Beispiel #1
0
/**
 * Update system alarms
 */
static void updateSystemAlarms()
{
	SystemStatsData stats;
	UAVObjStats objStats;
	EventStats evStats;
	SystemStatsGet(&stats);

	// Check heap
	if (stats.HeapRemaining < HEAP_LIMIT_CRITICAL) {
		AlarmsSet(SYSTEMALARMS_ALARM_OUTOFMEMORY, SYSTEMALARMS_ALARM_CRITICAL);
	} else if (stats.HeapRemaining < HEAP_LIMIT_WARNING) {
		AlarmsSet(SYSTEMALARMS_ALARM_OUTOFMEMORY, SYSTEMALARMS_ALARM_WARNING);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_OUTOFMEMORY);
	}

	// Check CPU load
	if (stats.CPULoad > CPULOAD_LIMIT_CRITICAL) {
		AlarmsSet(SYSTEMALARMS_ALARM_CPUOVERLOAD, SYSTEMALARMS_ALARM_CRITICAL);
	} else if (stats.CPULoad > CPULOAD_LIMIT_WARNING) {
		AlarmsSet(SYSTEMALARMS_ALARM_CPUOVERLOAD, SYSTEMALARMS_ALARM_WARNING);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_CPUOVERLOAD);
	}

	// Check for stack overflow
	if (stackOverflow == 1) {
		AlarmsSet(SYSTEMALARMS_ALARM_STACKOVERFLOW, SYSTEMALARMS_ALARM_CRITICAL);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_STACKOVERFLOW);
	}

#if defined(PIOS_INCLUDE_SDCARD)
	// Check for SD card
	if (PIOS_SDCARD_IsMounted() == 0) {
		AlarmsSet(SYSTEMALARMS_ALARM_SDCARD, SYSTEMALARMS_ALARM_ERROR);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_SDCARD);
	}
#endif

	// Check for event errors
	UAVObjGetStats(&objStats);
	EventGetStats(&evStats);
	UAVObjClearStats();
	EventClearStats();
	if (objStats.eventErrors > 0 || evStats.eventErrors > 0) {
		AlarmsSet(SYSTEMALARMS_ALARM_EVENTSYSTEM, SYSTEMALARMS_ALARM_WARNING);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_EVENTSYSTEM);
	}
}
Beispiel #2
0
/**
 * Called periodically to update the system stats
 */
static void updateStats()
{
	static portTickType lastTickCount = 0;
	SystemStatsData stats;

	// Get stats and update
	SystemStatsGet(&stats);
	stats.FlightTime = xTaskGetTickCount() * portTICK_RATE_MS;
#if defined(ARCH_POSIX) || defined(ARCH_WIN32)
	// POSIX port of FreeRTOS doesn't have xPortGetFreeHeapSize()
	stats.HeapRemaining = 10240;
#else
	stats.HeapRemaining = xPortGetFreeHeapSize();
#endif

	// Get Irq stack status
	stats.IRQStackRemaining = GetFreeIrqStackSize();

	// When idleCounterClear was not reset by the idle-task, it means the idle-task did not run
	if (idleCounterClear) {
		idleCounter = 0;
	}

	portTickType now = xTaskGetTickCount();
	if (now > lastTickCount) {
		uint32_t dT = (xTaskGetTickCount() - lastTickCount) * portTICK_RATE_MS;	// in ms
		stats.CPULoad =
			100 - (uint8_t) roundf(100.0f * ((float)idleCounter / ((float)dT / 1000.0f)) / (float)IDLE_COUNTS_PER_SEC_AT_NO_LOAD);
	} //else: TickCount has wrapped, do not calc now
	lastTickCount = now;
	idleCounterClear = 1;
	
#if defined(PIOS_INCLUDE_ADC) && defined(PIOS_ADC_USE_TEMP_SENSOR)
#if defined(STM32F2XX) || defined(STM32F4XX)
	// STM32F2XX and STM32F4XX sensor values
	float temp_voltage = 3.3f * PIOS_ADC_PinGet(5) / ((1 << 12) - 1);
	const float STM32_TEMP_V25 = 0.76f; /* V */
	const float STM32_TEMP_AVG_SLOPE = 2.5f; /* mV/C */
	stats.CPUTemp = (temp_voltage-STM32_TEMP_V25) * 1000.0f / STM32_TEMP_AVG_SLOPE + 25.0f;
#else
	float temp_voltage = 3.3f * PIOS_ADC_PinGet(0) / ((1 << 12) - 1);
	const float STM32_TEMP_V25 = 1.43f; /* V */
	const float STM32_TEMP_AVG_SLOPE = 4.3f; /* mV/C */
	stats.CPUTemp = (temp_voltage-STM32_TEMP_V25) * 1000.0f / STM32_TEMP_AVG_SLOPE + 25.0f;
#endif
#endif
	SystemStatsSet(&stats);
}
Beispiel #3
0
/**
 * Called periodically to update the system stats
 */
static void updateStats()
{
	static uint32_t lastTickCount = 0;
	SystemStatsData stats;

