UAS.cc 138 KB
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/*===================================================================
======================================================================*/

/**
 * @file
 *   @brief Represents one unmanned aerial vehicle
 *
 *   @author Lorenz Meier <mavteam@student.ethz.ch>
 *
 */

#include <QList>
#include <QMessageBox>
#include <QTimer>
#include <QSettings>
#include <iostream>
#include <QDebug>
#include <cmath>
#include <qmath.h>
#include "UAS.h"
#include "LinkInterface.h"
#include "UASManager.h"
#include "QGC.h"
#include "GAudioOutput.h"
#include "MAVLinkProtocol.h"
#include "QGCMAVLink.h"
#include "LinkManager.h"
#include "SerialLink.h"
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#include "UASParameterCommsMgr.h"
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#include <Eigen/Geometry>
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#include <comm/px4_custom_mode.h>
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#ifdef QGC_PROTOBUF_ENABLED
#include <google/protobuf/descriptor.h>
#endif

/**
* Gets the settings from the previous UAS (name, airframe, autopilot, battery specs)
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* by calling readSettings. This means the new UAS will have the same settings
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* as the previous one created unless one calls deleteSettings in the code after
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* creating the UAS.
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*/
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UAS::UAS(MAVLinkProtocol* protocol, QThread* thread, int id) : UASInterface(),
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    lipoFull(4.2f),
    lipoEmpty(3.5f),
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    uasId(id),
    links(new QList<LinkInterface*>()),
    unknownPackets(),
    mavlink(protocol),
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    commStatus(COMM_DISCONNECTED),
    receiveDropRate(0),
    sendDropRate(0),
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    statusTimeout(thread),
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    name(""),
    type(MAV_TYPE_GENERIC),
    airframe(QGC_AIRFRAME_GENERIC),
    autopilot(-1),
    systemIsArmed(false),
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    base_mode(0),
    custom_mode(0),
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    // custom_mode not initialized
    status(-1),
    // shortModeText not initialized
    // shortStateText not initialized

    // actuatorValues not initialized
    // actuatorNames not initialized
    // motorValues not initialized
    // motorNames mnot initialized
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    thrustSum(0),
    thrustMax(10),
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    // batteryType not initialized
    // cells not initialized
    // fullVoltage not initialized
    // emptyVoltage not initialized
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    startVoltage(-1.0f),
    tickVoltage(10.5f),
    lastTickVoltageValue(13.0f),
    tickLowpassVoltage(12.0f),
    warnVoltage(9.5f),
    warnLevelPercent(20.0f),
    currentVoltage(12.6f),
    lpVoltage(12.0f),
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    currentCurrent(0.4f),
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    batteryRemainingEstimateEnabled(false),
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    // chargeLevel not initialized
    // timeRemaining  not initialized
    lowBattAlarm(false),

    startTime(QGC::groundTimeMilliseconds()),
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    onboardTimeOffset(0),
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    controlRollManual(true),
    controlPitchManual(true),
    controlYawManual(true),
    controlThrustManual(true),
    manualRollAngle(0),
    manualPitchAngle(0),
    manualYawAngle(0),
    manualThrust(0),
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    positionLock(false),
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    isLocalPositionKnown(false),
    isGlobalPositionKnown(false),

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    localX(0.0),
    localY(0.0),
    localZ(0.0),
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    latitude(0.0),
    longitude(0.0),
    altitudeAMSL(0.0),
    altitudeRelative(0.0),

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    globalEstimatorActive(false),

    latitude_gps(0.0),
    longitude_gps(0.0),
    altitude_gps(0.0),
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    speedX(0.0),
    speedY(0.0),
    speedZ(0.0),

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    nedPosGlobalOffset(0,0,0),
    nedAttGlobalOffset(0,0,0),

