/**************************************************************************** * * (c) 2009-2016 QGROUNDCONTROL PROJECT * * QGroundControl is licensed according to the terms in the file * COPYING.md in the root of the source code directory. * ****************************************************************************/ #include #include #include #include #include "Vehicle.h" #include "MAVLinkProtocol.h" #include "FirmwarePluginManager.h" #include "LinkManager.h" #include "FirmwarePlugin.h" #include "UAS.h" #include "JoystickManager.h" #include "MissionManager.h" #include "MissionController.h" #include "PlanMasterController.h" #include "GeoFenceManager.h" #include "RallyPointManager.h" #include "CoordinateVector.h" #include "ParameterManager.h" #include "QGCApplication.h" #include "QGCImageProvider.h" #include "AudioOutput.h" #include "FollowMe.h" #include "MissionCommandTree.h" #include "QGroundControlQmlGlobal.h" #include "SettingsManager.h" #include "QGCQGeoCoordinate.h" #include "QGCCorePlugin.h" #include "ADSBVehicle.h" #include "QGCCameraManager.h" #include "VideoReceiver.h" #include "VideoManager.h" QGC_LOGGING_CATEGORY(VehicleLog, "VehicleLog") #define UPDATE_TIMER 50 #define DEFAULT_LAT 38.965767f #define DEFAULT_LON -120.083923f const QString guided_mode_not_supported_by_vehicle = QObject::tr("Guided mode not supported by Vehicle."); const char* Vehicle::_settingsGroup = "Vehicle%1"; // %1 replaced with mavlink system id const char* Vehicle::_joystickModeSettingsKey = "JoystickMode"; const char* Vehicle::_joystickEnabledSettingsKey = "JoystickEnabled"; const char* Vehicle::_rollFactName = "roll"; const char* Vehicle::_pitchFactName = "pitch"; const char* Vehicle::_headingFactName = "heading"; const char* Vehicle::_rollRateFactName = "rollRate"; const char* Vehicle::_pitchRateFactName = "pitchRate"; const char* Vehicle::_yawRateFactName = "yawRate"; const char* Vehicle::_airSpeedFactName = "airSpeed"; const char* Vehicle::_groundSpeedFactName = "groundSpeed"; const char* Vehicle::_climbRateFactName = "climbRate"; const char* Vehicle::_altitudeRelativeFactName = "altitudeRelative"; const char* Vehicle::_altitudeAMSLFactName = "altitudeAMSL"; const char* Vehicle::_flightDistanceFactName = "flightDistance"; const char* Vehicle::_flightTimeFactName = "flightTime"; const char* Vehicle::_distanceToHomeFactName = "distanceToHome"; const char* Vehicle::_hobbsFactName = "hobbs"; const char* Vehicle::_gpsFactGroupName = "gps"; const char* Vehicle::_batteryFactGroupName = "battery"; const char* Vehicle::_windFactGroupName = "wind"; const char* Vehicle::_vibrationFactGroupName = "vibration"; const char* Vehicle::_temperatureFactGroupName = "temperature"; const char* Vehicle::_clockFactGroupName = "clock"; Vehicle::Vehicle(LinkInterface* link, int vehicleId, int defaultComponentId, MAV_AUTOPILOT firmwareType, MAV_TYPE vehicleType, FirmwarePluginManager* firmwarePluginManager, JoystickManager* joystickManager) : FactGroup(_vehicleUIUpdateRateMSecs, ":/json/Vehicle/VehicleFact.json") , _id(vehicleId) , _defaultComponentId(defaultComponentId) , _active(false) , _offlineEditingVehicle(false) , _firmwareType(firmwareType) , _vehicleType(vehicleType) , _firmwarePlugin(NULL) , _firmwarePluginInstanceData(NULL) , _autopilotPlugin(NULL) , _mavlink(NULL) , _soloFirmware(false) , _toolbox(qgcApp()->toolbox()) , _settingsManager(_toolbox->settingsManager()) , _joystickMode(JoystickModeRC) , _joystickEnabled(false) , _uas(NULL) , _mav(NULL) , _currentMessageCount(0) , _messageCount(0) , _currentErrorCount(0) , _currentWarningCount(0) , _currentNormalCount(0) , _currentMessageType(MessageNone) , _updateCount(0) , _rcRSSI(255) , _rcRSSIstore(255) , _autoDisconnect(false) , _flying(false) , _landing(false) , _vtolInFwdFlight(false) , _onboardControlSensorsPresent(0) , _onboardControlSensorsEnabled(0) , _onboardControlSensorsHealth(0) , _onboardControlSensorsUnhealthy(0) , _gpsRawIntMessageAvailable(false) , _globalPositionIntMessageAvailable(false) , _defaultCruiseSpeed(_settingsManager->appSettings()->offlineEditingCruiseSpeed()->rawValue().toDouble()) , _defaultHoverSpeed(_settingsManager->appSettings()->offlineEditingHoverSpeed()->rawValue().toDouble()) , _telemetryRRSSI(0) , _telemetryLRSSI(0) , _telemetryRXErrors(0) , _telemetryFixed(0) , _telemetryTXBuffer(0) , _telemetryLNoise(0) , _telemetryRNoise(0) , _maxProtoVersion(0) , _vehicleCapabilitiesKnown(false) , _capabilityBits(0) , _highLatencyLink(false) , _cameras(NULL) , _connectionLost(false) , _connectionLostEnabled(true) , _initialPlanRequestComplete(false) , _missionManager(NULL) , _missionManagerInitialRequestSent(false) , _geoFenceManager(NULL) , _geoFenceManagerInitialRequestSent(false) , _rallyPointManager(NULL) , _rallyPointManagerInitialRequestSent(false) , _parameterManager(NULL) , _armed(false) , _base_mode(0) , _custom_mode(0) , _nextSendMessageMultipleIndex(0) , _firmwarePluginManager(firmwarePluginManager) , _joystickManager(joystickManager) , _flowImageIndex(0) , _allLinksInactiveSent(false) , _messagesReceived(0) , _messagesSent(0) , _messagesLost(0) , _messageSeq(0) , _compID(0) , _heardFrom(false) , _firmwareMajorVersion(versionNotSetValue) , _firmwareMinorVersion(versionNotSetValue) , _firmwarePatchVersion(versionNotSetValue) , _firmwareCustomMajorVersion(versionNotSetValue) , _firmwareCustomMinorVersion(versionNotSetValue) , _firmwareCustomPatchVersion(versionNotSetValue) , _firmwareVersionType(FIRMWARE_VERSION_TYPE_OFFICIAL) , _gitHash(versionNotSetValue) , _uid(0) , _lastAnnouncedLowBatteryPercent(100) , _rollFact (0, _rollFactName, FactMetaData::valueTypeDouble) , _pitchFact (0, _pitchFactName, FactMetaData::valueTypeDouble) , _headingFact (0, _headingFactName, FactMetaData::valueTypeDouble) , _rollRateFact (0, _rollRateFactName, FactMetaData::valueTypeDouble) , _pitchRateFact (0, _pitchRateFactName, FactMetaData::valueTypeDouble) , _yawRateFact (0, _yawRateFactName, FactMetaData::valueTypeDouble) , _groundSpeedFact (0, _groundSpeedFactName, FactMetaData::valueTypeDouble) , _airSpeedFact (0, _airSpeedFactName, FactMetaData::valueTypeDouble) , _climbRateFact (0, _climbRateFactName, FactMetaData::valueTypeDouble) , _altitudeRelativeFact (0, _altitudeRelativeFactName, FactMetaData::valueTypeDouble) , _altitudeAMSLFact (0, _altitudeAMSLFactName, FactMetaData::valueTypeDouble) , _flightDistanceFact (0, _flightDistanceFactName, FactMetaData::valueTypeDouble) , _flightTimeFact (0, _flightTimeFactName, FactMetaData::valueTypeElapsedTimeInSeconds) , _distanceToHomeFact (0, _distanceToHomeFactName, FactMetaData::valueTypeDouble) , _hobbsFact (0, _hobbsFactName, FactMetaData::valueTypeString) , _gpsFactGroup(this) , _batteryFactGroup(this) , _windFactGroup(this) , _vibrationFactGroup(this) , _temperatureFactGroup(this) , _clockFactGroup(this) { _addLink(link); connect(_joystickManager, &JoystickManager::activeJoystickChanged, this, &Vehicle::_loadSettings); connect(qgcApp()->toolbox()->multiVehicleManager(), &MultiVehicleManager::activeVehicleAvailableChanged, this, &Vehicle::_loadSettings); _mavlink = _toolbox->mavlinkProtocol(); connect(_mavlink, &MAVLinkProtocol::messageReceived, this, &Vehicle::_mavlinkMessageReceived); connect(this, &Vehicle::_sendMessageOnLinkOnThread, this, &Vehicle::_sendMessageOnLink, Qt::QueuedConnection); connect(this, &Vehicle::flightModeChanged, this, &Vehicle::_handleFlightModeChanged); connect(this, &Vehicle::armedChanged, this, &Vehicle::_announceArmedChanged); connect(_toolbox->multiVehicleManager(), &MultiVehicleManager::parameterReadyVehicleAvailableChanged, this, &Vehicle::_vehicleParamLoaded); _uas = new UAS(_mavlink, this, _firmwarePluginManager); connect(_uas, &UAS::imageReady, this, &Vehicle::_imageReady); connect(this, &Vehicle::remoteControlRSSIChanged, this, &Vehicle::_remoteControlRSSIChanged); _commonInit(); _autopilotPlugin = _firmwarePlugin->autopilotPlugin(this); // connect this vehicle to the follow me handle manager connect(this, &Vehicle::flightModeChanged,_toolbox->followMe(), &FollowMe::followMeHandleManager); // PreArm Error self-destruct timer connect(&_prearmErrorTimer, &QTimer::timeout, this, &Vehicle::_prearmErrorTimeout); _prearmErrorTimer.setInterval(_prearmErrorTimeoutMSecs); _prearmErrorTimer.setSingleShot(true); // Connection Lost timer _connectionLostTimer.setInterval(_connectionLostTimeoutMSecs); _connectionLostTimer.setSingleShot(false); _connectionLostTimer.start(); connect(&_connectionLostTimer, &QTimer::timeout, this, &Vehicle::_connectionLostTimeout); // Send MAV_CMD ack timer _mavCommandAckTimer.setSingleShot(true); _mavCommandAckTimer.setInterval(_highLatencyLink ? _mavCommandAckTimeoutMSecsHighLatency : _mavCommandAckTimeoutMSecs); connect(&_mavCommandAckTimer, &QTimer::timeout, this, &Vehicle::_sendMavCommandAgain); _mav = uas(); // Listen for system messages connect(_toolbox->uasMessageHandler(), &UASMessageHandler::textMessageCountChanged, this, &Vehicle::_handleTextMessage); connect(_toolbox->uasMessageHandler(), &UASMessageHandler::textMessageReceived, this, &Vehicle::_handletextMessageReceived); // Now connect the new UAS connect(_mav, SIGNAL(attitudeChanged (UASInterface*,double,double,double,quint64)), this, SLOT(_updateAttitude(UASInterface*, double, double, double, quint64))); connect(_mav, SIGNAL(attitudeChanged (UASInterface*,int,double,double,double,quint64)), this, SLOT(_updateAttitude(UASInterface*,int,double, double, double, quint64))); if (_highLatencyLink) { // High latency links don't request information _setMaxProtoVersion(100); _setCapabilities(0); _initialPlanRequestComplete = true; _missionManagerInitialRequestSent = true; _geoFenceManagerInitialRequestSent = true; _rallyPointManagerInitialRequestSent = true; } else { // Ask the vehicle for protocol version info. sendMavCommand(MAV_COMP_ID_ALL, // Don't know default component id yet. MAV_CMD_REQUEST_PROTOCOL_VERSION, false, // No error shown if fails 1); // Request protocol version // Ask the vehicle for firmware version info. sendMavCommand(MAV_COMP_ID_ALL, // Don't know default component id yet. MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES, false, // No error shown if fails 1); // Request firmware version } _firmwarePlugin->initializeVehicle(this); _sendMultipleTimer.start(_sendMessageMultipleIntraMessageDelay); connect(&_sendMultipleTimer, &QTimer::timeout, this, &Vehicle::_sendMessageMultipleNext); _mapTrajectoryTimer.setInterval(_mapTrajectoryMsecsBetweenPoints); connect(&_mapTrajectoryTimer, &QTimer::timeout, this, &Vehicle::_addNewMapTrajectoryPoint); // Create camera manager instance _cameras = _firmwarePlugin->createCameraManager(this); emit dynamicCamerasChanged(); } // Disconnected Vehicle for offline editing Vehicle::Vehicle(MAV_AUTOPILOT firmwareType, MAV_TYPE vehicleType, FirmwarePluginManager* firmwarePluginManager, QObject* parent) : FactGroup(_vehicleUIUpdateRateMSecs, ":/json/Vehicle/VehicleFact.json", parent) , _id(0) , _defaultComponentId(MAV_COMP_ID_ALL) , _active(false) , _offlineEditingVehicle(true) , _firmwareType(firmwareType) , _vehicleType(vehicleType) , _firmwarePlugin(NULL) , _firmwarePluginInstanceData(NULL) , _autopilotPlugin(NULL) , _mavlink(NULL) , _soloFirmware(false) , _toolbox(qgcApp()->toolbox()) , _settingsManager(_toolbox->settingsManager()) , _joystickMode(JoystickModeRC) , _joystickEnabled(false) , _uas(NULL) , _mav(NULL) , _currentMessageCount(0) , _messageCount(0) , _currentErrorCount(0) , _currentWarningCount(0) , _currentNormalCount(0) , _currentMessageType(MessageNone) , _updateCount(0) , _rcRSSI(255) , _rcRSSIstore(255) , _autoDisconnect(false) , _flying(false) , _landing(false) , _vtolInFwdFlight(false) , _onboardControlSensorsPresent(0) , _onboardControlSensorsEnabled(0) , _onboardControlSensorsHealth(0) , _onboardControlSensorsUnhealthy(0) , _gpsRawIntMessageAvailable(false) , _globalPositionIntMessageAvailable(false) , _defaultCruiseSpeed(_settingsManager->appSettings()->offlineEditingCruiseSpeed()->rawValue().toDouble()) , _defaultHoverSpeed(_settingsManager->appSettings()->offlineEditingHoverSpeed()->rawValue().toDouble()) , _vehicleCapabilitiesKnown(true) , _capabilityBits(_firmwareType == MAV_AUTOPILOT_ARDUPILOTMEGA ? 