	// Get stats and update
	SystemStatsGet(&stats);
	stats.FlightTime = PIOS_Thread_Systime();
#if defined(ARCH_POSIX) || defined(ARCH_WIN32)
	// POSIX port of FreeRTOS doesn't have xPortGetFreeHeapSize()
	stats.HeapRemaining = 10240;
#else
	stats.HeapRemaining = PIOS_heap_get_free_size();
#endif

	// Get Irq stack status
	stats.IRQStackRemaining = GetFreeIrqStackSize();

	// When idleCounterClear was not reset by the idle-task, it means the idle-task did not run
	if (idleCounterClear) {
		idleCounter = 0;
	}

	uint32_t now = PIOS_Thread_Systime();
	if (now > lastTickCount) {
		float dT = (PIOS_Thread_Systime() - lastTickCount) / 1000.0f;

		// In the case of a slightly miscalibrated max idle count, make sure CPULoad does
		// not go negative and set an alarm inappropriately.
		float idleFraction = ((float)idleCounter / dT) / (float)IDLE_COUNTS_PER_SEC_AT_NO_LOAD;
		if (idleFraction > 1)
			stats.CPULoad = 0;
		else
			stats.CPULoad = 100 - roundf(100.0f * idleFraction);
	} //else: TickCount has wrapped, do not calc now
	lastTickCount = now;
	idleCounterClear = 1;
	
#if defined(PIOS_INCLUDE_ADC) && defined(PIOS_ADC_USE_TEMP_SENSOR)
	float temp_voltage = 3.3 * PIOS_ADC_DevicePinGet(PIOS_INTERNAL_ADC, 0) / ((1 << 12) - 1);
	const float STM32_TEMP_V25 = 1.43; /* V */
	const float STM32_TEMP_AVG_SLOPE = 4.3; /* mV/C */
	stats.CPUTemp = (temp_voltage-STM32_TEMP_V25) * 1000 / STM32_TEMP_AVG_SLOPE + 25;
#endif
	SystemStatsSet(&stats);
}
Beispiel #4
0
static void uavoMavlinkBridgeTask(void *parameters) {
	uint32_t lastSysTime;
	// Main task loop
	lastSysTime = PIOS_Thread_Systime();

	FlightBatterySettingsData batSettings = {};

	if (FlightBatterySettingsHandle() != NULL )
		FlightBatterySettingsGet(&batSettings);

	SystemStatsData systemStats;

	while (1) {
		PIOS_Thread_Sleep_Until(&lastSysTime, 1000 / TASK_RATE_HZ);

		if (stream_trigger(MAV_DATA_STREAM_EXTENDED_STATUS)) {
			FlightBatteryStateData batState = {};

			if (FlightBatteryStateHandle() != NULL )
				FlightBatteryStateGet(&batState);

			SystemStatsGet(&systemStats);

			int8_t battery_remaining = 0;
			if (batSettings.Capacity != 0) {
				if (batState.ConsumedEnergy < batSettings.Capacity) {
					battery_remaining = 100 - lroundf(batState.ConsumedEnergy / batSettings.Capacity * 100);
				}
			}

			uint16_t voltage = 0;
			if (batSettings.VoltagePin != FLIGHTBATTERYSETTINGS_VOLTAGEPIN_NONE)
				voltage = lroundf(batState.Voltage * 1000);

			uint16_t current = 0;
			if (batSettings.CurrentPin != FLIGHTBATTERYSETTINGS_CURRENTPIN_NONE)
				current = lroundf(batState.Current * 100);

			mavlink_msg_sys_status_pack(0, 200, mav_msg,
					// onboard_control_sensors_present Bitmask showing which onboard controllers and sensors are present. Value of 0: not present. Value of 1: present. Indices: 0: 3D gyro, 1: 3D acc, 2: 3D mag, 3: absolute pressure, 4: differential pressure, 5: GPS, 6: optical flow, 7: computer vision position, 8: laser based position, 9: external ground-truth (Vicon or Leica). Controllers: 10: 3D angular rate control 11: attitude stabilization, 12: yaw position, 13: z/altitude control, 14: x/y position control, 15: motor outputs / control
					0,
					// onboard_control_sensors_enabled Bitmask showing which onboard controllers and sensors are enabled:  Value of 0: not enabled. Value of 1: enabled. Indices: 0: 3D gyro, 1: 3D acc, 2: 3D mag, 3: absolute pressure, 4: differential pressure, 5: GPS, 6: optical flow, 7: computer vision position, 8: laser based position, 9: external ground-truth (Vicon or Leica). Controllers: 10: 3D angular rate control 11: attitude stabilization, 12: yaw position, 13: z/altitude control, 14: x/y position control, 15: motor outputs / control
					0,
					// onboard_control_sensors_health Bitmask showing which onboard controllers and sensors are operational or have an error:  Value of 0: not enabled. Value of 1: enabled. Indices: 0: 3D gyro, 1: 3D acc, 2: 3D mag, 3: absolute pressure, 4: differential pressure, 5: GPS, 6: optical flow, 7: computer vision position, 8: laser based position, 9: external ground-truth (Vicon or Leica). Controllers: 10: 3D angular rate control 11: attitude stabilization, 12: yaw position, 13: z/altitude control, 14: x/y position control, 15: motor outputs / control
					0,
					// load Maximum usage in percent of the mainloop time, (0%: 0, 100%: 1000) should be always below 1000
					(uint16_t)systemStats.CPULoad * 10,
					// voltage_battery Battery voltage, in millivolts (1 = 1 millivolt)
					voltage,
					// current_battery Battery current, in 10*milliamperes (1 = 10 milliampere), -1: autopilot does not measure the current
					current,
					// battery_remaining Remaining battery energy: (0%: 0, 100%: 100), -1: autopilot estimate the remaining battery
					battery_remaining,
					// drop_rate_comm Communication drops in percent, (0%: 0, 100%: 10'000), (UART, I2C, SPI, CAN), dropped packets on all links (packets that were corrupted on reception on the MAV)
					0,
					// errors_comm Communication errors (UART, I2C, SPI, CAN), dropped packets on all links (packets that were corrupted on reception on the MAV)
					0,
					// errors_count1 Autopilot-specific errors
					0,
					// errors_count2 Autopilot-specific errors
					0,
					// errors_count3 Autopilot-specific errors
					0,
					// errors_count4 Autopilot-specific errors
					0);