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    #if defined(QGC_PROTOBUF_ENABLED) && defined(QGC_USE_PIXHAWK_MESSAGES)
    receivedOverlayTimestamp(0.0),
    receivedObstacleListTimestamp(0.0),
    receivedPathTimestamp(0.0),
    receivedPointCloudTimestamp(0.0),
    receivedRGBDImageTimestamp(0.0),
    #endif
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    airSpeed(std::numeric_limits<double>::quiet_NaN()),
    groundSpeed(std::numeric_limits<double>::quiet_NaN()),
    waypointManager(this),
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    fileManager(this, this),
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    attitudeKnown(false),
    attitudeStamped(false),
    lastAttitude(0),
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    roll(0.0),
    pitch(0.0),
    yaw(0.0),

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    imagePackets(0),    // We must initialize to 0, otherwise extended data packets maybe incorrectly thought to be images

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    blockHomePositionChanges(false),
    receivedMode(false),


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    paramsOnceRequested(false),
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    paramMgr(this),
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    simulation(0),
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    _thread(thread),
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    // The protected members.
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    connectionLost(false),
    lastVoltageWarning(0),
    lastNonNullTime(0),
    onboardTimeOffsetInvalidCount(0),
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    hilEnabled(false),
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    sensorHil(false),
    lastSendTimeGPS(0),
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    lastSendTimeSensors(0)
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{
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    moveToThread(thread);

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    for (unsigned int i = 0; i<255;++i)
    {
        componentID[i] = -1;
        componentMulti[i] = false;
    }
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    connect(mavlink, SIGNAL(messageReceived(LinkInterface*,mavlink_message_t)), &fileManager, SLOT(receiveMessage(LinkInterface*,mavlink_message_t)));

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    // Store a list of available actions for this UAS.
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    // Basically everything exposed as a SLOT with no return value or arguments.
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    QAction* newAction = new QAction(tr("Arm"), thread);
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    newAction->setToolTip(tr("Enable the UAS so that all actuators are online"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(armSystem()));
    actions.append(newAction);

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    newAction = new QAction(tr("Disarm"), thread);
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    newAction->setToolTip(tr("Disable the UAS so that all actuators are offline"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(disarmSystem()));
    actions.append(newAction);

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    newAction = new QAction(tr("Toggle armed"), thread);
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    newAction->setToolTip(tr("Toggle between armed and disarmed"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(toggleAutonomy()));
    actions.append(newAction);

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    newAction = new QAction(tr("Go home"), thread);
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    newAction->setToolTip(tr("Command the UAS to return to its home position"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(home()));
    actions.append(newAction);

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    newAction = new QAction(tr("Land"), thread);
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    newAction->setToolTip(tr("Command the UAS to land"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(land()));
    actions.append(newAction);

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    newAction = new QAction(tr("Launch"), thread);
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    newAction->setToolTip(tr("Command the UAS to launch itself and begin its mission"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(launch()));
    actions.append(newAction);

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    newAction = new QAction(tr("Resume"), thread);
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    newAction->setToolTip(tr("Command the UAS to continue its mission"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(go()));
    actions.append(newAction);

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    newAction = new QAction(tr("Stop"), thread);
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    newAction->setToolTip(tr("Command the UAS to halt and hold position"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(halt()));
    actions.append(newAction);

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    newAction = new QAction(tr("Go autonomous"), thread);
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    newAction->setToolTip(tr("Set the UAS into an autonomous control mode"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(goAutonomous()));
    actions.append(newAction);

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    newAction = new QAction(tr("Go manual"), thread);
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    newAction->setToolTip(tr("Set the UAS into a manual control mode"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(goManual()));
    actions.append(newAction);

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    newAction = new QAction(tr("Toggle autonomy"), thread);
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    newAction->setToolTip(tr("Toggle between manual and full-autonomy"));
    connect(newAction, SIGNAL(triggered()), this, SLOT(toggleAutonomy()));
    actions.append(newAction);