0 : MAV_PROTOCOL_CAPABILITY_MISSION_FENCE | MAV_PROTOCOL_CAPABILITY_MISSION_RALLY) , _highLatencyLink(false) , _cameras(NULL) , _connectionLost(false) , _connectionLostEnabled(true) , _initialPlanRequestComplete(false) , _missionManager(NULL) , _missionManagerInitialRequestSent(false) , _geoFenceManager(NULL) , _geoFenceManagerInitialRequestSent(false) , _rallyPointManager(NULL) , _rallyPointManagerInitialRequestSent(false) , _parameterManager(NULL) , _armed(false) , _base_mode(0) , _custom_mode(0) , _nextSendMessageMultipleIndex(0) , _firmwarePluginManager(firmwarePluginManager) , _joystickManager(NULL) , _flowImageIndex(0) , _allLinksInactiveSent(false) , _messagesReceived(0) , _messagesSent(0) , _messagesLost(0) , _messageSeq(0) , _compID(0) , _heardFrom(false) , _firmwareMajorVersion(versionNotSetValue) , _firmwareMinorVersion(versionNotSetValue) , _firmwarePatchVersion(versionNotSetValue) , _firmwareCustomMajorVersion(versionNotSetValue) , _firmwareCustomMinorVersion(versionNotSetValue) , _firmwareCustomPatchVersion(versionNotSetValue) , _firmwareVersionType(FIRMWARE_VERSION_TYPE_OFFICIAL) , _gitHash(versionNotSetValue) , _uid(0) , _lastAnnouncedLowBatteryPercent(100) , _rollFact (0, _rollFactName, FactMetaData::valueTypeDouble) , _pitchFact (0, _pitchFactName, FactMetaData::valueTypeDouble) , _headingFact (0, _headingFactName, FactMetaData::valueTypeDouble) , _rollRateFact (0, _rollRateFactName, FactMetaData::valueTypeDouble) , _pitchRateFact (0, _pitchRateFactName, FactMetaData::valueTypeDouble) , _yawRateFact (0, _yawRateFactName, FactMetaData::valueTypeDouble) , _groundSpeedFact (0, _groundSpeedFactName, FactMetaData::valueTypeDouble) , _airSpeedFact (0, _airSpeedFactName, FactMetaData::valueTypeDouble) , _climbRateFact (0, _climbRateFactName, FactMetaData::valueTypeDouble) , _altitudeRelativeFact (0, _altitudeRelativeFactName, FactMetaData::valueTypeDouble) , _altitudeAMSLFact (0, _altitudeAMSLFactName, FactMetaData::valueTypeDouble) , _flightDistanceFact (0, _flightDistanceFactName, FactMetaData::valueTypeDouble) , _flightTimeFact (0, _flightTimeFactName, FactMetaData::valueTypeElapsedTimeInSeconds) , _distanceToHomeFact (0, _distanceToHomeFactName, FactMetaData::valueTypeDouble) , _hobbsFact (0, _hobbsFactName, FactMetaData::valueTypeString) , _gpsFactGroup(this) , _batteryFactGroup(this) , _windFactGroup(this) , _vibrationFactGroup(this) , _clockFactGroup(this) { _commonInit(); _firmwarePlugin->initializeVehicle(this); } void Vehicle::_commonInit(void) { _firmwarePlugin = _firmwarePluginManager->firmwarePluginForAutopilot(_firmwareType, _vehicleType); connect(_firmwarePlugin, &FirmwarePlugin::toolbarIndicatorsChanged, this, &Vehicle::toolBarIndicatorsChanged); connect(this, &Vehicle::coordinateChanged, this, &Vehicle::_updateDistanceToHome); connect(this, &Vehicle::homePositionChanged, this, &Vehicle::_updateDistanceToHome); connect(this, &Vehicle::hobbsMeterChanged, this, &Vehicle::_updateHobbsMeter); _missionManager = new MissionManager(this); connect(_missionManager, &MissionManager::error, this, &Vehicle::_missionManagerError); connect(_missionManager, &MissionManager::newMissionItemsAvailable, this, &Vehicle::_missionLoadComplete); connect(_missionManager, &MissionManager::newMissionItemsAvailable, this, &Vehicle::_clearCameraTriggerPoints); connect(_missionManager, &MissionManager::newMissionItemsAvailable, this, &Vehicle::_clearTrajectoryPoints); connect(_missionManager, &MissionManager::sendComplete, this, &Vehicle::_clearCameraTriggerPoints); connect(_missionManager, &MissionManager::sendComplete, this, &Vehicle::_clearTrajectoryPoints); _parameterManager = new ParameterManager(this); connect(_parameterManager, &ParameterManager::parametersReadyChanged, this, &Vehicle::_parametersReady); // GeoFenceManager needs to access ParameterManager so make sure to create after _geoFenceManager = new GeoFenceManager(this); connect(_geoFenceManager, &GeoFenceManager::error, this, &Vehicle::_geoFenceManagerError); connect(_geoFenceManager, &GeoFenceManager::loadComplete, this, &Vehicle::_geoFenceLoadComplete); _rallyPointManager = new RallyPointManager(this); connect(_rallyPointManager, &RallyPointManager::error, this, &Vehicle::_rallyPointManagerError); connect(_rallyPointManager, &RallyPointManager::loadComplete, this, &Vehicle::_rallyPointLoadComplete); // Offline editing vehicle tracks settings changes for offline editing settings connect(_settingsManager->appSettings()->offlineEditingFirmwareType(), &Fact::rawValueChanged, this, &Vehicle::_offlineFirmwareTypeSettingChanged); connect(_settingsManager->appSettings()->offlineEditingVehicleType(), &Fact::rawValueChanged, this, &Vehicle::_offlineVehicleTypeSettingChanged); connect(_settingsManager->appSettings()->offlineEditingCruiseSpeed(), &Fact::rawValueChanged, this, &Vehicle::_offlineCruiseSpeedSettingChanged); connect(_settingsManager->appSettings()->offlineEditingHoverSpeed(), &Fact::rawValueChanged, this, &Vehicle::_offlineHoverSpeedSettingChanged); // Build FactGroup object model _addFact(&_rollFact, _rollFactName); _addFact(&_pitchFact, _pitchFactName); _addFact(&_headingFact, _headingFactName); _addFact(&_rollRateFact, _rollRateFactName); _addFact(&_pitchRateFact, _pitchRateFactName); _addFact(&_yawRateFact, _yawRateFactName); _addFact(&_groundSpeedFact, _groundSpeedFactName); _addFact(&_airSpeedFact, _airSpeedFactName); _addFact(&_climbRateFact, _climbRateFactName); _addFact(&_altitudeRelativeFact, _altitudeRelativeFactName); _addFact(&_altitudeAMSLFact, _altitudeAMSLFactName); _addFact(&_flightDistanceFact, _flightDistanceFactName); _addFact(&_flightTimeFact, _flightTimeFactName); _addFact(&_distanceToHomeFact, _distanceToHomeFactName); _hobbsFact.setRawValue(QVariant(QString("0000:00:00"))); _addFact(&_hobbsFact, _hobbsFactName); _addFactGroup(&_gpsFactGroup, _gpsFactGroupName); _addFactGroup(&_batteryFactGroup, _batteryFactGroupName); _addFactGroup(&_windFactGroup, _windFactGroupName); _addFactGroup(&_vibrationFactGroup, _vibrationFactGroupName); _addFactGroup(&_temperatureFactGroup, _temperatureFactGroupName); _addFactGroup(&_clockFactGroup, _clockFactGroupName); // Add firmware-specific fact groups, if provided QMap* fwFactGroups = _firmwarePlugin->factGroups(); if (fwFactGroups) { QMapIterator i(*fwFactGroups); while(i.hasNext()) { i.next(); _addFactGroup(i.value(), i.key()); } } _flightDistanceFact.setRawValue(0); _flightTimeFact.setRawValue(0); } Vehicle::~Vehicle() { qCDebug(VehicleLog) << "~Vehicle" << this; delete _missionManager; _missionManager = NULL; delete _autopilotPlugin; _autopilotPlugin = NULL; delete _mav; _mav = NULL; } void Vehicle::prepareDelete() { if(_cameras) { delete _cameras; _cameras = NULL; emit dynamicCamerasChanged(); qApp->processEvents(); } } void Vehicle::_offlineFirmwareTypeSettingChanged(QVariant value) { _firmwareType = static_cast(value.toInt()); emit firmwareTypeChanged(); if (_firmwareType == MAV_AUTOPILOT_ARDUPILOTMEGA) { _capabilityBits = 0; } else { _capabilityBits = MAV_PROTOCOL_CAPABILITY_MISSION_FENCE | MAV_PROTOCOL_CAPABILITY_MISSION_RALLY; } emit capabilityBitsChanged(_capabilityBits); } void Vehicle::_offlineVehicleTypeSettingChanged(QVariant value) { _vehicleType = static_cast(value.toInt()); emit vehicleTypeChanged(); } void Vehicle::_offlineCruiseSpeedSettingChanged(QVariant value) { _defaultCruiseSpeed = value.toDouble(); emit defaultCruiseSpeedChanged(_defaultCruiseSpeed); } void Vehicle::_offlineHoverSpeedSettingChanged(QVariant value) { _defaultHoverSpeed = value.toDouble(); emit defaultHoverSpeedChanged(_defaultHoverSpeed); } QString Vehicle::firmwareTypeString(void) const { if (px4Firmware()) { return QStringLiteral("PX4 Pro"); } else if (apmFirmware()) { return QStringLiteral("ArduPilot"); } else { return tr("MAVLink Generic"); } } QString Vehicle::vehicleTypeString(void) const { if (fixedWing()) { return tr("Fixed Wing"); } else if (multiRotor()) { return tr("Multi-Rotor"); } else if (vtol()) { return tr("VTOL"); } else if (rover()) { return tr("Rover"); } else if (sub()) { return tr("Sub"); } else { return tr("Unknown"); } } void Vehicle::resetCounters() { _messagesReceived = 0; _messagesSent = 0; _messagesLost = 0; _messageSeq = 0; _heardFrom = false; } void Vehicle::_mavlinkMessageReceived(LinkInterface* link, mavlink_message_t message) { // if the minimum supported version of MAVLink is already 2.0 // set our max proto version to it. unsigned mavlinkVersion = _mavlink->getCurrentVersion(); if (_maxProtoVersion != mavlinkVersion && mavlinkVersion >= 200) { _maxProtoVersion = _mavlink->getCurrentVersion(); qCDebug(VehicleLog) << "Vehicle::_mavlinkMessageReceived setting _maxProtoVersion" << _maxProtoVersion; } if (message.sysid != _id && message.sysid != 0) { // We allow RADIO_STATUS messages which come from a link the vehicle is using to pass through and be handled if (!(message.msgid == MAVLINK_MSG_ID_RADIO_STATUS && _containsLink(link))) { return; } } if (!_containsLink(link)) { _addLink(link); } //-- Check link status _messagesReceived++; emit messagesReceivedChanged(); if(!_heardFrom) { if(message.msgid == MAVLINK_MSG_ID_HEARTBEAT) { _heardFrom = true; _compID = message.compid; _messageSeq = message.seq + 1; } } else { if(_compID == message.compid) { uint16_t seq_received = (uint16_t)message.seq; uint16_t packet_lost_count = 0; //-- Account for overflow during packet loss if(seq_received < _messageSeq) { packet_lost_count = (seq_received + 255) - _messageSeq; } else { packet_lost_count = seq_received - _messageSeq; } _messageSeq = message.seq + 1; _messagesLost += packet_lost_count; if(packet_lost_count) emit messagesLostChanged(); } } // Mark this vehicle as active - but only if the traffic is coming from // the actual vehicle if (message.sysid == _id) { _connectionActive(); } // Give the plugin a change to adjust the message contents if (!_firmwarePlugin->adjustIncomingMavlinkMessage(this, &message)) { return; } // Give the Core Plugin access to all mavlink traffic if (!_toolbox->corePlugin()->mavlinkMessage(this, link, message)) { return; } switch (message.msgid) { case MAVLINK_MSG_ID_HOME_POSITION: _handleHomePosition(message); break; case MAVLINK_MSG_ID_HEARTBEAT: _handleHeartbeat(message); break; case MAVLINK_MSG_ID_RADIO_STATUS: _handleRadioStatus(message); break; case MAVLINK_MSG_ID_RC_CHANNELS: _handleRCChannels(message); break; case MAVLINK_MSG_ID_RC_CHANNELS_RAW: _handleRCChannelsRaw(message); break; case MAVLINK_MSG_ID_BATTERY_STATUS: _handleBatteryStatus(message); break; case MAVLINK_MSG_ID_SYS_STATUS: _handleSysStatus(message); break; case MAVLINK_MSG_ID_RAW_IMU: emit mavlinkRawImu(message); break; case MAVLINK_MSG_ID_SCALED_IMU: emit mavlinkScaledImu1(message); break; case MAVLINK_MSG_ID_SCALED_IMU2: emit mavlinkScaledImu2(message); break; case MAVLINK_MSG_ID_SCALED_IMU3: emit mavlinkScaledImu3(message); break; case MAVLINK_MSG_ID_VIBRATION: _handleVibration(message); break; case MAVLINK_MSG_ID_EXTENDED_SYS_STATE: _handleExtendedSysState(message); break; case MAVLINK_MSG_ID_COMMAND_ACK: _handleCommandAck(message); break; case MAVLINK_MSG_ID_COMMAND_LONG: _handleCommandLong(message); break; case MAVLINK_MSG_ID_AUTOPILOT_VERSION: _handleAutopilotVersion(link, message); break; case MAVLINK_MSG_ID_PROTOCOL_VERSION: _handleProtocolVersion(link, message); break; case MAVLINK_MSG_ID_WIND_COV: _handleWindCov(message); break; case MAVLINK_MSG_ID_HIL_ACTUATOR_CONTROLS: _handleHilActuatorControls(message); break; case MAVLINK_MSG_ID_LOGGING_DATA: _handleMavlinkLoggingData(message); break; case MAVLINK_MSG_ID_LOGGING_DATA_ACKED: _handleMavlinkLoggingDataAcked(message); break; case MAVLINK_MSG_ID_GPS_RAW_INT: _handleGpsRawInt(message); break; case MAVLINK_MSG_ID_GLOBAL_POSITION_INT: _handleGlobalPositionInt(message); break; case MAVLINK_MSG_ID_ALTITUDE: _handleAltitude(message); break; case MAVLINK_MSG_ID_VFR_HUD: _handleVfrHud(message); break; case MAVLINK_MSG_ID_SCALED_PRESSURE: _handleScaledPressure(message); break; case MAVLINK_MSG_ID_SCALED_PRESSURE2: _handleScaledPressure2(message); break; case MAVLINK_MSG_ID_SCALED_PRESSURE3: _handleScaledPressure3(message); break; case MAVLINK_MSG_ID_CAMERA_IMAGE_CAPTURED: _handleCameraImageCaptured(message); break; case MAVLINK_MSG_ID_ADSB_VEHICLE: _handleADSBVehicle(message); break; case MAVLINK_MSG_ID_HIGH_LATENCY2: _handleHighLatency2(message); break; case MAVLINK_MSG_ID_ATTITUDE: _handleAttitude(message); break; case MAVLINK_MSG_ID_ATTITUDE_TARGET: _handleAttitudeTarget(message); break; case MAVLINK_MSG_ID_SERIAL_CONTROL: { mavlink_serial_control_t ser; mavlink_msg_serial_control_decode(&message, &ser); emit mavlinkSerialControl(ser.device, ser.flags, ser.timeout, ser.baudrate, QByteArray(reinterpret_cast(ser.data), ser.count)); } break; // Following are ArduPilot dialect messages #if !defined(NO_ARDUPILOT_DIALECT) case MAVLINK_MSG_ID_CAMERA_FEEDBACK: _handleCameraFeedback(message); break; case MAVLINK_MSG_ID_WIND: _handleWind(message); break; #endif } // This must be emitted after the vehicle processes the message. This way the vehicle state is up to date when anyone else // does processing. emit mavlinkMessageReceived(message); _uas->receiveMessage(message); } #if !defined(NO_ARDUPILOT_DIALECT) void Vehicle::_handleCameraFeedback(const mavlink_message_t& message) { mavlink_camera_feedback_t feedback; mavlink_msg_camera_feedback_decode(&message, &feedback); QGeoCoordinate imageCoordinate((double)feedback.lat / qPow(10.0, 7.0), (double)feedback.lng / qPow(10.0, 7.0), feedback.alt_msl); qCDebug(VehicleLog) << "_handleCameraFeedback coord:index" << imageCoordinate << feedback.img_idx; _cameraTriggerPoints.append(new QGCQGeoCoordinate(imageCoordinate, this)); } #endif void Vehicle::_handleCameraImageCaptured(const mavlink_message_t& message) { mavlink_camera_image_captured_t feedback; mavlink_msg_camera_image_captured_decode(&message, &feedback); QGeoCoordinate imageCoordinate((double)feedback.lat / qPow(10.0, 7.0), (double)feedback.lon / qPow(10.0, 7.0), feedback.alt); qCDebug(VehicleLog) << "_handleCameraFeedback coord:index" << imageCoordinate << feedback.image_index << feedback.capture_result; if (feedback.capture_result == 1) { _cameraTriggerPoints.append(new QGCQGeoCoordinate(imageCoordinate, this)); } } void Vehicle::_handleVfrHud(mavlink_message_t& message) { mavlink_vfr_hud_t vfrHud; mavlink_msg_vfr_hud_decode(&message, &vfrHud); _airSpeedFact.setRawValue(qIsNaN(vfrHud.airspeed) ? 