			send_message();
		}

		if (stream_trigger(MAV_DATA_STREAM_RC_CHANNELS)) {
			ManualControlCommandData manualState;
			FlightStatusData flightStatus;

			ManualControlCommandGet(&manualState);
			FlightStatusGet(&flightStatus);
			SystemStatsGet(&systemStats);

			//TODO connect with RSSI object and pass in last argument
			mavlink_msg_rc_channels_raw_pack(0, 200, mav_msg,
					// time_boot_ms Timestamp (milliseconds since system boot)
					systemStats.FlightTime,
					// port Servo output port (set of 8 outputs = 1 port). Most MAVs will just use one, but this allows to encode more than 8 servos.
					0,
					// chan1_raw RC channel 1 value, in microseconds
					manualState.Channel[0],
					// chan2_raw RC channel 2 value, in microseconds
					manualState.Channel[1],
					// chan3_raw RC channel 3 value, in microseconds
					manualState.Channel[2],
					// chan4_raw RC channel 4 value, in microseconds
					manualState.Channel[3],
					// chan5_raw RC channel 5 value, in microseconds
					manualState.Channel[4],
					// chan6_raw RC channel 6 value, in microseconds
					manualState.Channel[5],
					// chan7_raw RC channel 7 value, in microseconds
					manualState.Channel[6],
					// chan8_raw RC channel 8 value, in microseconds
					manualState.Channel[7],
					// rssi Receive signal strength indicator, 0: 0%, 255: 100%
					manualState.Rssi);

			send_message();
		}

		if (stream_trigger(MAV_DATA_STREAM_POSITION)) {
			GPSPositionData gpsPosData = {};
			HomeLocationData homeLocation = {};
			SystemStatsGet(&systemStats);

			if (GPSPositionHandle() != NULL )
				GPSPositionGet(&gpsPosData);
			if (HomeLocationHandle() != NULL )
				HomeLocationGet(&homeLocation);
			SystemStatsGet(&systemStats);

			uint8_t gps_fix_type;
			switch (gpsPosData.Status)
			{
			case GPSPOSITION_STATUS_NOGPS:
				gps_fix_type = 0;
				break;
			case GPSPOSITION_STATUS_NOFIX:
				gps_fix_type = 1;
				break;
			case GPSPOSITION_STATUS_FIX2D:
				gps_fix_type = 2;
				break;
			case GPSPOSITION_STATUS_FIX3D:
			case GPSPOSITION_STATUS_DIFF3D:
				gps_fix_type = 3;
				break;
			default:
				gps_fix_type = 0;
				break;
			}

			mavlink_msg_gps_raw_int_pack(0, 200, mav_msg,
					// time_usec Timestamp (microseconds since UNIX epoch or microseconds since system boot)
					(uint64_t)systemStats.FlightTime * 1000,
					// fix_type 0-1: no fix, 2: 2D fix, 3: 3D fix. Some applications will not use the value of this field unless it is at least two, so always correctly fill in the fix.
					gps_fix_type,
					// lat Latitude in 1E7 degrees
					gpsPosData.Latitude,
					// lon Longitude in 1E7 degrees
					gpsPosData.Longitude,
					// alt Altitude in 1E3 meters (millimeters) above MSL
					gpsPosData.Altitude * 1000,
					// eph GPS HDOP horizontal dilution of position in cm (m*100). If unknown, set to: 65535
					gpsPosData.HDOP * 100,
					// epv GPS VDOP horizontal dilution of position in cm (m*100). If unknown, set to: 65535
					gpsPosData.VDOP * 100,
					// vel GPS ground speed (m/s * 100). If unknown, set to: 65535
					gpsPosData.Groundspeed * 100,
					// cog Course over ground (NOT heading, but direction of movement) in degrees * 100, 0.0..359.99 degrees. If unknown, set to: 65535
					gpsPosData.Heading * 100,
					// satellites_visible Number of satellites visible. If unknown, set to 255
					gpsPosData.Satellites);

			send_message();

			mavlink_msg_gps_global_origin_pack(0, 200, mav_msg,
					// latitude Latitude (WGS84), expressed as * 1E7
					homeLocation.Latitude,
					// longitude Longitude (WGS84), expressed as * 1E7
					homeLocation.Longitude,
					// altitude Altitude(WGS84), expressed as * 1000
					homeLocation.Altitude * 1000);

			send_message();

