topic.ram_total = status_msg.ram_total;
	memcpy(onboard_computer_status_topic.storage_type, status_msg.storage_type, sizeof(status_msg.storage_type));
	memcpy(onboard_computer_status_topic.storage_usage, status_msg.storage_usage, sizeof(status_msg.storage_usage));
	memcpy(onboard_computer_status_topic.storage_total, status_msg.storage_total, sizeof(status_msg.storage_total));
	memcpy(onboard_computer_status_topic.link_type, status_msg.link_type, sizeof(status_msg.link_type));
	memcpy(onboard_computer_status_topic.link_tx_rate, status_msg.link_tx_rate, sizeof(status_msg.link_tx_rate));
	memcpy(onboard_computer_status_topic.link_rx_rate, status_msg.link_rx_rate, sizeof(status_msg.link_rx_rate));
	memcpy(onboard_computer_status_topic.link_tx_max, status_msg.link_tx_max, sizeof(status_msg.link_tx_max));
	memcpy(onboard_computer_status_topic.link_rx_max, status_msg.link_rx_max, sizeof(status_msg.link_rx_max));

	_onboard_computer_status_pub.publish(onboard_computer_status_topic);
}

void MavlinkReceiver::handle_message_generator_status(mavlink_message_t *msg)
{
	mavlink_generator_status_t status_msg;
	mavlink_msg_generator_status_decode(msg, &status_msg);

	generator_status_s generator_status{};
	generator_status.timestamp = hrt_absolute_time();
	generator_status.status = status_msg.status;
	generator_status.battery_current = status_msg.battery_current;
	generator_status.load_current = status_msg.load_current;
	generator_status.power_generated = status_msg.power_generated;
	generator_status.bus_voltage = status_msg.bus_voltage;
	generator_status.bat_current_setpoint = status_msg.bat_current_setpoint;
	generator_status.runtime = status_msg.runtime;
	generator_status.time_until_maintenance = status_msg.time_until_maintenance;
	generator_status.generator_speed = status_msg.generator_speed;
	generator_status.rectifier_temperature = status_msg.rectifier_temperature;
	generator_status.generator_temperature = status_msg.generator_temperature;

	_generator_status_pub.publish(generator_status);
}

void MavlinkReceiver::handle_message_statustext(mavlink_message_t *msg)
{
	if (msg->sysid == mavlink_system.sysid) {
		// log message from the same system

		mavlink_statustext_t statustext;
		mavlink_msg_statustext_decode(msg, &statustext);

		log_message_s log_message{};

		log_message.severity = statustext.severity;
		log_message.timestamp = hrt_absolute_time();

		snprintf(log_message.text, sizeof(log_message.text),
			 "[mavlink: component %d] %." STRINGIFY(MAVLINK_MSG_STATUSTEXT_FIELD_TEXT_LEN) "s", msg->compid, statustext.text);

		_log_message_pub.publish(log_message);
	}
}

void MavlinkReceiver::CheckHeartbeats(const hrt_abstime &t, bool force)
{
	// check HEARTBEATs for timeout
	static constexpr uint64_t TIMEOUT = telemetry_status_s::HEARTBEAT_TIMEOUT_US;

	if (t <= TIMEOUT) {
		return;
	}

	if ((t >= _last_heartbeat_check + (TIMEOUT / 2)) || force) {
		telemetry_status_s &tstatus = _mavlink->telemetry_status();

		tstatus.heartbeat_type_antenna_tracker         = (t <= TIMEOUT + _heartbeat_type_antenna_tracker);
		tstatus.heartbeat_type_gcs                     = (t <= TIMEOUT + _heartbeat_type_gcs);
		tstatus.heartbeat_type_onboard_controller      = (t <= TIMEOUT + _heartbeat_type_onboard_controller);
		tstatus.heartbeat_type_gimbal                  = (t <= TIMEOUT + _heartbeat_type_gimbal);
		tstatus.heartbeat_type_adsb                    = (t <= TIMEOUT + _heartbeat_type_adsb);
		tstatus.heartbeat_type_camera                  = (t <= TIMEOUT + _heartbeat_type_camera);