0 : vfrHud.airspeed); _groundSpeedFact.setRawValue(qIsNaN(vfrHud.groundspeed) ? 0 : vfrHud.groundspeed); _climbRateFact.setRawValue(qIsNaN(vfrHud.climb) ? 0 : vfrHud.climb); } void Vehicle::_handleAttitudeTarget(mavlink_message_t& message) { mavlink_attitude_target_t attitudeTarget; mavlink_msg_attitude_target_decode(&message, &attitudeTarget); float roll, pitch, yaw; mavlink_quaternion_to_euler(attitudeTarget.q, &roll, &pitch, &yaw); _setpointFactGroup.roll()->setRawValue(roll); _setpointFactGroup.pitch()->setRawValue(pitch); _setpointFactGroup.yaw()->setRawValue(yaw); _setpointFactGroup.rollRate()->setRawValue(qRadiansToDegrees(attitudeTarget.body_roll_rate)); _setpointFactGroup.pitchRate()->setRawValue(qRadiansToDegrees(attitudeTarget.body_pitch_rate)); _setpointFactGroup.yawRate()->setRawValue(qRadiansToDegrees(attitudeTarget.body_yaw_rate)); } void Vehicle::_handleAttitude(mavlink_message_t& message) { mavlink_attitude_t attitude; mavlink_msg_attitude_decode(&message, &attitude); rollRate()->setRawValue(qRadiansToDegrees(attitude.rollspeed)); pitchRate()->setRawValue(qRadiansToDegrees(attitude.pitchspeed)); yawRate()->setRawValue(qRadiansToDegrees(attitude.yawspeed)); } void Vehicle::_handleGpsRawInt(mavlink_message_t& message) { mavlink_gps_raw_int_t gpsRawInt; mavlink_msg_gps_raw_int_decode(&message, &gpsRawInt); _gpsRawIntMessageAvailable = true; if (gpsRawInt.fix_type >= GPS_FIX_TYPE_3D_FIX) { if (!_globalPositionIntMessageAvailable) { //-- Set these here and emit a single signal instead of 3 for the same variable (_coordinate) _coordinate.setLatitude(gpsRawInt.lat / (double)1E7); _coordinate.setLongitude(gpsRawInt.lon / (double)1E7); _coordinate.setAltitude(gpsRawInt.alt / 1000.0); emit coordinateChanged(_coordinate); _altitudeAMSLFact.setRawValue(gpsRawInt.alt / 1000.0); } } _gpsFactGroup.lat()->setRawValue(gpsRawInt.lat * 1e-7); _gpsFactGroup.lon()->setRawValue(gpsRawInt.lon * 1e-7); _gpsFactGroup.count()->setRawValue(gpsRawInt.satellites_visible == 255 ? 0 : gpsRawInt.satellites_visible); _gpsFactGroup.hdop()->setRawValue(gpsRawInt.eph == UINT16_MAX ? std::numeric_limits::quiet_NaN() : gpsRawInt.eph / 100.0); _gpsFactGroup.vdop()->setRawValue(gpsRawInt.epv == UINT16_MAX ? std::numeric_limits::quiet_NaN() : gpsRawInt.epv / 100.0); _gpsFactGroup.courseOverGround()->setRawValue(gpsRawInt.cog == UINT16_MAX ? std::numeric_limits::quiet_NaN() : gpsRawInt.cog / 100.0); _gpsFactGroup.lock()->setRawValue(gpsRawInt.fix_type); } void Vehicle::_handleGlobalPositionInt(mavlink_message_t& message) { mavlink_global_position_int_t globalPositionInt; mavlink_msg_global_position_int_decode(&message, &globalPositionInt); _altitudeRelativeFact.setRawValue(globalPositionInt.relative_alt / 1000.0); _altitudeAMSLFact.setRawValue(globalPositionInt.alt / 1000.0); // ArduPilot sends bogus GLOBAL_POSITION_INT messages with lat/lat 0/0 even when it has no gps signal // Apparently, this is in order to transport relative altitude information. if (globalPositionInt.lat == 0 && globalPositionInt.lon == 0) { return; } _globalPositionIntMessageAvailable = true; //-- Set these here and emit a single signal instead of 3 for the same variable (_coordinate) _coordinate.setLatitude(globalPositionInt.lat / (double)1E7); _coordinate.setLongitude(globalPositionInt.lon / (double)1E7); _coordinate.setAltitude(globalPositionInt.alt / 1000.0); emit coordinateChanged(_coordinate); } void Vehicle::_handleHighLatency2(mavlink_message_t& message) { mavlink_high_latency2_t highLatency2; mavlink_msg_high_latency2_decode(&message, &highLatency2); QString previousFlightMode; if (_base_mode != 0 || _custom_mode != 0){ // Vehicle is initialized with _base_mode=0 and _custom_mode=0. Don't pass this to flightMode() since it will complain about // bad modes while unit testing. previousFlightMode = flightMode(); } _base_mode = MAV_MODE_FLAG_CUSTOM_MODE_ENABLED; _custom_mode = _firmwarePlugin->highLatencyCustomModeTo32Bits(highLatency2.custom_mode); if (previousFlightMode != flightMode()) { emit flightModeChanged(flightMode()); } // Assume armed since we don't know if (_armed != true) { _armed = true; emit armedChanged(_armed); } _coordinate.setLatitude(highLatency2.latitude / (double)1E7); _coordinate.setLongitude(highLatency2.longitude / (double)1E7); _coordinate.setAltitude(highLatency2.altitude); emit coordinateChanged(_coordinate); _airSpeedFact.setRawValue((double)highLatency2.airspeed / 5.0); _groundSpeedFact.setRawValue((double)highLatency2.groundspeed / 5.0); _climbRateFact.setRawValue((double)highLatency2.climb_rate / 10.0); _headingFact.setRawValue((double)highLatency2.heading * 2.0); _altitudeRelativeFact.setRawValue(std::numeric_limits::quiet_NaN()); _altitudeAMSLFact.setRawValue(highLatency2.altitude); _windFactGroup.direction()->setRawValue((double)highLatency2.wind_heading * 2.0); _windFactGroup.speed()->setRawValue((double)highLatency2.windspeed / 5.0); _batteryFactGroup.percentRemaining()->setRawValue(highLatency2.battery); _temperatureFactGroup.temperature1()->setRawValue(highLatency2.temperature_air); _gpsFactGroup.lat()->setRawValue(highLatency2.latitude * 1e-7); _gpsFactGroup.lon()->setRawValue(highLatency2.longitude * 1e-7); _gpsFactGroup.count()->setRawValue(0); _gpsFactGroup.hdop()->setRawValue(highLatency2.eph == UINT8_MAX ? std::numeric_limits::quiet_NaN() : highLatency2.eph / 10.0); _gpsFactGroup.vdop()->setRawValue(highLatency2.epv == UINT8_MAX ? std::numeric_limits::quiet_NaN() : highLatency2.epv / 10.0); struct failure2Sensor_s { HL_FAILURE_FLAG failureBit; MAV_SYS_STATUS_SENSOR sensorBit; }; static const failure2Sensor_s rgFailure2Sensor[] = { { HL_FAILURE_FLAG_GPS, MAV_SYS_STATUS_SENSOR_GPS }, { HL_FAILURE_FLAG_DIFFERENTIAL_PRESSURE, MAV_SYS_STATUS_SENSOR_DIFFERENTIAL_PRESSURE }, { HL_FAILURE_FLAG_ABSOLUTE_PRESSURE, MAV_SYS_STATUS_SENSOR_ABSOLUTE_PRESSURE }, { HL_FAILURE_FLAG_3D_ACCEL, MAV_SYS_STATUS_SENSOR_3D_ACCEL }, { HL_FAILURE_FLAG_3D_GYRO, MAV_SYS_STATUS_SENSOR_3D_GYRO }, { HL_FAILURE_FLAG_3D_MAG, MAV_SYS_STATUS_SENSOR_3D_MAG }, }; // Map from MAV_FAILURE bits to standard SYS_STATUS message handling uint32_t newOnboardControlSensorsEnabled = 0; for (size_t i=0; ifailureBit) { // Assume if reporting as unhealthy that is it present and enabled newOnboardControlSensorsEnabled |= pFailure2Sensor->sensorBit; } } if (newOnboardControlSensorsEnabled != _onboardControlSensorsEnabled) { _onboardControlSensorsEnabled = newOnboardControlSensorsEnabled; _onboardControlSensorsPresent = newOnboardControlSensorsEnabled; _onboardControlSensorsUnhealthy = 0; emit unhealthySensorsChanged(); } } void Vehicle::_handleAltitude(mavlink_message_t& message) { mavlink_altitude_t altitude; mavlink_msg_altitude_decode(&message, &altitude); // If data from GPS is available it takes precedence over ALTITUDE message if (!_globalPositionIntMessageAvailable) { _altitudeRelativeFact.setRawValue(altitude.altitude_relative); if (!_gpsRawIntMessageAvailable) { _altitudeAMSLFact.setRawValue(altitude.altitude_amsl); } } } void Vehicle::_setCapabilities(uint64_t capabilityBits) { _capabilityBits = capabilityBits; _vehicleCapabilitiesKnown = true; emit capabilitiesKnownChanged(true); emit capabilityBitsChanged(_capabilityBits); // This should potentially be turned into a user-facing warning // if the general experience after deployment is that users want MAVLink 2 // but forget to upgrade their radio firmware if (capabilityBits & MAV_PROTOCOL_CAPABILITY_MAVLINK2 && maxProtoVersion() < 200) { qCDebug(VehicleLog) << QString("Vehicle does support MAVLink 2 but the link does not allow for it."); } QString supports("supports"); QString doesNotSupport("does not support"); qCDebug(VehicleLog) << QString("Vehicle %1 Mavlink 2.0").arg(_capabilityBits & MAV_PROTOCOL_CAPABILITY_MAVLINK2 ? supports : doesNotSupport); qCDebug(VehicleLog) << QString("Vehicle %1 MISSION_ITEM_INT").arg(_capabilityBits & MAV_PROTOCOL_CAPABILITY_MISSION_INT ? supports : doesNotSupport); qCDebug(VehicleLog) << QString("Vehicle %1 GeoFence").arg(_capabilityBits & MAV_PROTOCOL_CAPABILITY_MISSION_FENCE ? supports : doesNotSupport); qCDebug(VehicleLog) << QString("Vehicle %1 RallyPoints").arg(_capabilityBits & MAV_PROTOCOL_CAPABILITY_MISSION_RALLY ? supports : doesNotSupport); } void Vehicle::_handleAutopilotVersion(LinkInterface *link, mavlink_message_t& message) { Q_UNUSED(link); mavlink_autopilot_version_t autopilotVersion; mavlink_msg_autopilot_version_decode(&message, &autopilotVersion); _uid = (quint64)autopilotVersion.uid; emit vehicleUIDChanged(); if (autopilotVersion.flight_sw_version != 0) { int majorVersion, minorVersion, patchVersion; FIRMWARE_VERSION_TYPE versionType; majorVersion = (autopilotVersion.flight_sw_version >> (8*3)) & 0xFF; minorVersion = (autopilotVersion.flight_sw_version >> (8*2)) & 0xFF; patchVersion = (autopilotVersion.flight_sw_version >> (8*1)) & 0xFF; versionType = (FIRMWARE_VERSION_TYPE)((autopilotVersion.flight_sw_version >> (8*0)) & 0xFF); setFirmwareVersion(majorVersion, minorVersion, patchVersion, versionType); } if (px4Firmware()) { // Lower 3 bytes is custom version int majorVersion, minorVersion, patchVersion; majorVersion = autopilotVersion.flight_custom_version[2]; minorVersion = autopilotVersion.flight_custom_version[1]; patchVersion = autopilotVersion.flight_custom_version[0]; setFirmwareCustomVersion(majorVersion, minorVersion, patchVersion); // PX4 Firmware stores the first 16 characters of the git hash as binary, with the individual bytes in reverse order _gitHash = ""; QByteArray array((char*)autopilotVersion.flight_custom_version, 8); for (int i = 7; i >= 0; i--) { _gitHash.append(QString("%1").arg(autopilotVersion.flight_custom_version[i], 2, 16, QChar('0'))); } } else { // APM Firmware stores the first 8 characters of the git hash as an ASCII character string _gitHash = QString::fromUtf8((char*)autopilotVersion.flight_custom_version, 8); } emit gitHashChanged(_gitHash); _setCapabilities(autopilotVersion.capabilities); _startPlanRequest(); } void Vehicle::_handleProtocolVersion(LinkInterface *link, mavlink_message_t& message) { Q_UNUSED(link); mavlink_protocol_version_t protoVersion; mavlink_msg_protocol_version_decode(&message, &protoVersion); _setMaxProtoVersion(protoVersion.max_version); } void Vehicle::_setMaxProtoVersion(unsigned version) { // Set only once or if we need to reduce the max version if (_maxProtoVersion == 0 || version < _maxProtoVersion) { qCDebug(VehicleLog) << "_setMaxProtoVersion before:after" << _maxProtoVersion << version; _maxProtoVersion = version; emit requestProtocolVersion(_maxProtoVersion); // Now that the protocol version is known, the mission load is safe // as it will use the right MAVLink version to enable all features // the vehicle supports _startPlanRequest(); } } QString Vehicle::vehicleUIDStr() { QString uid; uint8_t* pUid = (uint8_t*)(void*)&_uid; uid.sprintf("%02X:%02X:%02X:%02X:%02X:%02X:%02X:%02X", pUid[0] & 0xff, pUid[1] & 0xff, pUid[2] & 0xff, pUid[3] & 0xff, pUid[4] & 0xff, pUid[5] & 0xff, pUid[6] & 0xff, pUid[7] & 0xff); return uid; } void Vehicle::_handleHilActuatorControls(mavlink_message_t &message) { mavlink_hil_actuator_controls_t hil; mavlink_msg_hil_actuator_controls_decode(&message, &hil); emit hilActuatorControlsChanged(hil.time_usec, hil.flags, hil.controls[0], hil.controls[1], hil.controls[2], hil.controls[3], hil.controls[4], hil.controls[5], hil.controls[6], hil.controls[7], hil.controls[8], hil.controls[9], hil.controls[10], hil.controls[11], hil.controls[12], hil.controls[13], hil.controls[14], hil.controls[15], hil.mode); } void Vehicle::_handleCommandLong(mavlink_message_t& message) { #ifdef NO_SERIAL_LINK // If not using serial link, bail out. Q_UNUSED(message) #else mavlink_command_long_t cmd; mavlink_msg_command_long_decode(&message, &cmd); switch (cmd.command) { // Other component on the same system // requests that QGC frees up the serial port of the autopilot case MAV_CMD_PREFLIGHT_REBOOT_SHUTDOWN: if (cmd.param6 > 0) { // disconnect the USB link if its a direct connection to a Pixhawk for (int i = 