			//TODO add waypoint nav stuff
			//wp_target_bearing
			//wp_dist = mavlink_msg_nav_controller_output_get_wp_dist(&msg);
			//alt_error = mavlink_msg_nav_controller_output_get_alt_error(&msg);
			//aspd_error = mavlink_msg_nav_controller_output_get_aspd_error(&msg);
			//xtrack_error = mavlink_msg_nav_controller_output_get_xtrack_error(&msg);
			//mavlink_msg_nav_controller_output_pack
			//wp_number
			//mavlink_msg_mission_current_pack
		}

		if (stream_trigger(MAV_DATA_STREAM_EXTRA1)) {
			AttitudeActualData attActual;
			SystemStatsData systemStats;

			AttitudeActualGet(&attActual);
			SystemStatsGet(&systemStats);

			mavlink_msg_attitude_pack(0, 200, mav_msg,
					// time_boot_ms Timestamp (milliseconds since system boot)
					systemStats.FlightTime,
					// roll Roll angle (rad)
					attActual.Roll * DEG2RAD,
					// pitch Pitch angle (rad)
					attActual.Pitch * DEG2RAD,
					// yaw Yaw angle (rad)
					attActual.Yaw * DEG2RAD,
					// rollspeed Roll angular speed (rad/s)
					0,
					// pitchspeed Pitch angular speed (rad/s)
					0,
					// yawspeed Yaw angular speed (rad/s)
					0);

			send_message();
		}

		if (stream_trigger(MAV_DATA_STREAM_EXTRA2)) {
			ActuatorDesiredData actDesired;
			AttitudeActualData attActual;
			AirspeedActualData airspeedActual = {};
			GPSPositionData gpsPosData = {};
			BaroAltitudeData baroAltitude = {};
			FlightStatusData flightStatus;

			if (AirspeedActualHandle() != NULL )
				AirspeedActualGet(&airspeedActual);
			if (GPSPositionHandle() != NULL )
				GPSPositionGet(&gpsPosData);
			if (BaroAltitudeHandle() != NULL )
				BaroAltitudeGet(&baroAltitude);
			ActuatorDesiredGet(&actDesired);
			AttitudeActualGet(&attActual);
			FlightStatusGet(&flightStatus);

			float altitude = 0;
			if (BaroAltitudeHandle() != NULL)
				altitude = baroAltitude.Altitude;
			else if (GPSPositionHandle() != NULL)
				altitude = gpsPosData.Altitude;

			// round attActual.Yaw to nearest int and transfer from (-180 ... 180) to (0 ... 360)
			int16_t heading = lroundf(attActual.Yaw);
			if (heading < 0)
				heading += 360;

			mavlink_msg_vfr_hud_pack(0, 200, mav_msg,
					// airspeed Current airspeed in m/s
					airspeedActual.TrueAirspeed,
					// groundspeed Current ground speed in m/s
					gpsPosData.Groundspeed,
					// heading Current heading in degrees, in compass units (0..360, 0=north)
					heading,
					// throttle Current throttle setting in integer percent, 0 to 100
					actDesired.Throttle * 100,
					// alt Current altitude (MSL), in meters
					altitude,
					// climb Current climb rate in meters/second
					0);

			send_message();

			uint8_t armed_mode = 0;
			if (flightStatus.Armed == FLIGHTSTATUS_ARMED_ARMED)
				armed_mode |= MAV_MODE_FLAG_SAFETY_ARMED;

			uint8_t custom_mode = CUSTOM_MODE_STAB;

			switch (flightStatus.FlightMode) {
				case FLIGHTSTATUS_FLIGHTMODE_MANUAL:
				case FLIGHTSTATUS_FLIGHTMODE_MWRATE:
				case FLIGHTSTATUS_FLIGHTMODE_VIRTUALBAR:
				case FLIGHTSTATUS_FLIGHTMODE_HORIZON:
					/* Kinda a catch all */
					custom_mode = CUSTOM_MODE_SPORT;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_ACRO:
				case FLIGHTSTATUS_FLIGHTMODE_AXISLOCK:
					custom_mode = CUSTOM_MODE_ACRO;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_STABILIZED1:
				case FLIGHTSTATUS_FLIGHTMODE_STABILIZED2:
				case FLIGHTSTATUS_FLIGHTMODE_STABILIZED3:
					/* May want these three to try and
					 * infer based on roll axis */
				case FLIGHTSTATUS_FLIGHTMODE_LEVELING:
					custom_mode = CUSTOM_MODE_STAB;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_AUTOTUNE:
					custom_mode = CUSTOM_MODE_DRIFT;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_ALTITUDEHOLD:
					custom_mode = CUSTOM_MODE_ALTH;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_RETURNTOHOME:
					custom_mode = CUSTOM_MODE_RTL;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_TABLETCONTROL:
				case FLIGHTSTATUS_FLIGHTMODE_POSITIONHOLD:
					custom_mode = CUSTOM_MODE_POSH;
					break;
				case FLIGHTSTATUS_FLIGHTMODE_PATHPLANNER:
					custom_mode = CUSTOM_MODE_AUTO;
					break;
			}