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    color = UASInterface::getNextColor();
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    setBatterySpecs(QString(""));
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    connect(&statusTimeout, SIGNAL(timeout()), this, SLOT(updateState()));
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    connect(this, SIGNAL(systemSpecsChanged(int)), this, SLOT(writeSettings()));
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    statusTimeout.start(500);
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    readSettings();
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    //need to init paramMgr after readSettings have been loaded, to properly set autopilot and so forth
    paramMgr.initWithUAS(this);
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    // Initial signals
    emit disarmed();
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    emit armingChanged(false);
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}

/**
* Saves the settings of name, airframe, autopilot type and battery specifications
* by calling writeSettings.
*/
UAS::~UAS()
{
    writeSettings();
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    _thread->quit();
    _thread->wait();

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    delete links;
    delete simulation;
}

/**
* Saves the settings of name, airframe, autopilot type and battery specifications
* for the next instantiation of UAS.
*/
void UAS::writeSettings()
{
    QSettings settings;
    settings.beginGroup(QString("MAV%1").arg(uasId));
    settings.setValue("NAME", this->name);
    settings.setValue("AIRFRAME", this->airframe);
    settings.setValue("AP_TYPE", this->autopilot);
    settings.setValue("BATTERY_SPECS", getBatterySpecs());
    settings.endGroup();
    settings.sync();
}

/**
* Reads in the settings: name, airframe, autopilot type, and battery specifications
* for the new UAS.
*/
void UAS::readSettings()
{
    QSettings settings;
    settings.beginGroup(QString("MAV%1").arg(uasId));
    this->name = settings.value("NAME", this->name).toString();
    this->airframe = settings.value("AIRFRAME", this->airframe).toInt();
    this->autopilot = settings.value("AP_TYPE", this->autopilot).toInt();
    if (settings.contains("BATTERY_SPECS"))
    {
        setBatterySpecs(settings.value("BATTERY_SPECS").toString());
    }
    settings.endGroup();
}

/**
*  Deletes the settings origianally read into the UAS by readSettings.
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*  This is in case one does not want the old values but would rather
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*  start with the values assigned by the constructor.
*/
void UAS::deleteSettings()
{
    this->name = "";
    this->airframe = QGC_AIRFRAME_GENERIC;
    this->autopilot = -1;
    setBatterySpecs(QString("9V,9.5V,12.6V"));
}

/**
* @ return the id of the uas
*/
int UAS::getUASID() const
{
    return uasId;
}

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void UAS::triggerAction(int action)
{
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    if (action >= 0 && action < actions.size())
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    {
        qDebug() << "Triggering action: '" << actions[action]->text() << "'";
        actions[action]->trigger();
    }
}

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/**
* Update the heartbeat.
*/
void UAS::updateState()
{
    // Check if heartbeat timed out
    quint64 heartbeatInterval = QGC::groundTimeUsecs() - lastHeartbeat;
    if (!connectionLost && (heartbeatInterval > timeoutIntervalHeartbeat))
    {
        connectionLost = true;
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        receivedMode = false;
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        QString audiostring = QString("Link lost to system %1").arg(this->getUASID());
        GAudioOutput::instance()->say(audiostring.toLower());
    }

    // Update connection loss time on each iteration
    if (connectionLost && (heartbeatInterval > timeoutIntervalHeartbeat))
    {
        connectionLossTime = heartbeatInterval;
        emit heartbeatTimeout(true, heartbeatInterval/1000);
    }

    // Connection gained
    if (connectionLost && (heartbeatInterval < timeoutIntervalHeartbeat))
    {
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        QString audiostring = QString("Link regained to system %1").arg(this->getUASID());
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        GAudioOutput::instance()->say(audiostring.toLower());
        connectionLost = false;
        connectionLossTime = 0;
        emit heartbeatTimeout(false, 0);
    }