		tstatus.heartbeat_component_telemetry_radio    = (t <= TIMEOUT + _heartbeat_component_telemetry_radio);
		tstatus.heartbeat_component_log                = (t <= TIMEOUT + _heartbeat_component_log);
		tstatus.heartbeat_component_osd                = (t <= TIMEOUT + _heartbeat_component_osd);
		tstatus.heartbeat_component_obstacle_avoidance = (t <= TIMEOUT + _heartbeat_component_obstacle_avoidance);
		tstatus.heartbeat_component_vio                = (t <= TIMEOUT + _heartbeat_component_visual_inertial_odometry);
		tstatus.heartbeat_component_pairing_manager    = (t <= TIMEOUT + _heartbeat_component_pairing_manager);
		tstatus.heartbeat_component_udp_bridge         = (t <= TIMEOUT + _heartbeat_component_udp_bridge);
		tstatus.heartbeat_component_uart_bridge        = (t <= TIMEOUT + _heartbeat_component_uart_bridge);

		_mavlink->telemetry_status_updated();
		_last_heartbeat_check = t;
	}
}

void
MavlinkReceiver::handle_message_gimbal_manager_set_manual_control(mavlink_message_t *msg)
{
	mavlink_gimbal_manager_set_manual_control_t set_manual_control_msg;
	mavlink_msg_gimbal_manager_set_manual_control_decode(msg, &set_manual_control_msg);

	gimbal_manager_set_manual_control_s set_manual_control{};
	set_manual_control.timestamp = hrt_absolute_time();
	set_manual_control.origin_sysid = msg->sysid;
	set_manual_control.origin_compid = msg->compid;
	set_manual_control.target_system = set_manual_control_msg.target_system;
	set_manual_control.target_component = set_manual_control_msg.target_component;
	set_manual_control.flags = set_manual_control_msg.flags;
	set_manual_control.gimbal_device_id = set_manual_control_msg.gimbal_device_id;

	set_manual_control.pitch = set_manual_control_msg.pitch;
	set_manual_control.yaw = set_manual_control_msg.yaw;
	set_manual_control.pitch_rate = set_manual_control_msg.pitch_rate;
	set_manual_control.yaw_rate = set_manual_control_msg.yaw_rate;

	_gimbal_manager_set_manual_control_pub.publish(set_manual_control);
}

void
MavlinkReceiver::handle_message_gimbal_manager_set_attitude(mavlink_message_t *msg)
{
	mavlink_gimbal_manager_set_attitude_t set_attitude_msg;
	mavlink_msg_gimbal_manager_set_attitude_decode(msg, &set_attitude_msg);

	gimbal_manager_set_attitude_s gimbal_attitude{};
	gimbal_attitude.timestamp = hrt_absolute_time();
	gimbal_attitude.origin_sysid = msg->sysid;
	gimbal_attitude.origin_compid = msg->compid;
	gimbal_attitude.target_system = set_attitude_msg.target_system;
	gimbal_attitude.target_component = set_attitude_msg.target_component;
	gimbal_attitude.flags = set_attitude_msg.flags;
	gimbal_attitude.gimbal_device_id = set_attitude_msg.gimbal_device_id;

	matrix::Quatf q(set_attitude_msg.q);
	q.copyTo(gimbal_attitude.q);

	gimbal_attitude.angular_velocity_x = set_attitude_msg.angular_velocity_x;
	gimbal_attitude.angular_velocity_y = set_attitude_msg.angular_velocity_y;
	gimbal_attitude.angular_velocity_z = set_attitude_msg.angular_velocity_z;

	_gimbal_manager_set_attitude_pub.publish(gimbal_attitude);
}

void
MavlinkReceiver::handle_message_gimbal_device_information(mavlink_message_t *msg)
{

	mavlink_gimbal_device_information_t gimbal_device_info_msg;
	mavlink_msg_gimbal_device_information_decode(msg, &gimbal_device_info_msg);

	gimbal_device_information_s gimbal_information{};
	gimbal_information.timestamp = hrt_absolute_time();