			mavlink_msg_heartbeat_pack(0, 200, mav_msg,
					// type Type of the MAV (quadrotor, helicopter, etc., up to 15 types, defined in MAV_TYPE ENUM)
					MAV_TYPE_GENERIC,
					// autopilot Autopilot type / class. defined in MAV_AUTOPILOT ENUM
					MAV_AUTOPILOT_GENERIC,
					// base_mode System mode bitfield, see MAV_MODE_FLAGS ENUM in mavlink/include/mavlink_types.h
					armed_mode,
					// custom_mode A bitfield for use for autopilot-specific flags.
					custom_mode,
					// system_status System status flag, see MAV_STATE ENUM
					0);

			send_message();
		}
	}
}
Beispiel #5
0
/**
 * Update system alarms
 */
static void updateSystemAlarms()
{
	SystemStatsData stats;
	UAVObjStats objStats;
	EventStats evStats;
	SystemStatsGet(&stats);

	// Check heap, IRQ stack and malloc failures
	if (PIOS_heap_malloc_failed_p()
	     || (stats.HeapRemaining < HEAP_LIMIT_CRITICAL)
#if !defined(ARCH_POSIX) && !defined(ARCH_WIN32) && defined(CHECK_IRQ_STACK)
	     || (stats.IRQStackRemaining < IRQSTACK_LIMIT_CRITICAL)
#endif
	    ) {
		AlarmsSet(SYSTEMALARMS_ALARM_OUTOFMEMORY, SYSTEMALARMS_ALARM_CRITICAL);
	} else if (
		(stats.HeapRemaining < HEAP_LIMIT_WARNING)
#if !defined(ARCH_POSIX) && !defined(ARCH_WIN32) && defined(CHECK_IRQ_STACK)
	     || (stats.IRQStackRemaining < IRQSTACK_LIMIT_WARNING)
#endif
	    ) {
		AlarmsSet(SYSTEMALARMS_ALARM_OUTOFMEMORY, SYSTEMALARMS_ALARM_WARNING);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_OUTOFMEMORY);
	}

	// Check CPU load
	if (stats.CPULoad > CPULOAD_LIMIT_CRITICAL) {
		AlarmsSet(SYSTEMALARMS_ALARM_CPUOVERLOAD, SYSTEMALARMS_ALARM_CRITICAL);
	} else if (stats.CPULoad > CPULOAD_LIMIT_WARNING) {
		AlarmsSet(SYSTEMALARMS_ALARM_CPUOVERLOAD, SYSTEMALARMS_ALARM_WARNING);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_CPUOVERLOAD);
	}

	// Check for stack overflow
	if (stackOverflow) {
		AlarmsSet(SYSTEMALARMS_ALARM_STACKOVERFLOW, SYSTEMALARMS_ALARM_CRITICAL);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_STACKOVERFLOW);
	}

	// Check for event errors
	UAVObjGetStats(&objStats);
	EventGetStats(&evStats);
	UAVObjClearStats();
	EventClearStats();
	if (objStats.eventCallbackErrors > 0 || objStats.eventQueueErrors > 0  || evStats.eventErrors > 0) {
		AlarmsSet(SYSTEMALARMS_ALARM_EVENTSYSTEM, SYSTEMALARMS_ALARM_WARNING);
	} else {
		AlarmsClear(SYSTEMALARMS_ALARM_EVENTSYSTEM);
	}
	
	if (objStats.lastCallbackErrorID || objStats.lastQueueErrorID || evStats.lastErrorID) {
		SystemStatsData sysStats;
		SystemStatsGet(&sysStats);
		sysStats.EventSystemWarningID = evStats.lastErrorID;
		sysStats.ObjectManagerCallbackID = objStats.lastCallbackErrorID;
		sysStats.ObjectManagerQueueID = objStats.lastQueueErrorID;
		SystemStatsSet(&sysStats);
	}
		
}
/**
 * Processes queue events
 */
static void processObjEvent(UAVObjEvent * ev)
{
	UAVObjMetadata metadata;
	//	FlightTelemetryStatsData flightStats;
	//	GCSTelemetryStatsData gcsTelemetryStatsData;
	//	int32_t retries;
	//	int32_t success;

	if (ev->obj == 0) {
		updateTelemetryStats();
	} else if (ev->obj == GCSTelemetryStatsHandle()) {
		gcsTelemetryStatsUpdated();
	} else if (ev->obj == TelemetrySettingsHandle()) {
		updateSettings();
	} else {

		// Get object metadata
		UAVObjGetMetadata(ev->obj, &metadata);

		// If this is a metaobject then make necessary telemetry updates
		if (UAVObjIsMetaobject(ev->obj)) {
			updateObject(UAVObjGetLinkedObj(ev->obj));	// linked object will be the actual object the metadata are for
		}

		mavlink_message_t msg;

		mavlink_system.sysid = 20;
		mavlink_system.compid = MAV_COMP_ID_IMU;
		mavlink_system.type = MAV_TYPE_FIXED_WING;
		uint8_t mavClass = MAV_AUTOPILOT_OPENPILOT;