0; i < _links.length(); i++) { SerialLink *sl = qobject_cast(_links.at(i)); if (sl && sl->getSerialConfig()->usbDirect()) { qDebug() << "Disconnecting:" << _links.at(i)->getName(); qgcApp()->toolbox()->linkManager()->disconnectLink(_links.at(i)); } } } break; } #endif } void Vehicle::_handleExtendedSysState(mavlink_message_t& message) { mavlink_extended_sys_state_t extendedState; mavlink_msg_extended_sys_state_decode(&message, &extendedState); switch (extendedState.landed_state) { case MAV_LANDED_STATE_ON_GROUND: _setFlying(false); _setLanding(false); break; case MAV_LANDED_STATE_TAKEOFF: case MAV_LANDED_STATE_IN_AIR: _setFlying(true); _setLanding(false); break; case MAV_LANDED_STATE_LANDING: _setFlying(true); _setLanding(true); break; default: break; } if (vtol()) { bool vtolInFwdFlight = extendedState.vtol_state == MAV_VTOL_STATE_FW; if (vtolInFwdFlight != _vtolInFwdFlight) { _vtolInFwdFlight = vtolInFwdFlight; emit vtolInFwdFlightChanged(vtolInFwdFlight); } } } void Vehicle::_handleVibration(mavlink_message_t& message) { mavlink_vibration_t vibration; mavlink_msg_vibration_decode(&message, &vibration); _vibrationFactGroup.xAxis()->setRawValue(vibration.vibration_x); _vibrationFactGroup.yAxis()->setRawValue(vibration.vibration_y); _vibrationFactGroup.zAxis()->setRawValue(vibration.vibration_z); _vibrationFactGroup.clipCount1()->setRawValue(vibration.clipping_0); _vibrationFactGroup.clipCount2()->setRawValue(vibration.clipping_1); _vibrationFactGroup.clipCount3()->setRawValue(vibration.clipping_2); } void Vehicle::_handleWindCov(mavlink_message_t& message) { mavlink_wind_cov_t wind; mavlink_msg_wind_cov_decode(&message, &wind); float direction = qRadiansToDegrees(qAtan2(wind.wind_y, wind.wind_x)); float speed = qSqrt(qPow(wind.wind_x, 2) + qPow(wind.wind_y, 2)); _windFactGroup.direction()->setRawValue(direction); _windFactGroup.speed()->setRawValue(speed); _windFactGroup.verticalSpeed()->setRawValue(0); } #if !defined(NO_ARDUPILOT_DIALECT) void Vehicle::_handleWind(mavlink_message_t& message) { mavlink_wind_t wind; mavlink_msg_wind_decode(&message, &wind); // We don't want negative wind angles float direction = wind.direction; if (direction < 0) { direction += 360; } _windFactGroup.direction()->setRawValue(direction); _windFactGroup.speed()->setRawValue(wind.speed); _windFactGroup.verticalSpeed()->setRawValue(wind.speed_z); } #endif void Vehicle::_handleSysStatus(mavlink_message_t& message) { mavlink_sys_status_t sysStatus; mavlink_msg_sys_status_decode(&message, &sysStatus); if (sysStatus.current_battery == -1) { _batteryFactGroup.current()->setRawValue(VehicleBatteryFactGroup::_currentUnavailable); } else { // Current is in Amps, current_battery is 10 * milliamperes (1 = 10 milliampere) _batteryFactGroup.current()->setRawValue((float)sysStatus.current_battery / 100.0f); } if (sysStatus.voltage_battery == UINT16_MAX) { _batteryFactGroup.voltage()->setRawValue(VehicleBatteryFactGroup::_voltageUnavailable); } else { _batteryFactGroup.voltage()->setRawValue((double)sysStatus.voltage_battery / 1000.0); // current_battery is 10 mA and voltage_battery is 1mV. (10/1e3 times 1/1e3 = 1/1e5) _batteryFactGroup.instantPower()->setRawValue((float)(sysStatus.current_battery*sysStatus.voltage_battery)/(100000.0)); } _batteryFactGroup.percentRemaining()->setRawValue(sysStatus.battery_remaining); if (sysStatus.battery_remaining > 0) { if (sysStatus.battery_remaining < _settingsManager->appSettings()->batteryPercentRemainingAnnounce()->rawValue().toInt() && sysStatus.battery_remaining < _lastAnnouncedLowBatteryPercent) { _say(QString(tr("%1 low battery: %2 percent remaining")).arg(_vehicleIdSpeech()).arg(sysStatus.battery_remaining)); } _lastAnnouncedLowBatteryPercent = sysStatus.battery_remaining; } _onboardControlSensorsPresent = sysStatus.onboard_control_sensors_present; _onboardControlSensorsEnabled = sysStatus.onboard_control_sensors_enabled; _onboardControlSensorsHealth = sysStatus.onboard_control_sensors_health; uint32_t newSensorsUnhealthy = _onboardControlSensorsEnabled & ~_onboardControlSensorsHealth; if (newSensorsUnhealthy != _onboardControlSensorsUnhealthy) { _onboardControlSensorsUnhealthy = newSensorsUnhealthy; emit unhealthySensorsChanged(); } } void Vehicle::_handleBatteryStatus(mavlink_message_t& message) { mavlink_battery_status_t bat_status; mavlink_msg_battery_status_decode(&message, &bat_status); if (bat_status.temperature == INT16_MAX) { _batteryFactGroup.temperature()->setRawValue(VehicleBatteryFactGroup::_temperatureUnavailable); } else { _batteryFactGroup.temperature()->setRawValue((double)bat_status.temperature / 100.0); } if (bat_status.current_consumed == -1) { _batteryFactGroup.mahConsumed()->setRawValue(VehicleBatteryFactGroup::_mahConsumedUnavailable); } else { _batteryFactGroup.mahConsumed()->setRawValue(bat_status.current_consumed); } int cellCount = 0; for (int i=0; i<10; i++) { if (bat_status.voltages[i] != UINT16_MAX) { cellCount++; } } if (cellCount == 0) { cellCount = -1; } _batteryFactGroup.cellCount()->setRawValue(cellCount); } void Vehicle::_setHomePosition(QGeoCoordinate& homeCoord) { if (homeCoord != _homePosition) { _homePosition = homeCoord; emit homePositionChanged(_homePosition); } } void Vehicle::_handleHomePosition(mavlink_message_t& message) { mavlink_home_position_t homePos; mavlink_msg_home_position_decode(&message, &homePos); QGeoCoordinate newHomePosition (homePos.latitude / 10000000.0, homePos.longitude / 10000000.0, homePos.altitude / 1000.0); _setHomePosition(newHomePosition); } void Vehicle::_handleHeartbeat(mavlink_message_t& message) { if (message.compid != _defaultComponentId) { return; } mavlink_heartbeat_t heartbeat; mavlink_msg_heartbeat_decode(&message, &heartbeat); bool newArmed = heartbeat.base_mode & MAV_MODE_FLAG_DECODE_POSITION_SAFETY; if (_armed != newArmed) { _armed = newArmed; emit armedChanged(_armed); // We are transitioning to the armed state, begin tracking trajectory points for the map if (_armed) { _mapTrajectoryStart(); _clearCameraTriggerPoints(); } else { _mapTrajectoryStop(); // Also handle Video Streaming if(_settingsManager->videoSettings()->disableWhenDisarmed()->rawValue().toBool()) { _settingsManager->videoSettings()->streamEnabled()->setRawValue(false); qgcApp()->toolbox()->videoManager()->videoReceiver()->stop(); } } } if (heartbeat.base_mode != _base_mode || heartbeat.custom_mode != _custom_mode) { QString previousFlightMode; if (_base_mode != 0 || _custom_mode != 0){ // Vehicle is initialized with _base_mode=0 and _custom_mode=0. Don't pass this to flightMode() since it will complain about // bad modes while unit testing. previousFlightMode = flightMode(); } _base_mode = heartbeat.base_mode; _custom_mode = heartbeat.custom_mode; if (previousFlightMode != flightMode()) { emit flightModeChanged(flightMode()); } } } void Vehicle::_handleRadioStatus(mavlink_message_t& message) { //-- Process telemetry status message mavlink_radio_status_t rstatus; mavlink_msg_radio_status_decode(&message, &rstatus); int rssi = rstatus.rssi; int remrssi = rstatus.remrssi; int lnoise = (int)(int8_t)rstatus.noise; int rnoise = (int)(int8_t)rstatus.remnoise; //-- 3DR Si1k radio needs rssi fields to be converted to dBm if (message.sysid == '3' && message.compid == 'D') { /* Per the Si1K datasheet figure 23.25 and SI AN474 code * samples the relationship between the RSSI register * and received power is as follows: * * 10 * inputPower = rssi * ------ 127 * 19 * * Additionally limit to the only realistic range [-120,0] dBm */ rssi = qMin(qMax(qRound(static_cast(rssi) / 1.9 - 127.0), - 120), 0); remrssi = qMin(qMax(qRound(static_cast(remrssi) / 1.9 - 127.0), - 120), 0); } else { rssi = (int)(int8_t)rstatus.rssi; remrssi = (int)(int8_t)rstatus.remrssi; } //-- Check for changes if(_telemetryLRSSI != rssi) { _telemetryLRSSI = rssi; emit telemetryLRSSIChanged(_telemetryLRSSI); } if(_telemetryRRSSI != remrssi) { _telemetryRRSSI = remrssi; emit telemetryRRSSIChanged(_telemetryRRSSI); } if(_telemetryRXErrors != rstatus.rxerrors) { _telemetryRXErrors = rstatus.rxerrors; emit telemetryRXErrorsChanged(_telemetryRXErrors); } if(_telemetryFixed != rstatus.fixed) { _telemetryFixed = rstatus.fixed; emit telemetryFixedChanged(_telemetryFixed); } if(_telemetryTXBuffer != rstatus.txbuf) { _telemetryTXBuffer = rstatus.txbuf; emit telemetryTXBufferChanged(_telemetryTXBuffer); } if(_telemetryLNoise != lnoise) { _telemetryLNoise = lnoise; emit telemetryLNoiseChanged(_telemetryLNoise); } if(_telemetryRNoise != rnoise) { _telemetryRNoise = rnoise; emit telemetryRNoiseChanged(_telemetryRNoise); } } void Vehicle::_handleRCChannels(mavlink_message_t& message) { mavlink_rc_channels_t channels; mavlink_msg_rc_channels_decode(&message, &channels); uint16_t* _rgChannelvalues[cMaxRcChannels] = { &channels.chan1_raw, &channels.chan2_raw, &channels.chan3_raw, &channels.chan4_raw, &channels.chan5_raw, &channels.chan6_raw, &channels.chan7_raw, &channels.chan8_raw, &channels.chan9_raw, &channels.chan10_raw, &channels.chan11_raw, &channels.chan12_raw, &channels.chan13_raw, &channels.chan14_raw, &channels.chan15_raw, &channels.chan16_raw, &channels.chan17_raw, &channels.chan18_raw, }; int pwmValues[cMaxRcChannels]; for (int i=0; isetRawValue(pressure.temperature / 100.0); } void Vehicle::_handleScaledPressure2(mavlink_message_t& message) { mavlink_scaled_pressure2_t pressure; mavlink_msg_scaled_pressure2_decode(&message, &pressure); _temperatureFactGroup.temperature2()->setRawValue(pressure.temperature / 100.0); } void Vehicle::_handleScaledPressure3(mavlink_message_t& message) { mavlink_scaled_pressure3_t pressure; mavlink_msg_scaled_pressure3_decode(&message, &pressure); _temperatureFactGroup.temperature3()->setRawValue(pressure.temperature / 100.0); } bool Vehicle::_containsLink(LinkInterface* link) { return _links.contains(link); } void Vehicle::_addLink(LinkInterface* link) { if (!_containsLink(link)) { qCDebug(VehicleLog) << "_addLink:" << QString("%1").arg((ulong)link, 0, 16); _links += link; _updatePriorityLink(); _updateHighLatencyLink(); connect(_toolbox->linkManager(), &LinkManager::linkInactive, this, &Vehicle::_linkInactiveOrDeleted); connect(_toolbox->linkManager(), &LinkManager::linkDeleted, this, &Vehicle::_linkInactiveOrDeleted); connect(link, &LinkInterface::highLatencyChanged, this, &Vehicle::_updateHighLatencyLink); } } void Vehicle::_linkInactiveOrDeleted(LinkInterface* link) { qCDebug(VehicleLog) << "_linkInactiveOrDeleted linkCount" << _links.count(); _links.removeOne(link); _updatePriorityLink(); if (_links.count() == 0 && !_allLinksInactiveSent) { qCDebug(VehicleLog) << "All links inactive"; // Make sure to not send this more than one time _allLinksInactiveSent = true; emit allLinksInactive(this); } } bool Vehicle::sendMessageOnLink(LinkInterface* link, mavlink_message_t message) { if (!link || !_links.contains(link) || !link->isConnected()) { return false; } emit _sendMessageOnLinkOnThread(link, message); return true; } void Vehicle::_sendMessageOnLink(LinkInterface* link, mavlink_message_t message) { // Make sure this is still a good link if (!link || !_links.contains(link) || !link->isConnected()) { return; } #if 0 // Leaving in for ease in Mav 2.0 testing mavlink_status_t* mavlinkStatus = mavlink_get_channel_status(link->mavlinkChannel()); qDebug() << "_sendMessageOnLink" << mavlinkStatus << link->mavlinkChannel() << mavlinkStatus->flags << message.magic; #endif // Give the plugin a chance to adjust _firmwarePlugin->adjustOutgoingMavlinkMessage(this, link, &message); // Write message into buffer, prepending start sign uint8_t buffer[MAVLINK_MAX_PACKET_LEN]; int len = mavlink_msg_to_send_buffer(buffer, &message); link->writeBytesSafe((const char*)buffer, len); _messagesSent++; emit messagesSentChanged(); } void Vehicle::_updatePriorityLink(void) { LinkInterface* newPriorityLink = NULL; // This routine specifically does not clear _priorityLink when there are no links remaining. // By doing this we hold a reference on the last link as the Vehicle shuts down. Thus preventing shutdown // ordering NULL pointer crashes where priorityLink() is still called during shutdown sequence. if (_links.count() == 0) { return; } // Check for the existing priority link to still be valid for (int i=0; i<_links.count(); i++) { if (_priorityLink.data() == _links[i]) { if (!