	static_assert(sizeof(gimbal_information.vendor_name) == sizeof(gimbal_device_info_msg.vendor_name),
		      "vendor_name length doesn't match");
	static_assert(sizeof(gimbal_information.model_name) == sizeof(gimbal_device_info_msg.model_name),
		      "model_name length doesn't match");
	static_assert(sizeof(gimbal_information.custom_name) == sizeof(gimbal_device_info_msg.custom_name),
		      "custom_name length doesn't match");
	memcpy(gimbal_information.vendor_name, gimbal_device_info_msg.vendor_name, sizeof(gimbal_information.vendor_name));
	memcpy(gimbal_information.model_name, gimbal_device_info_msg.model_name, sizeof(gimbal_information.model_name));
	memcpy(gimbal_information.custom_name, gimbal_device_info_msg.custom_name, sizeof(gimbal_information.custom_name));
	gimbal_device_info_msg.vendor_name[sizeof(gimbal_device_info_msg.vendor_name) - 1] = '\0';
	gimbal_device_info_msg.model_name[sizeof(gimbal_device_info_msg.model_name) - 1] = '\0';
	gimbal_device_info_msg.custom_name[sizeof(gimbal_device_info_msg.custom_name) - 1] = '\0';

	gimbal_information.firmware_version = gimbal_device_info_msg.firmware_version;
	gimbal_information.hardware_version = gimbal_device_info_msg.hardware_version;
	gimbal_information.cap_flags = gimbal_device_info_msg.cap_flags;
	gimbal_information.custom_cap_flags = gimbal_device_info_msg.custom_cap_flags;
	gimbal_information.uid = gimbal_device_info_msg.uid;

	gimbal_information.pitch_max = gimbal_device_info_msg.pitch_max;
	gimbal_information.pitch_min = gimbal_device_info_msg.pitch_min;

	gimbal_information.yaw_max = gimbal_device_info_msg.yaw_max;
	gimbal_information.yaw_min = gimbal_device_info_msg.yaw_min;

	gimbal_information.gimbal_device_compid = msg->compid;

	_gimbal_device_information_pub.publish(gimbal_information);
}

/**
 * Receive data from UART/UDP
 */
void
MavlinkReceiver::Run()
{
	/* set thread name */
	{
		char thread_name[17];
		snprintf(thread_name, sizeof(thread_name), "mavlink_rcv_if%d", _mavlink->get_instance_id());
		px4_prctl(PR_SET_NAME, thread_name, px4_getpid());
	}

	// make sure mavlink app has booted before we start processing anything (parameter sync, etc)
	while (!_mavlink->boot_complete()) {
		if (hrt_elapsed_time(&_mavlink->get_first_start_time()) > 20_s) {
			PX4_ERR("system boot did not complete in 20 seconds");
			_mavlink->set_boot_complete();
		}

		px4_usleep(100000);
	}

	// poll timeout in ms. Also defines the max update frequency of the mission & param manager, etc.
	const int timeout = 10;

#if defined(__PX4_POSIX)
	/* 1500 is the Wifi MTU, so we make sure to fit a full packet */
	uint8_t buf[1600 * 5];
#elif defined(CONFIG_NET)
	/* 1500 is the Wifi MTU, so we make sure to fit a full packet */
	uint8_t buf[1000];
#else
	/* the serial port buffers internally as well, we just need to fit a small chunk */
	uint8_t buf[64];
#endif
	mavlink_message_t msg;

	struct pollfd fds[1] = {};

	if (_mavlink->get_protocol() == Protocol::SERIAL) {
		fds[0].fd = _mavlink->get_uart_fd();
		fds[0].events = POLLIN;
	}

#if defined(MAVLINK_UDP)
	struct sockaddr_in srcaddr = {};
	socklen_t addrlen = sizeof(srcaddr);

	if (_mavlink->get_protocol() == Protocol::UDP) {
		fds[0].fd = _mavlink->get_socket_fd();
		fds[0].events = POLLIN;
	}

#endif // MAVLINK_UDP

	ssize_t nread = 0;
	hrt_abstime last_send_update = 0;

	while (!_mavlink->_task_should_exit) {

		// check for parameter updates
		if (_parameter_update_sub.updated()) {
			// clear update
			parameter_update_s pupdate;
			_parameter_update_sub.copy(&pupdate);

			// update parameters from storage
			updateParams();
		}

		int ret = poll(&fds[0], 1, timeout);

		if (ret > 0) {
			if (_mavlink->get_protocol() == Protocol::SERIAL) {
				/* non-blocking read. read may return negative values */
				nread = ::read(fds[0].fd, buf, sizeof(buf));

				if (nread == -1 && errno == ENOTCONN) { // Not connected (can happen for USB)
					usleep(100000);
				}
			}