		AlarmsClear(SYSTEMALARMS_ALARM_TELEMETRY);

		// Setup type and object id fields
		uint32_t objId = UAVObjGetID(ev->obj);

		//		uint64_t timeStamp = 0;
		switch(objId) {
		case BAROALTITUDE_OBJID:
		{
			BaroAltitudeGet(&baroAltitude);
			pressure.press_abs = baroAltitude.Pressure*10.0f;
			pressure.temperature = baroAltitude.Temperature*100.0f;
			mavlink_msg_scaled_pressure_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &pressure);
			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);
			break;
		}
		case FLIGHTTELEMETRYSTATS_OBJID:
		{
			//				FlightTelemetryStatsData flightTelemetryStats;
			FlightTelemetryStatsGet(&flightStats);

			// XXX this is a hack to make it think it got a confirmed
			// connection
			flightStats.Status = FLIGHTTELEMETRYSTATS_STATUS_CONNECTED;
			GCSTelemetryStatsGet(&gcsTelemetryStatsData);
			gcsTelemetryStatsData.Status = GCSTELEMETRYSTATS_STATUS_CONNECTED;
			//
			//
			//				//mavlink_msg_heartbeat_send(MAVLINK_COMM_0,mavlink_system.type,mavClass);
			//				mavlink_msg_heartbeat_pack(mavlink_system.sysid, mavlink_system.compid, &msg, mavlink_system.type, mavClass);
			//				// Copy the message to the send buffer
			//				uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			//				// Send buffer
			//				PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);
			break;
		}
		case SYSTEMSTATS_OBJID:
		{
			FlightStatusData flightStatus;
			FlightStatusGet(&flightStatus);

			uint8_t system_state = MAV_STATE_UNINIT;
			uint8_t base_mode = 0;
			uint8_t custom_mode = 0;

			// Set flight mode
			switch (flightStatus.FlightMode)
			{
			case FLIGHTSTATUS_FLIGHTMODE_MANUAL:
				base_mode |= MAV_MODE_FLAG_MANUAL_INPUT_ENABLED;
				break;
			case FLIGHTSTATUS_FLIGHTMODE_POSITIONHOLD:
				base_mode |= MAV_MODE_FLAG_GUIDED_ENABLED;
				break;
			case FLIGHTSTATUS_FLIGHTMODE_STABILIZED1:
				base_mode |= MAV_MODE_FLAG_STABILIZE_ENABLED;
				break;
			case FLIGHTSTATUS_FLIGHTMODE_STABILIZED2:
				base_mode |= MAV_MODE_FLAG_GUIDED_ENABLED;
				break;
			case FLIGHTSTATUS_FLIGHTMODE_STABILIZED3:
				base_mode |= MAV_MODE_FLAG_AUTO_ENABLED;
				break;
			case FLIGHTSTATUS_FLIGHTMODE_VELOCITYCONTROL:
				base_mode |= MAV_MODE_FLAG_GUIDED_ENABLED;
				break;
			default:
				base_mode |= MAV_MODE_FLAG_MANUAL_INPUT_ENABLED;
				break;
			}

			// Set arming state
			switch (flightStatus.Armed)
			{
			case FLIGHTSTATUS_ARMED_ARMING:
			case FLIGHTSTATUS_ARMED_ARMED:
				system_state = MAV_STATE_ACTIVE;
				base_mode |= MAV_MODE_FLAG_SAFETY_ARMED;
				break;
			case FLIGHTSTATUS_ARMED_DISARMED:
				system_state = MAV_STATE_STANDBY;
				base_mode &= !MAV_MODE_FLAG_SAFETY_ARMED;
				break;
			}

			// Set HIL
			if (hilEnabled) base_mode |= MAV_MODE_FLAG_HIL_ENABLED;

			mavlink_msg_heartbeat_send(MAVLINK_COMM_0, mavlink_system.type, mavClass, base_mode, custom_mode, system_state);

			SystemStatsData stats;
			SystemStatsGet(&stats);
			FlightBatteryStateData flightBatteryData;
			FlightBatteryStateGet(&flightBatteryData);
			FlightBatterySettingsData flightBatterySettings;
			FlightBatterySettingsGet(&flightBatterySettings);

			uint16_t batteryVoltage = (uint16_t)(flightBatteryData.Voltage*1000.0f);
			int16_t batteryCurrent = -1; // -1: Not present / not estimated
			int8_t batteryPercent = -1; // -1: Not present / not estimated
			//			if (flightBatterySettings.SensorCalibrations[FLIGHTBATTERYSETTINGS_SENSORCALIBRATIONS_CURRENTFACTOR] == 0)
			//			{
			// Factor is zero, sensor is not present
			// Estimate remaining capacity based on lipo curve
			batteryPercent = 100.0f*((flightBatteryData.Voltage - 9.6f)/(12.6f - 9.6f));
			//			}
			//			else
			//			{
			//				// Use capacity and current
			//				batteryPercent = 100.0f*((flightBatterySettings.Capacity - flightBatteryData.ConsumedEnergy) / flightBatterySettings.Capacity);
			//				batteryCurrent = flightBatteryData.Current*100;
			//			}

				mavlink_msg_sys_status_send(MAVLINK_COMM_0, 0xFF, 0xFF, 0xFF, ((uint16_t)stats.CPULoad*10), batteryVoltage, batteryCurrent, batteryPercent, 0, 0, 0, 0, 0, 0);
//				// Copy the message to the send buffer
//				uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
//				// Send buffer
//				PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);
			break;
		}
		case ATTITUDERAW_OBJID:
		{
			AttitudeRawGet(&attitudeRaw);