_priorityLink.data()->highLatency()) { // Link is still valid. Continue to use it unless it is high latency. In that case we still look for a better // link to use as priority link. return; } } } // The previous priority link is no longer valid. We must no find the best link available in this priority order: // Direct USB connection // Not a high latency link // Any link #ifndef NO_SERIAL_LINK // Search for direct usb connection for (int i=0; i<_links.count(); i++) { LinkInterface* link = _links[i]; SerialLink* pSerialLink = qobject_cast(link); if (pSerialLink) { LinkConfiguration* config = pSerialLink->getLinkConfiguration(); if (config) { SerialConfiguration* pSerialConfig = qobject_cast(config); if (pSerialConfig && pSerialConfig->usbDirect()) { if (_priorityLink.data() != link) { newPriorityLink = link; break; } return; } } } } #endif if (!newPriorityLink) { // Search for non-high latency link for (int i=0; i<_links.count(); i++) { LinkInterface* link = _links[i]; if (!link->highLatency()) { newPriorityLink = link; break; } } } if (!newPriorityLink) { // Use any link newPriorityLink = _links[0]; } _priorityLink = _toolbox->linkManager()->sharedLinkInterfacePointerForLink(newPriorityLink); _updateHighLatencyLink(); } void Vehicle::_updateAttitude(UASInterface*, double roll, double pitch, double yaw, quint64) { if (qIsInf(roll)) { _rollFact.setRawValue(0); } else { _rollFact.setRawValue(roll * (180.0 / M_PI)); } if (qIsInf(pitch)) { _pitchFact.setRawValue(0); } else { _pitchFact.setRawValue(pitch * (180.0 / M_PI)); } if (qIsInf(yaw)) { _headingFact.setRawValue(0); } else { yaw = yaw * (180.0 / M_PI); if (yaw < 0.0) yaw += 360.0; // truncate to integer so widget never displays 360 _headingFact.setRawValue(trunc(yaw)); } } void Vehicle::_updateAttitude(UASInterface* uas, int, double roll, double pitch, double yaw, quint64 timestamp) { _updateAttitude(uas, roll, pitch, yaw, timestamp); } int Vehicle::motorCount(void) { switch (_vehicleType) { case MAV_TYPE_HELICOPTER: return 1; case MAV_TYPE_VTOL_DUOROTOR: return 2; case MAV_TYPE_TRICOPTER: return 3; case MAV_TYPE_QUADROTOR: case MAV_TYPE_VTOL_QUADROTOR: return 4; case MAV_TYPE_HEXAROTOR: return 6; case MAV_TYPE_OCTOROTOR: return 8; default: return -1; } } bool Vehicle::coaxialMotors(void) { return _firmwarePlugin->multiRotorCoaxialMotors(this); } bool Vehicle::xConfigMotors(void) { return _firmwarePlugin->multiRotorXConfig(this); } /* * Internal */ QString Vehicle::getMavIconColor() { // TODO: Not using because not only the colors are ghastly, it doesn't respect dark/light palette if(_mav) return _mav->getColor().name(); else return QString("black"); } QString Vehicle::formatedMessages() { QString messages; foreach(UASMessage* message, _toolbox->uasMessageHandler()->messages()) { messages += message->getFormatedText(); } return messages; } void Vehicle::clearMessages() { _toolbox->uasMessageHandler()->clearMessages(); } void Vehicle::_handletextMessageReceived(UASMessage* message) { if(message) { _formatedMessage = message->getFormatedText(); emit formatedMessageChanged(); } } void Vehicle::_handleTextMessage(int newCount) { // Reset? if(!newCount) { _currentMessageCount = 0; _currentNormalCount = 0; _currentWarningCount = 0; _currentErrorCount = 0; _messageCount = 0; _currentMessageType = MessageNone; emit newMessageCountChanged(); emit messageTypeChanged(); emit messageCountChanged(); return; } UASMessageHandler* pMh = _toolbox->uasMessageHandler(); MessageType_t type = newCount ? _currentMessageType : MessageNone; int errorCount = _currentErrorCount; int warnCount = _currentWarningCount; int normalCount = _currentNormalCount; //-- Add current message counts errorCount += pMh->getErrorCount(); warnCount += pMh->getWarningCount(); normalCount += pMh->getNormalCount(); //-- See if we have a higher level if(errorCount != _currentErrorCount) { _currentErrorCount = errorCount; type = MessageError; } if(warnCount != _currentWarningCount) { _currentWarningCount = warnCount; if(_currentMessageType != MessageError) { type = MessageWarning; } } if(normalCount != _currentNormalCount) { _currentNormalCount = normalCount; if(_currentMessageType != MessageError && _currentMessageType != MessageWarning) { type = MessageNormal; } } int count = _currentErrorCount + _currentWarningCount + _currentNormalCount; if(count != _currentMessageCount) { _currentMessageCount = count; // Display current total new messages count emit newMessageCountChanged(); } if(type != _currentMessageType) { _currentMessageType = type; // Update message level emit messageTypeChanged(); } // Update message count (all messages) if(newCount != _messageCount) { _messageCount = newCount; emit messageCountChanged(); } QString errMsg = pMh->getLatestError(); if(errMsg != _latestError) { _latestError = errMsg; emit latestErrorChanged(); } } void Vehicle::resetMessages() { // Reset Counts int count = _currentMessageCount; MessageType_t type = _currentMessageType; _currentErrorCount = 0; _currentWarningCount = 0; _currentNormalCount = 0; _currentMessageCount = 0; _currentMessageType = MessageNone; if(count != _currentMessageCount) { emit newMessageCountChanged(); } if(type != _currentMessageType) { emit messageTypeChanged(); } } int Vehicle::manualControlReservedButtonCount(void) { return _firmwarePlugin->manualControlReservedButtonCount(); } void Vehicle::_loadSettings(void) { if (!_active) { return; } QSettings settings; settings.beginGroup(QString(_settingsGroup).arg(_id)); bool convertOk; _joystickMode = (JoystickMode_t)settings.value(_joystickModeSettingsKey, JoystickModeRC).toInt(&convertOk); if (!convertOk) { _joystickMode = JoystickModeRC; } // Joystick enabled is a global setting so first make sure there are any joysticks connected if (_toolbox->joystickManager()->joysticks().count()) { setJoystickEnabled(settings.value(_joystickEnabledSettingsKey, false).toBool()); _startJoystick(true); } } void Vehicle::_saveSettings(void) { QSettings settings; settings.beginGroup(QString(_settingsGroup).arg(_id)); settings.setValue(_joystickModeSettingsKey, _joystickMode); // The joystick enabled setting should only be changed if a joystick is present // since the checkbox can only be clicked if one is present if (_toolbox->joystickManager()->joysticks().count()) { settings.setValue(_joystickEnabledSettingsKey, _joystickEnabled); } } int Vehicle::joystickMode(void) { return _joystickMode; } void Vehicle::setJoystickMode(int mode) { if (mode < 0 || mode >= JoystickModeMax) { qCWarning(VehicleLog) << "Invalid joystick mode" << mode; return; } _joystickMode = (JoystickMode_t)mode; _saveSettings(); emit joystickModeChanged(mode); } QStringList Vehicle::joystickModes(void) { QStringList list; list << "Normal" << "Attitude" << "Position" << "Force" << "Velocity"; return list; } bool Vehicle::joystickEnabled(void) { return _joystickEnabled; } void Vehicle::setJoystickEnabled(bool enabled) { _joystickEnabled = enabled; _saveSettings(); emit joystickEnabledChanged(_joystickEnabled); } void Vehicle::_startJoystick(bool start) { Joystick* joystick = _joystickManager->activeJoystick(); if (joystick) { if (start) { joystick->startPolling(this); } else { joystick->stopPolling(); } } } bool Vehicle::active(void) { return _active; } void Vehicle::setActive(bool active) { if (_active != active) { _active = active; _startJoystick(false); emit activeChanged(_active); } } QGeoCoordinate Vehicle::homePosition(void) { return _homePosition; } void Vehicle::setArmed(bool armed) { // We specifically use COMMAND_LONG:MAV_CMD_COMPONENT_ARM_DISARM since it is supported by more flight stacks. sendMavCommand(_defaultComponentId, MAV_CMD_COMPONENT_ARM_DISARM, true, // show error if fails armed ? 1.0f : 0.0f); } bool Vehicle::flightModeSetAvailable(void) { return _firmwarePlugin->isCapable(this, FirmwarePlugin::SetFlightModeCapability); } QStringList Vehicle::flightModes(void) { return _firmwarePlugin->flightModes(this); } QString Vehicle::flightMode(void) const { return _firmwarePlugin->flightMode(_base_mode, _custom_mode); } void Vehicle::setFlightMode(const QString& flightMode) { uint8_t base_mode; uint32_t custom_mode; if (_firmwarePlugin->setFlightMode(flightMode, &base_mode, &custom_mode)) { // setFlightMode will only set MAV_MODE_FLAG_CUSTOM_MODE_ENABLED in base_mode, we need to move back in the existing // states. uint8_t newBaseMode = _base_mode & ~MAV_MODE_FLAG_DECODE_POSITION_CUSTOM_MODE; newBaseMode |= base_mode; mavlink_message_t msg; mavlink_msg_set_mode_pack_chan(_mavlink->getSystemId(), _mavlink->getComponentId(), priorityLink()->mavlinkChannel(), &msg, id(), newBaseMode, custom_mode); sendMessageOnLink(priorityLink(), msg); } else { qWarning() << "FirmwarePlugin::setFlightMode failed, flightMode:" << flightMode; } } bool Vehicle::hilMode(void) { return _base_mode & MAV_MODE_FLAG_HIL_ENABLED; } void Vehicle::setHilMode(bool hilMode) { mavlink_message_t msg; uint8_t newBaseMode = _base_mode & ~MAV_MODE_FLAG_DECODE_POSITION_HIL; if (hilMode) { newBaseMode |= MAV_MODE_FLAG_HIL_ENABLED; } mavlink_msg_set_mode_pack_chan(_mavlink->getSystemId(), _mavlink->getComponentId(), priorityLink()->mavlinkChannel(), &msg, id(), newBaseMode, _custom_mode); sendMessageOnLink(priorityLink(), msg); } void Vehicle::requestDataStream(MAV_DATA_STREAM stream, uint16_t rate, bool sendMultiple) { mavlink_message_t msg; mavlink_request_data_stream_t dataStream; memset(&dataStream, 0, sizeof(dataStream)); dataStream.req_stream_id = stream; dataStream.req_message_rate = rate; dataStream.start_stop = 1; // start dataStream.target_system = id(); dataStream.target_component = _defaultComponentId; mavlink_msg_request_data_stream_encode_chan(_mavlink->getSystemId(), _mavlink->getComponentId(), priorityLink()->mavlinkChannel(), &msg, &dataStream); if (sendMultiple) { // We use sendMessageMultiple since we really want these to make it to the vehicle sendMessageMultiple(msg); } else { sendMessageOnLink(priorityLink(), msg); } } void Vehicle::_sendMessageMultipleNext(void) { if (_nextSendMessageMultipleIndex < _sendMessageMultipleList.count()) { qCDebug(VehicleLog) << "_sendMessageMultipleNext:" << _sendMessageMultipleList[_nextSendMessageMultipleIndex].message.msgid; sendMessageOnLink(priorityLink(), _sendMessageMultipleList[_nextSendMessageMultipleIndex].message); if (--_sendMessageMultipleList[_nextSendMessageMultipleIndex].retryCount <= 0) { _sendMessageMultipleList.removeAt(_nextSendMessageMultipleIndex); } else { _nextSendMessageMultipleIndex++; } } if (_nextSendMessageMultipleIndex >= _sendMessageMultipleList.count()) { _nextSendMessageMultipleIndex = 0; } } void Vehicle::sendMessageMultiple(mavlink_message_t message) { SendMessageMultipleInfo_t info; info.message = message; info.retryCount = _sendMessageMultipleRetries; _sendMessageMultipleList.append(info); } void Vehicle::_missionManagerError(int errorCode, const QString& errorMsg) { Q_UNUSED(errorCode); qgcApp()->showMessage(tr("Mission transfer failed. Retry transfer. Error: %1").arg(errorMsg)); } void Vehicle::_geoFenceManagerError(int errorCode, const QString& errorMsg) { Q_UNUSED(errorCode); qgcApp()->showMessage(tr("GeoFence transfer failed. Retry transfer. Error: %1").arg(errorMsg)); } void Vehicle::_rallyPointManagerError(int errorCode, const QString& errorMsg) { Q_UNUSED(errorCode); qgcApp()->showMessage(tr("Rally Point transfer failed. Retry transfer. Error: %1").arg(errorMsg)); } void Vehicle::_addNewMapTrajectoryPoint(void) { if (_mapTrajectoryHaveFirstCoordinate) { // Keep three minutes of trajectory on mobile due to perf impact of lines #ifdef __mobile__ if (_mapTrajectoryList.count() * _mapTrajectoryMsecsBetweenPoints > 3 * 1000 * 60) { _mapTrajectoryList.removeAt(0)->deleteLater(); } #endif _mapTrajectoryList.append(new CoordinateVector(_mapTrajectoryLastCoordinate, _coordinate, this)); _flightDistanceFact.setRawValue(_flightDistanceFact.rawValue().toDouble() + _mapTrajectoryLastCoordinate.distanceTo(_coordinate)); } _mapTrajectoryHaveFirstCoordinate = true; _mapTrajectoryLastCoordinate = _coordinate; _flightTimeFact.setRawValue((double)_flightTimer.elapsed() / 1000.0); } void Vehicle::_clearTrajectoryPoints(void) { _mapTrajectoryList.clearAndDeleteContents(); } void Vehicle::_clearCameraTriggerPoints(void) { _cameraTriggerPoints.clearAndDeleteContents(); } void Vehicle::_mapTrajectoryStart(void) { _mapTrajectoryHaveFirstCoordinate = false; _clearTrajectoryPoints(); _mapTrajectoryTimer.start(); _flightTimer.start(); _flightDistanceFact.setRawValue(0); _flightTimeFact.setRawValue(0); } void Vehicle::_mapTrajectoryStop() { _mapTrajectoryTimer.stop(); } void Vehicle::_startPlanRequest(void) { if (_missionManagerInitialRequestSent) { return; } if (_parameterManager->parametersReady() && _vehicleCapabilitiesKnown) { qCDebug(VehicleLog) << "_startPlanRequest"; _missionManagerInitialRequestSent = true; if (_settingsManager->appSettings()->autoLoadMissions()->rawValue().toBool()) { QString missionAutoLoadDirPath = _settingsManager->appSettings()->missionSavePath(); if (!missionAutoLoadDirPath.isEmpty()) { QDir missionAutoLoadDir(missionAutoLoadDirPath); QString autoloadFilename = missionAutoLoadDir.absoluteFilePath(tr("AutoLoad%1.%2").arg(_id).arg(AppSettings::planFileExtension)); if (QFile(autoloadFilename).exists()) { _initialPlanRequestComplete = true; // We aren't going to load from the vehicle, so we are done PlanMasterController::sendPlanToVehicle(this, autoloadFilename); return; } } } _missionManager->loadFromVehicle(); } else { if (!