#if defined(MAVLINK_UDP)

			else if (_mavlink->get_protocol() == Protocol::UDP) {
				if (fds[0].revents & POLLIN) {
					nread = recvfrom(_mavlink->get_socket_fd(), buf, sizeof(buf), 0, (struct sockaddr *)&srcaddr, &addrlen);
				}

				struct sockaddr_in &srcaddr_last = _mavlink->get_client_source_address();

				int localhost = (127 << 24) + 1;

				if (!_mavlink->get_client_source_initialized()) {

					// set the address either if localhost or if 3 seconds have passed
					// this ensures that a GCS running on localhost can get a hold of
					// the system within the first N seconds
					hrt_abstime stime = _mavlink->get_start_time();

					if ((stime != 0 && (hrt_elapsed_time(&stime) > 3_s))
					    || (srcaddr_last.sin_addr.s_addr == htonl(localhost))) {

						srcaddr_last.sin_addr.s_addr = srcaddr.sin_addr.s_addr;
						srcaddr_last.sin_port = srcaddr.sin_port;

						_mavlink->set_client_source_initialized();

						PX4_INFO("partner IP: %s", inet_ntoa(srcaddr.sin_addr));
					}
				}
			}

			// only start accepting messages on UDP once we're sure who we talk to
			if (_mavlink->get_protocol() != Protocol::UDP || _mavlink->get_client_source_initialized()) {
#endif // MAVLINK_UDP

				/* if read failed, this loop won't execute */
				for (ssize_t i = 0; i < nread; i++) {
					if (mavlink_parse_char(_mavlink->get_channel(), buf[i], &msg, &_status)) {
						_total_received_counter++;

						/* check if we received version 2 and request a switch. */
						if (!(_mavlink->get_status()->flags & MAVLINK_STATUS_FLAG_IN_MAVLINK1)) {
							/* this will only switch to proto version 2 if allowed in settings */
							_mavlink->set_proto_version(2);
						}

						/* handle generic messages and commands */
						handle_message(&msg);

						/* handle packet with mission manager */
						_mission_manager.handle_message(&msg);


						/* handle packet with parameter component */
						_parameters_manager.handle_message(&msg);

						if (_mavlink->ftp_enabled()) {
							/* handle packet with ftp component */
							_mavlink_ftp.handle_message(&msg);
						}

						/* handle packet with log component */
						_mavlink_log_handler.handle_message(&msg);

						/* handle packet with timesync component */
						_mavlink_timesync.handle_message(&msg);

						/* handle packet with parent object */
						_mavlink->handle_message(&msg);


						// calculate lost messages for this system id
						bool px4_sysid_index_found = false;
						int px4_sysid_index = 0;

						if (msg.sysid != mavlink_system.sysid) {
							for (int sys_id = 1; sys_id < MAX_REMOTE_SYSTEM_IDS; sys_id++) {
								if (_system_id_map[sys_id] == msg.sysid) {
									// slot found
									px4_sysid_index_found = true;
									px4_sysid_index = sys_id;
									break;
								}
							}

							// otherwise record newly seen system id in first available slot
							if (!px4_sysid_index_found) {
								for (int sys_id = 1; sys_id < MAX_REMOTE_SYSTEM_IDS; sys_id++) {
									if (_system_id_map[sys_id] == 0) {
										// slot available
										px4_sysid_index_found = true;
										px4_sysid_index = sys_id;
										_system_id_map[sys_id] = msg.sysid;
										break;
									}
								}
							}

							if (!px4_sysid_index_found) {
								PX4_ERR("not enough system id slots (%d)", MAX_REMOTE_SYSTEM_IDS);
							}

						} else {
							px4_sysid_index_found = true;
						}

						// find PX4 component id
						uint8_t px4_comp_id = 0;
						bool px4_comp_id_found = false;

						for (int id = 0; id < COMP_ID_MAX; id++) {
							if (supported_component_map[id] == msg.compid) {
								px4_comp_id = id;
								px4_comp_id_found = true;
								break;
							}
						}

						if (!px4_comp_id_found) {
							PX4_WARN("unsupported component id, msgid: %d, sysid: %d compid: %d", msg.msgid, msg.sysid, msg.compid);
						}

						if (px4_comp_id_found && px4_sysid_index_found) {
							// Increase receive counter
							_total_received_supported_counter++;

							uint8_t last_seq = _last_index[px4_sysid_index][px4_comp_id];
							uint8_t expected_seq = last_seq + 1;