			// Copy data
			attitude_raw.xacc = attitudeRaw.accels[ATTITUDERAW_ACCELS_X];
			attitude_raw.yacc = attitudeRaw.accels[ATTITUDERAW_ACCELS_Y];
			attitude_raw.zacc = attitudeRaw.accels[ATTITUDERAW_ACCELS_Z];
			attitude_raw.xgyro = attitudeRaw.gyros[ATTITUDERAW_GYROS_X];
			attitude_raw.ygyro = attitudeRaw.gyros[ATTITUDERAW_GYROS_Y];
			attitude_raw.zgyro = attitudeRaw.gyros[ATTITUDERAW_GYROS_Z];
			attitude_raw.xmag = attitudeRaw.magnetometers[ATTITUDERAW_MAGNETOMETERS_X];
			attitude_raw.ymag = attitudeRaw.magnetometers[ATTITUDERAW_MAGNETOMETERS_Y];
			attitude_raw.zmag = attitudeRaw.magnetometers[ATTITUDERAW_MAGNETOMETERS_Z];

			mavlink_msg_raw_imu_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &attitude_raw);
			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);

			if (hilEnabled)
			{
				mavlink_hil_controls_t controls;

				// Copy data
				controls.roll_ailerons = 0.1;
				controls.pitch_elevator = 0.1;
				controls.yaw_rudder = 0.0;
				controls.throttle = 0.8;

				mavlink_msg_hil_controls_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &controls);
				// Copy the message to the send buffer
				len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
				// Send buffer
				PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);
			}
			break;
		}
		case ATTITUDEMATRIX_OBJID:
		{
			AttitudeMatrixGet(&attitudeMatrix);

			// Copy data
			attitude.roll = attitudeMatrix.Roll;
			attitude.pitch = attitudeMatrix.Pitch;
			attitude.yaw = attitudeMatrix.Yaw;

			attitude.rollspeed = attitudeMatrix.AngularRates[0];
			attitude.pitchspeed = attitudeMatrix.AngularRates[1];
			attitude.yawspeed = attitudeMatrix.AngularRates[2];

			mavlink_msg_attitude_encode(mavlink_system.sysid,
					mavlink_system.compid, &msg, &attitude);
			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);
			break;
		}
		case GPSPOSITION_OBJID:
		{
			GPSPositionGet(&gpsPosition);
			gps_raw.time_usec = 0;
			gps_raw.lat = gpsPosition.Latitude*10;
			gps_raw.lon = gpsPosition.Longitude*10;
			gps_raw.alt = gpsPosition.Altitude*10;
			gps_raw.eph = gpsPosition.HDOP*100;
			gps_raw.epv = gpsPosition.VDOP*100;
			gps_raw.cog = gpsPosition.Heading*100;
			gps_raw.satellites_visible = gpsPosition.Satellites;
			gps_raw.fix_type = gpsPosition.Status;
			mavlink_msg_gps_raw_int_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &gps_raw);
			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);

			//			mavlink_msg_gps_raw_int_send(MAVLINK_COMM_0, gps_raw.usec, gps_raw.lat, gps_raw.lon, gps_raw.alt, gps_raw.eph, gps_raw.epv, gps_raw.hdg, gps_raw.satellites_visible, gps_raw.fix_type, 0);

			break;
		}
		case POSITIONACTUAL_OBJID:
		{
			PositionActualData pos;
			PositionActualGet(&pos);
			mavlink_local_position_ned_t m_pos;
			m_pos.time_boot_ms = 0;
			m_pos.x = pos.North;
			m_pos.y = pos.East;
			m_pos.z = pos.Down;
			m_pos.vx = 0.0f;
			m_pos.vy = 0.0f;
			m_pos.vz = 0.0f;

			mavlink_msg_local_position_ned_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &m_pos);

			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(telemetryPort, mavlinkTxBuf, len);
		}
		break;
		case ACTUATORCOMMAND_OBJID:
		{
			mavlink_rc_channels_scaled_t rc;
			float val;
			ManualControlCommandRollGet(&val);
			rc.chan1_scaled = val*1000;
			ManualControlCommandPitchGet(&val);
			rc.chan2_scaled = val*1000;
			ManualControlCommandYawGet(&val);
			rc.chan3_scaled = val*1000;
			ManualControlCommandThrottleGet(&val);
			rc.chan4_scaled = val*1000;

			ActuatorCommandData act;
			ActuatorCommandGet(&act);

			rc.chan5_scaled = act.Channel[0];
			rc.chan6_scaled = act.Channel[1];
			rc.chan7_scaled = act.Channel[2];
			rc.chan8_scaled = act.Channel[3];