_parameterManager->parametersReady()) { qCDebug(VehicleLog) << "Delaying _startPlanRequest due to parameters not ready"; } else if (!_vehicleCapabilitiesKnown) { qCDebug(VehicleLog) << "Delaying _startPlanRequest due to vehicle capabilities not known"; } } } void Vehicle::_missionLoadComplete(void) { // After the initial mission request completes we ask for the geofence if (!_geoFenceManagerInitialRequestSent) { _geoFenceManagerInitialRequestSent = true; if (_geoFenceManager->supported()) { qCDebug(VehicleLog) << "_missionLoadComplete requesting GeoFence"; _geoFenceManager->loadFromVehicle(); } else { qCDebug(VehicleLog) << "_missionLoadComplete GeoFence not supported skipping"; _geoFenceLoadComplete(); } } } void Vehicle::_geoFenceLoadComplete(void) { // After geofence request completes we ask for the rally points if (!_rallyPointManagerInitialRequestSent) { _rallyPointManagerInitialRequestSent = true; if (_rallyPointManager->supported()) { qCDebug(VehicleLog) << "_missionLoadComplete requesting Rally Points"; _rallyPointManager->loadFromVehicle(); } else { qCDebug(VehicleLog) << "_missionLoadComplete Rally Points not supported skipping"; _rallyPointLoadComplete(); } } } void Vehicle::_rallyPointLoadComplete(void) { qCDebug(VehicleLog) << "_missionLoadComplete _initialPlanRequestComplete = true"; if (!_initialPlanRequestComplete) { _initialPlanRequestComplete = true; emit initialPlanRequestCompleteChanged(true); } } void Vehicle::_parametersReady(bool parametersReady) { if (parametersReady) { _setupAutoDisarmSignalling(); _startPlanRequest(); } } void Vehicle::disconnectInactiveVehicle(void) { // Vehicle is no longer communicating with us, disconnect all links LinkManager* linkMgr = _toolbox->linkManager(); for (int i=0; i<_links.count(); i++) { // FIXME: This linkInUse check is a hack fix for multiple vehicles on the same link. // The real fix requires significant restructuring which will come later. if (!_toolbox->multiVehicleManager()->linkInUse(_links[i], this)) { linkMgr->disconnectLink(_links[i]); } } } void Vehicle::_imageReady(UASInterface*) { if(_uas) { QImage img = _uas->getImage(); _toolbox->imageProvider()->setImage(&img, _id); _flowImageIndex++; emit flowImageIndexChanged(); } } void Vehicle::_remoteControlRSSIChanged(uint8_t rssi) { if (_rcRSSIstore < 0 || _rcRSSIstore > 100) { _rcRSSIstore = rssi; } // Low pass to git rid of jitter _rcRSSIstore = (_rcRSSIstore * 0.9f) + ((float)rssi * 0.1); uint8_t filteredRSSI = (uint8_t)ceil(_rcRSSIstore); if(_rcRSSIstore < 0.1) { filteredRSSI = 0; } if(_rcRSSI != filteredRSSI) { _rcRSSI = filteredRSSI; emit rcRSSIChanged(_rcRSSI); } } void Vehicle::virtualTabletJoystickValue(double roll, double pitch, double yaw, double thrust) { // The following if statement prevents the virtualTabletJoystick from sending values if the standard joystick is enabled if ( !_joystickEnabled ) { _uas->setExternalControlSetpoint(roll, pitch, yaw, thrust, 0, JoystickModeRC); } } void Vehicle::setConnectionLostEnabled(bool connectionLostEnabled) { if (_connectionLostEnabled != connectionLostEnabled) { _connectionLostEnabled = connectionLostEnabled; emit connectionLostEnabledChanged(_connectionLostEnabled); } } void Vehicle::_connectionLostTimeout(void) { if (highLatencyLink()) { // No connection timeout on high latency links return; } if (_connectionLostEnabled && !_connectionLost) { _connectionLost = true; _heardFrom = false; _maxProtoVersion = 0; emit connectionLostChanged(true); _say(QString(tr("%1 communication lost")).arg(_vehicleIdSpeech())); if (_autoDisconnect) { // Reset link state for (int i = 0; i < _links.length(); i++) { _mavlink->resetMetadataForLink(_links.at(i)); } disconnectInactiveVehicle(); } } } void Vehicle::_connectionActive(void) { _connectionLostTimer.start(); if (_connectionLost) { _connectionLost = false; emit connectionLostChanged(false); _say(QString(tr("%1 communication regained")).arg(_vehicleIdSpeech())); // Re-negotiate protocol version for the link sendMavCommand(MAV_COMP_ID_ALL, // Don't know default component id yet. MAV_CMD_REQUEST_PROTOCOL_VERSION, false, // No error shown if fails 1); // Request protocol version } } void Vehicle::_say(const QString& text) { _toolbox->audioOutput()->say(text.toLower()); } bool Vehicle::fixedWing(void) const { return QGCMAVLink::isFixedWing(vehicleType()); } bool Vehicle::rover(void) const { return QGCMAVLink::isRover(vehicleType()); } bool Vehicle::sub(void) const { return QGCMAVLink::isSub(vehicleType()); } bool Vehicle::multiRotor(void) const { return QGCMAVLink::isMultiRotor(vehicleType()); } bool Vehicle::vtol(void) const { return _firmwarePlugin->isVtol(this); } bool Vehicle::supportsThrottleModeCenterZero(void) const { return _firmwarePlugin->supportsThrottleModeCenterZero(); } bool Vehicle::supportsNegativeThrust(void) const { return _firmwarePlugin->supportsNegativeThrust(); } bool Vehicle::supportsRadio(void) const { return _firmwarePlugin->supportsRadio(); } bool Vehicle::supportsJSButton(void) const { return _firmwarePlugin->supportsJSButton(); } bool Vehicle::supportsMotorInterference(void) const { return _firmwarePlugin->supportsMotorInterference(); } QString Vehicle::vehicleTypeName() const { static QMap typeNames = { { MAV_TYPE_GENERIC, tr("Generic micro air vehicle" )}, { MAV_TYPE_FIXED_WING, tr("Fixed wing aircraft")}, { MAV_TYPE_QUADROTOR, tr("Quadrotor")}, { MAV_TYPE_COAXIAL, tr("Coaxial helicopter")}, { MAV_TYPE_HELICOPTER, tr("Normal helicopter with tail rotor.")}, { MAV_TYPE_ANTENNA_TRACKER, tr("Ground installation")}, { MAV_TYPE_GCS, tr("Operator control unit / ground control station")}, { MAV_TYPE_AIRSHIP, tr("Airship, controlled")}, { MAV_TYPE_FREE_BALLOON, tr("Free balloon, uncontrolled")}, { MAV_TYPE_ROCKET, tr("Rocket")}, { MAV_TYPE_GROUND_ROVER, tr("Ground rover")}, { MAV_TYPE_SURFACE_BOAT, tr("Surface vessel, boat, ship")}, { MAV_TYPE_SUBMARINE, tr("Submarine")}, { MAV_TYPE_HEXAROTOR, tr("Hexarotor")}, { MAV_TYPE_OCTOROTOR, tr("Octorotor")}, { MAV_TYPE_TRICOPTER, tr("Octorotor")}, { MAV_TYPE_FLAPPING_WING, tr("Flapping wing")}, { MAV_TYPE_KITE, tr("Flapping wing")}, { MAV_TYPE_ONBOARD_CONTROLLER, tr("Onboard companion controller")}, { MAV_TYPE_VTOL_DUOROTOR, tr("Two-rotor VTOL using control surfaces in vertical operation in addition. Tailsitter")}, { MAV_TYPE_VTOL_QUADROTOR, tr("Quad-rotor VTOL using a V-shaped quad config in vertical operation. Tailsitter")}, { MAV_TYPE_VTOL_TILTROTOR, tr("Tiltrotor VTOL")}, { MAV_TYPE_VTOL_RESERVED2, tr("VTOL reserved 2")}, { MAV_TYPE_VTOL_RESERVED3, tr("VTOL reserved 3")}, { MAV_TYPE_VTOL_RESERVED4, tr("VTOL reserved 4")}, { MAV_TYPE_VTOL_RESERVED5, tr("VTOL reserved 5")}, { MAV_TYPE_GIMBAL, tr("Onboard gimbal")}, { MAV_TYPE_ADSB, tr("Onboard ADSB peripheral")}, }; return typeNames[_vehicleType]; } /// Returns the string to speak to identify the vehicle QString Vehicle::_vehicleIdSpeech(void) { if (_toolbox->multiVehicleManager()->vehicles()->count() > 1) { return QString(tr("vehicle %1")).arg(id()); } else { return QString(); } } void Vehicle::_handleFlightModeChanged(const QString& flightMode) { _say(QString(tr("%1 %2 flight mode")).arg(_vehicleIdSpeech()).arg(flightMode)); emit guidedModeChanged(_firmwarePlugin->isGuidedMode(this)); } void Vehicle::_announceArmedChanged(bool armed) { _say(QString("%1 %2").arg(_vehicleIdSpeech()).arg(armed ? QString(tr("armed")) : QString(tr("disarmed")))); } void Vehicle::_setFlying(bool flying) { if (_flying != flying) { _flying = flying; emit flyingChanged(flying); } } void Vehicle::_setLanding(bool landing) { if (armed() && _landing != landing) { _landing = landing; emit landingChanged(landing); } } bool Vehicle::guidedModeSupported(void) const { return _firmwarePlugin->isCapable(this, FirmwarePlugin::GuidedModeCapability); } bool Vehicle::pauseVehicleSupported(void) const { return _firmwarePlugin->isCapable(this, FirmwarePlugin::PauseVehicleCapability); } bool Vehicle::orbitModeSupported() const { return _firmwarePlugin->isCapable(this, FirmwarePlugin::OrbitModeCapability); } bool Vehicle::takeoffVehicleSupported() const { return _firmwarePlugin->isCapable(this, FirmwarePlugin::TakeoffVehicleCapability); } void Vehicle::guidedModeRTL(void) { if (!guidedModeSupported()) { qgcApp()->showMessage(guided_mode_not_supported_by_vehicle); return; } _firmwarePlugin->guidedModeRTL(this); } void Vehicle::guidedModeLand(void) { if (!guidedModeSupported()) { qgcApp()->showMessage(guided_mode_not_supported_by_vehicle); return; } _firmwarePlugin->guidedModeLand(this); } void Vehicle::guidedModeTakeoff(double altitudeRelative) { if (!guidedModeSupported()) { qgcApp()->showMessage(guided_mode_not_supported_by_vehicle); return; } setGuidedMode(true); _firmwarePlugin->guidedModeTakeoff(this, altitudeRelative); } double Vehicle::minimumTakeoffAltitude(void) { return _firmwarePlugin->minimumTakeoffAltitude(this); } void Vehicle::startMission(void) { _firmwarePlugin->startMission(this); } void Vehicle::guidedModeGotoLocation(const QGeoCoordinate& gotoCoord) { if (!guidedModeSupported()) { qgcApp()->showMessage(guided_mode_not_supported_by_vehicle); return; } if (!coordinate().isValid()) { return; } double maxDistance = 1000.0; if (coordinate().distanceTo(gotoCoord) > maxDistance) { qgcApp()->showMessage(QString("New location is too far. Must be less than %1 %2").arg(qRound(FactMetaData::metersToAppSettingsDistanceUnits(maxDistance).toDouble())).arg(FactMetaData::appSettingsDistanceUnitsString())); return; } _firmwarePlugin->guidedModeGotoLocation(this, gotoCoord); } void Vehicle::guidedModeChangeAltitude(double altitudeChange) { if (!guidedModeSupported()) { qgcApp()->showMessage(guided_mode_not_supported_by_vehicle); return; } _firmwarePlugin->guidedModeChangeAltitude(this, altitudeChange); } void Vehicle::guidedModeOrbit(const QGeoCoordinate& centerCoord, double radius, double velocity, double altitude) { if (!orbitModeSupported()) { qgcApp()->showMessage(QStringLiteral("Orbit mode not supported by Vehicle.")); return; } _firmwarePlugin->guidedModeOrbit(this, centerCoord, radius, velocity, altitude); } void Vehicle::pauseVehicle(void) { if (!pauseVehicleSupported()) { qgcApp()->showMessage(QStringLiteral("Pause not supported by vehicle.")); return; } _firmwarePlugin->pauseVehicle(this); } void Vehicle::abortLanding(double climbOutAltitude) { sendMavCommand(defaultComponentId(), MAV_CMD_DO_GO_AROUND, true, // show error if fails climbOutAltitude); } bool Vehicle::guidedMode(void) const { return _firmwarePlugin->isGuidedMode(this); } void Vehicle::setGuidedMode(bool guidedMode) { return _firmwarePlugin->setGuidedMode(this, guidedMode); } void Vehicle::emergencyStop(void) { sendMavCommand(_defaultComponentId, MAV_CMD_COMPONENT_ARM_DISARM, true, // show error if fails 0.0f, 21196.0f); // Magic number for emergency stop } void Vehicle::setCurrentMissionSequence(int seq) { if (!_firmwarePlugin->sendHomePositionToVehicle()) { seq--; } mavlink_message_t msg; mavlink_msg_mission_set_current_pack_chan(_mavlink->getSystemId(), _mavlink->getComponentId(), priorityLink()->mavlinkChannel(), &msg, id(), _compID, seq); sendMessageOnLink(priorityLink(), msg); } void Vehicle::sendMavCommand(int component, MAV_CMD command, bool showError, float param1, float param2, float param3, float param4, float param5, float param6, float param7) { MavCommandQueueEntry_t entry; entry.component = component; entry.command = command; entry.showError = showError; entry.rgParam[0] = param1; entry.rgParam[1] = param2; entry.rgParam[2] = param3; entry.rgParam[3] = param4; entry.rgParam[4] = param5; entry.rgParam[5] = param6; entry.rgParam[6] = param7; _mavCommandQueue.append(entry); if (_mavCommandQueue.count() == 1) { _mavCommandRetryCount = 0; _sendMavCommandAgain(); } } void Vehicle::_sendMavCommandAgain(void) { if(!