							// Determine what the next expected sequence number is, accounting for
							// never having seen a message for this system/component pair.
							if (!_sys_comp_present[px4_sysid_index][px4_comp_id]) {
								_sys_comp_present[px4_sysid_index][px4_comp_id] = true;
								last_seq = msg.seq;
								expected_seq = msg.seq;
							}

							// And if we didn't encounter that sequence number, record the error
							if (msg.seq != expected_seq) {
								int lost_messages = 0;

								// Account for overflow during packet loss
								if (msg.seq < expected_seq) {
									lost_messages = (msg.seq + 255) - expected_seq;

								} else {
									lost_messages = msg.seq - expected_seq;
								}

								// Log how many were lost
								_total_lost_counter += lost_messages;
							}

							// And update the last sequence number for this system/component pair
							_last_index[px4_sysid_index][px4_comp_id] = msg.seq;

							// Calculate new loss ratio
							const float total_sent = _total_received_supported_counter + _total_lost_counter;
							float rx_loss_percent = (_total_lost_counter / total_sent) * 100.f;

							_running_loss_percent = (rx_loss_percent * 0.5f) + (_running_loss_percent * 0.5f);
						}
					}
				}

				/* count received bytes (nread will be -1 on read error) */
				if (nread > 0) {
					_mavlink->count_rxbytes(nread);

					telemetry_status_s &tstatus = _mavlink->telemetry_status();
					tstatus.rx_message_count = _total_received_counter;
					tstatus.rx_message_count_supported = _total_received_supported_counter;
					tstatus.rx_message_lost_count = _total_lost_counter;
					tstatus.rx_message_lost_rate = _running_loss_percent;

					if (_mavlink_status_last_buffer_overrun != _status.buffer_overrun) {
						tstatus.rx_buffer_overruns++;
						_mavlink_status_last_buffer_overrun = _status.buffer_overrun;
					}

					if (_mavlink_status_last_parse_error != _status.parse_error) {
						tstatus.rx_parse_errors++;
						_mavlink_status_last_parse_error = _status.parse_error;
					}

					if (_mavlink_status_last_packet_rx_drop_count != _status.packet_rx_drop_count) {
						tstatus.rx_packet_drop_count++;
						_mavlink_status_last_packet_rx_drop_count = _status.packet_rx_drop_count;
					}
				}

#if defined(MAVLINK_UDP)
			}

#endif // MAVLINK_UDP

		} else if (ret == -1) {
			usleep(10000);
		}

		const hrt_abstime t = hrt_absolute_time();

		CheckHeartbeats(t);

		if (t - last_send_update > timeout * 1000) {
			_mission_manager.check_active_mission();
			_mission_manager.send();

			_parameters_manager.send();

			if (_mavlink->ftp_enabled()) {
				_mavlink_ftp.send();
			}

			_mavlink_log_handler.send();
			last_send_update = t;
		}

		if (_tune_publisher != nullptr) {
			_tune_publisher->publish_next_tune(t);
		}
	}
}

void *
MavlinkReceiver::start_helper(void *context)
{
	MavlinkReceiver rcv{(Mavlink *)context};
	rcv.Run();

	return nullptr;
}

void
MavlinkReceiver::receive_start(pthread_t *thread, Mavlink *parent)
{
	pthread_attr_t receiveloop_attr;
	pthread_attr_init(&receiveloop_attr);

	struct sched_param param;
	(void)pthread_attr_getschedparam(&receiveloop_attr, &param);
	param.sched_priority = SCHED_PRIORITY_MAX - 80;
	(void)pthread_attr_setschedparam(&receiveloop_attr, &param);

	pthread_attr_setstacksize(&receiveloop_attr,
				  PX4_STACK_ADJUSTED(sizeof(MavlinkReceiver) + 2840 + MAVLINK_RECEIVER_NET_ADDED_STACK));

	pthread_create(thread, &receiveloop_attr, MavlinkReceiver::start_helper, (void *)parent);

	pthread_attr_destroy(&receiveloop_attr);
}