			ManualControlCommandData cmd;
			ManualControlCommandGet(&cmd);

			rc.rssi = ((uint8_t)(cmd.Connected == MANUALCONTROLCOMMAND_CONNECTED_TRUE))*255;
			rc.port = 0;

			mavlink_msg_rc_channels_scaled_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &rc);


			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(PIOS_COM_TELEM_RF, mavlinkTxBuf, len);
			break;
		}
		case MANUALCONTROLCOMMAND_OBJID:
		{
			mavlink_rc_channels_scaled_t rc;
			float val;
			ManualControlCommandRollGet(&val);
			rc.chan1_scaled = val*1000;
			ManualControlCommandPitchGet(&val);
			rc.chan2_scaled = val*1000;
			ManualControlCommandYawGet(&val);
			rc.chan3_scaled = val*1000;
			ManualControlCommandThrottleGet(&val);
			rc.chan4_scaled = val*1000;

			rc.chan5_scaled = 0;
			rc.chan6_scaled = 0;
			rc.chan7_scaled = 0;
			rc.chan8_scaled = 0;

			ManualControlCommandData cmd;
			ManualControlCommandGet(&cmd);

			rc.rssi = ((uint8_t)(cmd.Connected == MANUALCONTROLCOMMAND_CONNECTED_TRUE))*255;
			rc.port = 0;

			mavlink_msg_rc_channels_scaled_encode(mavlink_system.sysid, mavlink_system.compid, &msg, &rc);


			// Copy the message to the send buffer
			uint16_t len = mavlink_msg_to_send_buffer(mavlinkTxBuf, &msg);
			// Send buffer
			PIOS_COM_SendBufferNonBlocking(PIOS_COM_TELEM_RF, mavlinkTxBuf, len);
			break;
		}
		default:
		{
			//printf("unknown object: %x\n",(unsigned int)objId);
			break;
		}
		}
	}
}
Beispiel #7
0
/**
 * Update system alarms
 */
static void updateSystemAlarms()
{
    SystemStatsData stats;
    UAVObjStats objStats;
    EventStats evStats;
    SystemStatsGet(&stats);

    // Check heap, IRQ stack and malloc failures
    if ( mallocFailed
            || (stats.HeapRemaining < HEAP_LIMIT_CRITICAL)
#if !defined(ARCH_POSIX) && !defined(ARCH_WIN32) && defined(CHECK_IRQ_STACK)
            || (stats.IRQStackRemaining < IRQSTACK_LIMIT_CRITICAL)
#endif
       ) {
        AlarmsSet(SYSTEMALARMS_ALARM_OUTOFMEMORY, SYSTEMALARMS_ALARM_CRITICAL);
    } else if (
        (stats.HeapRemaining < HEAP_LIMIT_WARNING)
#if !defined(ARCH_POSIX) && !defined(ARCH_WIN32) && defined(CHECK_IRQ_STACK)
        || (stats.IRQStackRemaining < IRQSTACK_LIMIT_WARNING)
#endif
    ) {
        AlarmsSet(SYSTEMALARMS_ALARM_OUTOFMEMORY, SYSTEMALARMS_ALARM_WARNING);
    } else {
        AlarmsClear(SYSTEMALARMS_ALARM_OUTOFMEMORY);
    }

    // Check CPU load
    if (stats.CPULoad > CPULOAD_LIMIT_CRITICAL) {
        AlarmsSet(SYSTEMALARMS_ALARM_CPUOVERLOAD, SYSTEMALARMS_ALARM_CRITICAL);
    } else if (stats.CPULoad > CPULOAD_LIMIT_WARNING) {
        AlarmsSet(SYSTEMALARMS_ALARM_CPUOVERLOAD, SYSTEMALARMS_ALARM_WARNING);
    } else {
        AlarmsClear(SYSTEMALARMS_ALARM_CPUOVERLOAD);
    }

    // Check for stack overflow
    if (stackOverflow) {
        AlarmsSet(SYSTEMALARMS_ALARM_STACKOVERFLOW, SYSTEMALARMS_ALARM_CRITICAL);
    } else {
        AlarmsClear(SYSTEMALARMS_ALARM_STACKOVERFLOW);
    }

#if defined(PIOS_INCLUDE_SDCARD)
    // Check for SD card
    if (PIOS_SDCARD_IsMounted() == 0) {
        AlarmsSet(SYSTEMALARMS_ALARM_SDCARD, SYSTEMALARMS_ALARM_ERROR);
    } else {
        AlarmsClear(SYSTEMALARMS_ALARM_SDCARD);
    }
#endif

    // Check for event errors
    UAVObjGetStats(&objStats);
    EventGetStats(&evStats);
    UAVObjClearStats();
    EventClearStats();
    if (objStats.eventErrors > 0 || evStats.eventErrors > 0) {
        AlarmsSet(SYSTEMALARMS_ALARM_EVENTSYSTEM, SYSTEMALARMS_ALARM_WARNING);
    } else {
        AlarmsClear(SYSTEMALARMS_ALARM_EVENTSYSTEM);
    }
}