_mavCommandQueue.size()) { qWarning() << "Command resend with no commands in queue"; _mavCommandAckTimer.stop(); return; } MavCommandQueueEntry_t& queuedCommand = _mavCommandQueue[0]; if (_mavCommandRetryCount++ > _mavCommandMaxRetryCount) { if (queuedCommand.command == MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES) { // We aren't going to get a response back for capabilities, so stop waiting for it before we ask for mission items qCDebug(VehicleLog) << "Vehicle failed to responded to MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES. Setting no capabilities. Starting Plan request."; _setCapabilities(0); _startPlanRequest(); } if (queuedCommand.command == MAV_CMD_REQUEST_PROTOCOL_VERSION) { // We aren't going to get a response back for the protocol version, so assume v1 is all we can do. // If the max protocol version is uninitialized, fall back to v1. qCDebug(VehicleLog) << "Vehicle failed to responded to MAV_CMD_REQUEST_PROTOCOL_VERSION. Starting Plan request."; if (_maxProtoVersion == 0) { qCDebug(VehicleLog) << "Setting _maxProtoVersion to 100 since not yet set."; _setMaxProtoVersion(100); } else { qCDebug(VehicleLog) << "Leaving _maxProtoVersion at current value" << _maxProtoVersion; } } emit mavCommandResult(_id, queuedCommand.component, queuedCommand.command, MAV_RESULT_FAILED, true /* noResponsefromVehicle */); if (queuedCommand.showError) { qgcApp()->showMessage(tr("Vehicle did not respond to command: %1").arg(_toolbox->missionCommandTree()->friendlyName(queuedCommand.command))); } _mavCommandQueue.removeFirst(); _sendNextQueuedMavCommand(); return; } if (_mavCommandRetryCount > 1) { // We always let AUTOPILOT_CAPABILITIES go through multiple times even if we don't get acks. This is because // we really need to get capabilities and version info back over a lossy link. if (queuedCommand.command != MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES) { if (px4Firmware()) { // Older PX4 firmwares are inconsistent with repect to sending back an Ack from a COMMAND_LONG, hence we can't support retry logic for it. if (_firmwareMajorVersion != versionNotSetValue) { // If no version set assume lastest master dev build, so acks are suppored if (_firmwareMajorVersion <= 1 && _firmwareMinorVersion <= 5 && _firmwarePatchVersion <= 3) { // Acks not supported in this version return; } } } else { if (queuedCommand.command == MAV_CMD_START_RX_PAIR) { // The implementation of this command comes from the IO layer and is shared across stacks. So for other firmwares // we aren't really sure whether they are correct or not. return; } } } qCDebug(VehicleLog) << "Vehicle::_sendMavCommandAgain retrying command:_mavCommandRetryCount" << queuedCommand.command << _mavCommandRetryCount; } _mavCommandAckTimer.start(); mavlink_message_t msg; mavlink_command_long_t cmd; memset(&cmd, 0, sizeof(cmd)); cmd.command = queuedCommand.command; cmd.confirmation = 0; cmd.param1 = queuedCommand.rgParam[0]; cmd.param2 = queuedCommand.rgParam[1]; cmd.param3 = queuedCommand.rgParam[2]; cmd.param4 = queuedCommand.rgParam[3]; cmd.param5 = queuedCommand.rgParam[4]; cmd.param6 = queuedCommand.rgParam[5]; cmd.param7 = queuedCommand.rgParam[6]; cmd.target_system = _id; cmd.target_component = queuedCommand.component; mavlink_msg_command_long_encode_chan(_mavlink->getSystemId(), _mavlink->getComponentId(), priorityLink()->mavlinkChannel(), &msg, &cmd); sendMessageOnLink(priorityLink(), msg); } void Vehicle::_sendNextQueuedMavCommand(void) { if (_mavCommandQueue.count()) { _mavCommandRetryCount = 0; _sendMavCommandAgain(); } } void Vehicle::_handleCommandAck(mavlink_message_t& message) { bool showError = false; mavlink_command_ack_t ack; mavlink_msg_command_ack_decode(&message, &ack); if (ack.command == MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES && ack.result != MAV_RESULT_ACCEPTED) { // We aren't going to get a response back for capabilities, so stop waiting for it before we ask for mission items qCDebug(VehicleLog) << QStringLiteral("Vehicle responded to MAV_CMD_REQUEST_AUTOPILOT_CAPABILITIES with error(%1). Setting no capabilities. Starting Plan request.").arg(ack.result); _setCapabilities(0); } if (ack.command == MAV_CMD_REQUEST_PROTOCOL_VERSION && ack.result != MAV_RESULT_ACCEPTED) { // The autopilot does not understand the request and consequently is likely handling only // MAVLink 1 qCDebug(VehicleLog) << QStringLiteral("Vehicle responded to MAV_CMD_REQUEST_PROTOCOL_VERSION with error(%1).").arg(ack.result); if (_maxProtoVersion == 0) { qCDebug(VehicleLog) << "Setting _maxProtoVersion to 100 since not yet set."; _setMaxProtoVersion(100); } else { qCDebug(VehicleLog) << "Leaving _maxProtoVersion at current value" << _maxProtoVersion; } // FIXME: Is this missing here. I believe it is a bug. Debug to verify. May need to go into Stable. //_startPlanRequest(); } if (_mavCommandQueue.count() && ack.command == _mavCommandQueue[0].command) { _mavCommandAckTimer.stop(); showError = _mavCommandQueue[0].showError; _mavCommandQueue.removeFirst(); } emit mavCommandResult(_id, message.compid, ack.command, ack.result, false /* noResponsefromVehicle */); if (showError) { QString commandName = _toolbox->missionCommandTree()->friendlyName((MAV_CMD)ack.command); switch (ack.result) { case MAV_RESULT_TEMPORARILY_REJECTED: qgcApp()->showMessage(tr("%1 command temporarily rejected").arg(commandName)); break; case MAV_RESULT_DENIED: qgcApp()->showMessage(tr("%1 command denied").arg(commandName)); break; case MAV_RESULT_UNSUPPORTED: qgcApp()->showMessage(tr("%1 command not supported").arg(commandName)); break; case MAV_RESULT_FAILED: qgcApp()->showMessage(tr("%1 command failed").arg(commandName)); break; default: // Do nothing break; } } _sendNextQueuedMavCommand(); } void Vehicle::setPrearmError(const QString& prearmError) { _prearmError = prearmError; emit prearmErrorChanged(_prearmError); if (!_prearmError.isEmpty()) { _prearmErrorTimer.start(); } } void Vehicle::_prearmErrorTimeout(void) { setPrearmError(QString()); } void Vehicle::setFirmwareVersion(int majorVersion, int minorVersion, int patchVersion, FIRMWARE_VERSION_TYPE versionType) { _firmwareMajorVersion = majorVersion; _firmwareMinorVersion = minorVersion; _firmwarePatchVersion = patchVersion; _firmwareVersionType = versionType; emit firmwareVersionChanged(); } void Vehicle::setFirmwareCustomVersion(int majorVersion, int minorVersion, int patchVersion) { _firmwareCustomMajorVersion = majorVersion; _firmwareCustomMinorVersion = minorVersion; _firmwareCustomPatchVersion = patchVersion; emit firmwareCustomVersionChanged(); } QString Vehicle::firmwareVersionTypeString(void) const { switch (_firmwareVersionType) { case FIRMWARE_VERSION_TYPE_DEV: return QStringLiteral("dev"); case FIRMWARE_VERSION_TYPE_ALPHA: return QStringLiteral("alpha"); case FIRMWARE_VERSION_TYPE_BETA: return QStringLiteral("beta"); case FIRMWARE_VERSION_TYPE_RC: return QStringLiteral("rc"); case FIRMWARE_VERSION_TYPE_OFFICIAL: default: return QStringLiteral(""); } } void Vehicle::rebootVehicle() { sendMavCommand(_defaultComponentId, MAV_CMD_PREFLIGHT_REBOOT_SHUTDOWN, true, 1.0f); } void Vehicle::setSoloFirmware(bool soloFirmware) { if (soloFirmware != _soloFirmware) { _soloFirmware = soloFirmware; emit soloFirmwareChanged(soloFirmware); } } #if 0 // Temporarily removed, waiting for new command implementation void Vehicle::motorTest(int motor, int percent, int timeoutSecs) { doCommandLongUnverified(_defaultComponentId, MAV_CMD_DO_MOTOR_TEST, motor, MOTOR_TEST_THROTTLE_PERCENT, percent, timeoutSecs); } #endif QString Vehicle::brandImageIndoor(void) const { return _firmwarePlugin->brandImageIndoor(this); } QString Vehicle::brandImageOutdoor(void) const { return _firmwarePlugin->brandImageOutdoor(this); } QStringList Vehicle::unhealthySensors(void) const { QStringList sensorList; struct sensorInfo_s { uint32_t bit; const char* sensorName; }; static const sensorInfo_s rgSensorInfo[] = { { MAV_SYS_STATUS_SENSOR_3D_GYRO, "Gyro" }, { MAV_SYS_STATUS_SENSOR_3D_ACCEL, "Accelerometer" }, { MAV_SYS_STATUS_SENSOR_3D_MAG, "Magnetometer" }, { MAV_SYS_STATUS_SENSOR_ABSOLUTE_PRESSURE, "Absolute pressure" }, { MAV_SYS_STATUS_SENSOR_DIFFERENTIAL_PRESSURE, "Differential pressure" }, { MAV_SYS_STATUS_SENSOR_GPS, "GPS" }, { MAV_SYS_STATUS_SENSOR_OPTICAL_FLOW, "Optical flow" }, { MAV_SYS_STATUS_SENSOR_VISION_POSITION, "Computer vision position" }, { MAV_SYS_STATUS_SENSOR_LASER_POSITION, "Laser based position" }, { MAV_SYS_STATUS_SENSOR_EXTERNAL_GROUND_TRUTH, "External ground truth" }, { MAV_SYS_STATUS_SENSOR_ANGULAR_RATE_CONTROL, "Angular rate control" }, { MAV_SYS_STATUS_SENSOR_ATTITUDE_STABILIZATION, "Attitude stabilization" }, { MAV_SYS_STATUS_SENSOR_YAW_POSITION, "Yaw position" }, { MAV_SYS_STATUS_SENSOR_Z_ALTITUDE_CONTROL, "Z/altitude control" }, { MAV_SYS_STATUS_SENSOR_XY_POSITION_CONTROL, "X/Y position control" }, { MAV_SYS_STATUS_SENSOR_MOTOR_OUTPUTS, "Motor outputs / control" }, { MAV_SYS_STATUS_SENSOR_RC_RECEIVER, "RC receiver" }, { MAV_SYS_STATUS_SENSOR_3D_GYRO2, "Gyro 2" }, { MAV_SYS_STATUS_SENSOR_3D_ACCEL2, "Accelerometer 2" }, { MAV_SYS_STATUS_SENSOR_3D_MAG2, "Magnetometer 2" }, { MAV_SYS_STATUS_GEOFENCE, "GeoFence" }, { MAV_SYS_STATUS_AHRS, "AHRS" }, { MAV_SYS_STATUS_TERRAIN, "Terrain" }, { MAV_SYS_STATUS_REVERSE_MOTOR, "Motors reversed" }, { MAV_SYS_STATUS_LOGGING, "Logging" }, { MAV_SYS_STATUS_SENSOR_BATTERY, "Battery" }, }; for (size_t i=0; ibit) && !(_onboardControlSensorsHealth & pSensorInfo->bit)) { sensorList << pSensorInfo->sensorName; } } return sensorList; } void Vehicle::setOfflineEditingDefaultComponentId(int defaultComponentId) { if (_offlineEditingVehicle) { _defaultComponentId = defaultComponentId; } else { qWarning() << "Call to Vehicle::setOfflineEditingDefaultComponentId on vehicle which is not offline"; } } void Vehicle::triggerCamera(void) { sendMavCommand(_defaultComponentId, MAV_CMD_DO_DIGICAM_CONTROL, true, // show errors 0.0, 0.0, 0.0, 0.0, // param 1-4 unused 1.0, // trigger camera 0.0, // param 6 unused 1.0); // test shot flag } void Vehicle::setVtolInFwdFlight(bool vtolInFwdFlight) { if (_vtolInFwdFlight != vtolInFwdFlight) { sendMavCommand(_defaultComponentId, MAV_CMD_DO_VTOL_TRANSITION, true, // show errors vtolInFwdFlight ? MAV_VTOL_STATE_FW : MAV_VTOL_STATE_MC, // transition state 0, 0, 0, 0, 0, 0); // param 2-7 unused } } const char* VehicleGPSFactGroup::_latFactName = "lat"; const char* VehicleGPSFactGroup::_lonFactName = "lon"; const char* VehicleGPSFactGroup::_hdopFactName = "hdop"; const char* VehicleGPSFactGroup::_vdopFactName = "vdop"; const char* VehicleGPSFactGroup::_courseOverGroundFactName = "courseOverGround"; const char* VehicleGPSFactGroup::_countFactName = "count"; const char* VehicleGPSFactGroup::_lockFactName = "lock"; VehicleGPSFactGroup::VehicleGPSFactGroup(QObject* parent) : FactGroup(1000, ":/json/Vehicle/GPSFact.json", parent) , _latFact (0, _latFactName, FactMetaData::valueTypeDouble) , _lonFact (0, _lonFactName, FactMetaData::valueTypeDouble) , _hdopFact (0, _hdopFactName, FactMetaData::valueTypeDouble) , _vdopFact (0, _vdopFactName, FactMetaData::valueTypeDouble) , _courseOverGroundFact (0, _courseOverGroundFactName, FactMetaData::valueTypeDouble) , _countFact (0, _countFactName, FactMetaData::valueTypeInt32) , _lockFact (0, _lockFactName, FactMetaData::valueTypeInt32) { _addFact(&_latFact, _latFactName); _addFact(&_lonFact, _lonFactName); _addFact(&_hdopFact, _hdopFactName); _addFact(&_vdopFact, _vdopFactName); _addFact(&_courseOverGroundFact, _courseOverGroundFactName); _addFact(&_lockFact, _lockFactName); _addFact(&_countFact, _countFactName); _latFact.setRawValue(std::numeric_limits::quiet_NaN()); _lonFact.setRawValue(std::numeric_limits::quiet_NaN()); _hdopFact.setRawValue(std::numeric_limits::quiet_NaN()); _vdopFact.setRawValue(std::numeric_limits::quiet_NaN()); _courseOverGroundFact.setRawValue(std::numeric_limits::quiet_NaN()); } void Vehicle::startMavlinkLog() { sendMavCommand(_defaultComponentId, MAV_CMD_LOGGING_START, false /* showError */); } void Vehicle::stopMavlinkLog() { sendMavCommand(_defaultComponentId, MAV_CMD_LOGGING_STOP, false /* showError */); } void Vehicle::_ackMavlinkLogData(uint16_t sequence) { mavlink_message_t msg; mavlink_logging_ack_t ack; memset(&ack, 0, sizeof(ack)); ack.sequence = sequence; ack.target_component = _defaultComponentId; ack.target_system = id(); mavlink_msg_logging_ack_encode_chan( _mavlink->getSystemId(), _mavlink->getComponentId(), priorityLink()->mavlinkChannel(), &msg, &ack); sendMessageOnLink(priorityLink(), msg); } void Vehicle::_handleMavlinkLoggingData(mavlink_message_t& message) { mavlink_logging_data_t log; mavlink_msg_logging_data_decode(&message, &log); emit mavlinkLogData(this, log.target_system, log.target_component, log.sequence, log.first_message_offset, QByteArray((const char*)log.data, log.length), false); } void Vehicle::_handleMavlinkLoggingDataAcked(mavlink_message_t& message) { mavlink_logging_data_acked_t log; mavlink_msg_logging_data_acked_decode(&message, &log); _ackMavlinkLogData(log.sequence); emit mavlinkLogData(this, log.target_system, log.target_component, log.sequence, log.first_message_offset, QByteArray((const char*)log.data, log.length), true); } void Vehicle::setFirmwarePluginInstanceData(QObject* firmwarePluginInstanceData) { firmwarePluginInstanceData->setParent(this); _firmwarePluginInstanceData = firmwarePluginInstanceData; } QString Vehicle::missionFlightMode(void) const { return _firmwarePlugin->missionFlightMode(); } QString Vehicle::pauseFlightMode(void) const { return _firmwarePlugin->pauseFlightMode(); } QString Vehicle::rtlFlightMode(void) const { return _firmwarePlugin->rtlFlightMode(); } QString Vehicle::landFlightMode(void) const { return _firmwarePlugin->landFlightMode(); } QString Vehicle::takeControlFlightMode(void) const { return _firmwarePlugin->takeControlFlightMode(); } QString Vehicle::vehicleImageOpaque() const { if(_firmwarePlugin) return _firmwarePlugin->vehicleImageOpaque(this); else return QString(); } QString Vehicle::vehicleImageOutline() const { if(_firmwarePlugin) return _firmwarePlugin->vehicleImageOutline(this); else return QString(); } QString Vehicle::vehicleImageCompass() const { if(_firmwarePlugin) return _firmwarePlugin->vehicleImageCompass(this); else return QString(); } const QVariantList& Vehicle::toolBarIndicators() { if(_firmwarePlugin) { return _firmwarePlugin->toolBarIndicators(this); } static QVariantList emptyList; return emptyList; } const QVariantList& Vehicle::staticCameraList(void) const { if (_firmwarePlugin) { return _firmwarePlugin->cameraList(this); } static QVariantList emptyList; return emptyList; } bool Vehicle::vehicleYawsToNextWaypointInMission(void) const { return _firmwarePlugin->vehicleYawsToNextWaypointInMission(this); } void Vehicle::_setupAutoDisarmSignalling(void) { QString param = _firmwarePlugin->autoDisarmParameter(this); if (!param.isEmpty() && _parameterManager->parameterExists(FactSystem::defaultComponentId, param)) { Fact* fact = _parameterManager->getParameter(FactSystem::defaultComponentId,param); connect(fact, &Fact::rawValueChanged, this, &Vehicle::autoDisarmChanged); emit autoDisarmChanged(); } } bool Vehicle::autoDisarm(void) { QString param = _firmwarePlugin->autoDisarmParameter(this); if (!param.isEmpty() && _parameterManager->parameterExists(FactSystem::defaultComponentId, param)) { Fact* fact = _parameterManager->getParameter(FactSystem::defaultComponentId,param); return fact->rawValue().toDouble() > 0; } return false; } void Vehicle::_handleADSBVehicle(const mavlink_message_t& message) { mavlink_adsb_vehicle_t adsbVehicle; static const int maxTimeSinceLastSeen = 15; mavlink_msg_adsb_vehicle_decode(&message, &adsbVehicle); if (adsbVehicle.flags | ADSB_FLAGS_VALID_COORDS) { if (_adsbICAOMap.contains(adsbVehicle.ICAO_address)) { if (adsbVehicle.tslc > maxTimeSinceLastSeen) { ADSBVehicle* vehicle = _adsbICAOMap[adsbVehicle.ICAO_address]; _adsbVehicles.removeOne(vehicle); _adsbICAOMap.remove(adsbVehicle.ICAO_address); vehicle->deleteLater(); } else { _adsbICAOMap[adsbVehicle.ICAO_address]->update(adsbVehicle); } } else if (adsbVehicle.tslc <= maxTimeSinceLastSeen) { ADSBVehicle* vehicle = new ADSBVehicle(adsbVehicle, this); _adsbICAOMap[adsbVehicle.ICAO_address] = vehicle; _adsbVehicles.append(vehicle); } } } void Vehicle::_updateDistanceToHome(void) { if (coordinate().isValid() && homePosition().isValid()) { _distanceToHomeFact.setRawValue(coordinate().distanceTo(homePosition())); } else { _distanceToHomeFact.setRawValue(qQNaN()); } } void Vehicle::_updateHobbsMeter(void) { _hobbsFact.setRawValue(hobbsMeter()); } void Vehicle::forceInitialPlanRequestComplete(void) { _initialPlanRequestComplete = true; emit initialPlanRequestCompleteChanged(true); } void Vehicle::sendPlan(QString planFile) { PlanMasterController::sendPlanToVehicle(this, planFile); } QString Vehicle::hobbsMeter() { static const char* HOOBS_HI = "LND_FLIGHT_T_HI"; static const char* HOOBS_LO = "LND_FLIGHT_T_LO"; //-- TODO: Does this exist on non PX4? if (_parameterManager->parameterExists(FactSystem::defaultComponentId, HOOBS_HI) && _parameterManager->parameterExists(FactSystem::defaultComponentId, HOOBS_LO)) { Fact* factHi = _parameterManager->getParameter(FactSystem::defaultComponentId, HOOBS_HI); Fact* factLo = _parameterManager->getParameter(FactSystem::defaultComponentId, HOOBS_LO); uint64_t hobbsTimeSeconds = ((uint64_t)factHi->rawValue().toUInt() << 32 | (uint64_t)factLo->rawValue().toUInt()) / 1000000; int hours = hobbsTimeSeconds / 3600; int minutes = (hobbsTimeSeconds % 3600) / 60; int seconds = hobbsTimeSeconds % 60; QString timeStr; timeStr.sprintf("%04d:%02d:%02d", hours, minutes, seconds); qCDebug(VehicleLog) << "Hobbs Meter:" << timeStr << "(" << factHi->rawValue().toUInt() << factLo->rawValue().toUInt() << ")"; return timeStr; } return QString("0000:00:00"); } void Vehicle::_vehicleParamLoaded(bool ready) { //-- TODO: This seems silly but can you think of a better // way to update this? if(ready) { emit hobbsMeterChanged(); } } void Vehicle::_updateHighLatencyLink(void) { if (_priorityLink->highLatency() != _highLatencyLink) { _highLatencyLink = _priorityLink->highLatency(); _mavCommandAckTimer.setInterval(_highLatencyLink ? _mavCommandAckTimeoutMSecsHighLatency : _mavCommandAckTimeoutMSecs); emit highLatencyLinkChanged(_highLatencyLink); } } //----------------------------------------------------------------------------- //----------------------------------------------------------------------------- const char* VehicleBatteryFactGroup::_voltageFactName = "voltage"; const char* VehicleBatteryFactGroup::_percentRemainingFactName = "percentRemaining"; const char* VehicleBatteryFactGroup::_mahConsumedFactName = "mahConsumed"; const char* VehicleBatteryFactGroup::_currentFactName = "current"; const char* VehicleBatteryFactGroup::_temperatureFactName = "temperature"; const char* VehicleBatteryFactGroup::_cellCountFactName = "cellCount"; const char* VehicleBatteryFactGroup::_instantPowerFactName = "instantPower"; const char* VehicleBatteryFactGroup::_settingsGroup = "Vehicle.battery"; const double VehicleBatteryFactGroup::_voltageUnavailable = -1.0; const int VehicleBatteryFactGroup::_percentRemainingUnavailable = -1; const int VehicleBatteryFactGroup::_mahConsumedUnavailable = -1; const int VehicleBatteryFactGroup::_currentUnavailable = -1; const double VehicleBatteryFactGroup::_temperatureUnavailable = -1.0; const int VehicleBatteryFactGroup::_cellCountUnavailable = -1.0; const double VehicleBatteryFactGroup::_instantPowerUnavailable = -1.0; VehicleBatteryFactGroup::VehicleBatteryFactGroup(QObject* parent) : FactGroup(1000, ":/json/Vehicle/BatteryFact.json", parent) , _voltageFact (0, _voltageFactName, FactMetaData::valueTypeDouble) , _percentRemainingFact (0, _percentRemainingFactName, FactMetaData::valueTypeInt32) , _mahConsumedFact (0, _mahConsumedFactName, FactMetaData::valueTypeInt32) , _currentFact (0, _currentFactName, FactMetaData::valueTypeFloat) , _temperatureFact (0, _temperatureFactName, FactMetaData::valueTypeDouble) , _cellCountFact (0, _cellCountFactName, FactMetaData::valueTypeInt32) , _instantPowerFact (0, _instantPowerFactName, FactMetaData::valueTypeFloat) { _addFact(&_voltageFact, _voltageFactName); _addFact(&_percentRemainingFact, _percentRemainingFactName); _addFact(&_mahConsumedFact, _mahConsumedFactName); _addFact(&_currentFact, _currentFactName); _addFact(&_temperatureFact, _temperatureFactName); _addFact(&_cellCountFact, _cellCountFactName); _addFact(&_instantPowerFact, _instantPowerFactName); // Start out as not available _voltageFact.setRawValue (_voltageUnavailable); _percentRemainingFact.setRawValue (_percentRemainingUnavailable); _mahConsumedFact.setRawValue (_mahConsumedUnavailable); _currentFact.setRawValue (_currentUnavailable); _temperatureFact.setRawValue (_temperatureUnavailable); _cellCountFact.setRawValue (_cellCountUnavailable); _instantPowerFact.setRawValue (_instantPowerUnavailable); } const char* VehicleWindFactGroup::_directionFactName = "direction"; const char* VehicleWindFactGroup::_speedFactName = "speed"; const char* VehicleWindFactGroup::_verticalSpeedFactName = "verticalSpeed"; VehicleWindFactGroup::VehicleWindFactGroup(QObject* parent) : FactGroup(1000, ":/json/Vehicle/WindFact.json", parent) , _directionFact (0, _directionFactName, FactMetaData::valueTypeDouble) , _speedFact (0, _speedFactName, FactMetaData::valueTypeDouble) , _verticalSpeedFact(0, _verticalSpeedFactName, FactMetaData::valueTypeDouble) { _addFact(&_directionFact, _directionFactName); _addFact(&_speedFact, _speedFactName); _addFact(&_verticalSpeedFact, _verticalSpeedFactName); // Start out as not available "--.--" _directionFact.setRawValue (std::numeric_limits::quiet_NaN()); _speedFact.setRawValue (std::numeric_limits::quiet_NaN()); _verticalSpeedFact.setRawValue (std::numeric_limits::quiet_NaN()); } const char* VehicleVibrationFactGroup::_xAxisFactName = "xAxis"; const char* VehicleVibrationFactGroup::_yAxisFactName = "yAxis"; const char* VehicleVibrationFactGroup::_zAxisFactName = "zAxis"; const char* VehicleVibrationFactGroup::_clipCount1FactName = "clipCount1"; const char* VehicleVibrationFactGroup::_clipCount2FactName = "clipCount2"; const char* VehicleVibrationFactGroup::_clipCount3FactName = "clipCount3"; VehicleVibrationFactGroup::VehicleVibrationFactGroup(QObject* parent) : FactGroup(1000, ":/json/Vehicle/VibrationFact.json", parent) , _xAxisFact (0, _xAxisFactName, FactMetaData::valueTypeDouble) , _yAxisFact (0, _yAxisFactName, FactMetaData::valueTypeDouble) , _zAxisFact (0, _zAxisFactName, FactMetaData::valueTypeDouble) , _clipCount1Fact (0, _clipCount1FactName, FactMetaData::valueTypeUint32) , _clipCount2Fact (0, _clipCount2FactName, FactMetaData::valueTypeUint32) , _clipCount3Fact (0, _clipCount3FactName, FactMetaData::valueTypeUint32) { _addFact(&_xAxisFact, _xAxisFactName); _addFact(&_yAxisFact, _yAxisFactName); _addFact(&_zAxisFact, _zAxisFactName); _addFact(&_clipCount1Fact, _clipCount1FactName); _addFact(&_clipCount2Fact, _clipCount2FactName); _addFact(&_clipCount3Fact, _clipCount3FactName); // Start out as not available "--.--" _xAxisFact.setRawValue(std::numeric_limits::quiet_NaN()); _yAxisFact.setRawValue(std::numeric_limits::quiet_NaN()); _zAxisFact.setRawValue(std::numeric_limits::quiet_NaN()); } const char* VehicleTemperatureFactGroup::_temperature1FactName = "temperature1"; const char* VehicleTemperatureFactGroup::_temperature2FactName = "temperature2"; const char* VehicleTemperatureFactGroup::_temperature3FactName = "temperature3"; VehicleTemperatureFactGroup::VehicleTemperatureFactGroup(QObject* parent) : FactGroup(1000, ":/json/Vehicle/TemperatureFact.json", parent) , _temperature1Fact (0, _temperature1FactName, FactMetaData::valueTypeDouble) , _temperature2Fact (0, _temperature2FactName, FactMetaData::valueTypeDouble) , _temperature3Fact (0, _temperature3FactName, FactMetaData::valueTypeDouble) { _addFact(&_temperature1Fact, _temperature1FactName); _addFact(&_temperature2Fact, _temperature2FactName); _addFact(&_temperature3Fact, _temperature3FactName); // Start out as not available "--.--" _temperature1Fact.setRawValue (std::numeric_limits::quiet_NaN()); _temperature2Fact.setRawValue (std::numeric_limits::quiet_NaN()); _temperature3Fact.setRawValue (std::numeric_limits::quiet_NaN()); } const char* VehicleClockFactGroup::_currentTimeFactName = "currentTime"; const char* VehicleClockFactGroup::_currentDateFactName = "currentDate"; VehicleClockFactGroup::VehicleClockFactGroup(QObject* parent) : FactGroup(1000, ":/json/Vehicle/ClockFact.json", parent) , _currentTimeFact (0, _currentTimeFactName, FactMetaData::valueTypeString) , _currentDateFact (0, _currentDateFactName, FactMetaData::valueTypeString) { _addFact(&_currentTimeFact, _currentTimeFactName); _addFact(&_currentDateFact, _currentDateFactName); // Start out as not available "--.--" _currentTimeFact.setRawValue (std::numeric_limits::quiet_NaN()); _currentDateFact.setRawValue (std::numeric_limits::quiet_NaN()); } void VehicleClockFactGroup::_updateAllValues(void) { _currentTimeFact.setRawValue(QTime::currentTime().toString()); _currentDateFact.setRawValue(QDateTime::currentDateTime().toString(QLocale::system().dateFormat(QLocale::ShortFormat))); FactGroup::_updateAllValues(); } const char* VehicleSetpointFactGroup::_rollFactName = "roll"; const char* VehicleSetpointFactGroup::_pitchFactName = "pitch"; const char* VehicleSetpointFactGroup::_yawFactName = "yaw"; const char* VehicleSetpointFactGroup::_rollRateFactName = "rollRate"; const char* VehicleSetpointFactGroup::_pitchRateFactName = "pitchRate"; const char* VehicleSetpointFactGroup::_yawRateFactName = "yawRate"; VehicleSetpointFactGroup::VehicleSetpointFactGroup(QObject* parent) : FactGroup (1000, ":/json/Vehicle/SetpointFact.json", parent) , _rollFact (0, _rollFactName, FactMetaData::valueTypeDouble) , _pitchFact (0, _pitchFactName, FactMetaData::valueTypeDouble) , _yawFact (0, _yawFactName, FactMetaData::valueTypeDouble) , _rollRateFact (0, _rollRateFactName, FactMetaData::valueTypeDouble) , _pitchRateFact(0, _pitchRateFactName, FactMetaData::valueTypeDouble) , _yawRateFact (0, _yawRateFactName, FactMetaData::valueTypeDouble) { _addFact(&_rollFact, _rollFactName); _addFact(&_pitchFact, _pitchFactName); _addFact(&_yawFact, _yawFactName); _addFact(&_rollRateFact, _rollRateFactName); _addFact(&_pitchRateFact, _pitchRateFactName); _addFact(&_yawRateFact, _yawRateFactName); // Start out as not available "--.--" _rollFact.setRawValue(std::numeric_limits::quiet_NaN()); _pitchFact.setRawValue(std::numeric_limits::quiet_NaN()); _yawFact.setRawValue(std::numeric_limits::quiet_NaN()); _rollRateFact.setRawValue(std::numeric_limits::quiet_NaN()); _pitchRateFact.setRawValue(std::numeric_limits::quiet_NaN()); _yawRateFact.setRawValue(std::numeric_limits::quiet_NaN()); }