    // Position lock is set by the MAVLink message handler
    // if no position lock is available, indicate an error
    if (positionLock)
    {
        positionLock = false;
    }
    else
    {
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        if (((base_mode & MAV_MODE_FLAG_DECODE_POSITION_AUTO) || (base_mode & MAV_MODE_FLAG_DECODE_POSITION_GUIDED)) && positionLock)
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        {
            GAudioOutput::instance()->notifyNegative();
        }
    }
}

/**
* If the acitve UAS (the UAS that was selected) is not the one that is currently
* active, then change the active UAS to the one that was selected.
*/
void UAS::setSelected()
{
    if (UASManager::instance()->getActiveUAS() != this)
    {
        UASManager::instance()->setActiveUAS(this);
        emit systemSelected(true);
    }
}

/**
* @return if the active UAS is the current UAS
**/
bool UAS::getSelected() const
{
    return (UASManager::instance()->getActiveUAS() == this);
}

void UAS::receiveMessage(LinkInterface* link, mavlink_message_t message)
{
    if (!link) return;
    if (!links->contains(link))
    {
        addLink(link);
        //        qDebug() << __FILE__ << __LINE__ << "ADDED LINK!" << link->getName();
    }

    if (!components.contains(message.compid))
    {
        QString componentName;

        switch (message.compid)
        {
        case MAV_COMP_ID_ALL:
        {
            componentName = "ANONYMOUS";
            break;
        }
        case MAV_COMP_ID_IMU:
        {
            componentName = "IMU #1";
            break;
        }
        case MAV_COMP_ID_CAMERA:
        {
            componentName = "CAMERA";
            break;
        }
        case MAV_COMP_ID_MISSIONPLANNER:
        {
            componentName = "MISSIONPLANNER";
            break;
        }
        }

        components.insert(message.compid, componentName);
        emit componentCreated(uasId, message.compid, componentName);
    }

    //    qDebug() << "UAS RECEIVED from" << message.sysid << "component" << message.compid << "msg id" << message.msgid << "seq no" << message.seq;

    // Only accept messages from this system (condition 1)
    // and only then if a) attitudeStamped is disabled OR b) attitudeStamped is enabled
    // and we already got one attitude packet
    if (message.sysid == uasId && (!attitudeStamped || (attitudeStamped && (lastAttitude != 0)) || message.msgid == MAVLINK_MSG_ID_ATTITUDE))
    {
        QString uasState;
        QString stateDescription;

        bool multiComponentSourceDetected = false;
        bool wrongComponent = false;

        switch (message.compid)
        {
        case MAV_COMP_ID_IMU_2:
            // Prefer IMU 2 over IMU 1 (FIXME)
            componentID[message.msgid] = MAV_COMP_ID_IMU_2;
            break;
        default:
            // Do nothing
            break;
        }

        // Store component ID
        if (componentID[message.msgid] == -1)
        {
            // Prefer the first component
            componentID[message.msgid] = message.compid;
        }
        else
        {
            // Got this message already
            if (componentID[message.msgid] != message.compid)
            {
                componentMulti[message.msgid] = true;
                wrongComponent = true;
            }
        }

        if (componentMulti[message.msgid] == true) multiComponentSourceDetected = true;


        switch (message.msgid)
        {
        case MAVLINK_MSG_ID_HEARTBEAT:
        {
            if (multiComponentSourceDetected && wrongComponent)
            {
                break;
            }
            lastHeartbeat = QGC::groundTimeUsecs();
            emit heartbeat(this);
            mavlink_heartbeat_t state;
            mavlink_msg_heartbeat_decode(&message, &state);
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            // Send the base_mode and system_status values to the plotter. This uses the ground time
            // so the Ground Time checkbox must be ticked for these values to display
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            quint64 time = getUnixTime();
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            QString name = QString("M%1:HEARTBEAT.%2").arg(message.sysid);
            emit valueChanged(uasId, name.arg("base_mode"), "bits", state.base_mode, time);
            emit valueChanged(uasId, name.arg("custom_mode"), "bits", state.custom_mode, time);
            emit valueChanged(uasId, name.arg("system_status"), "-", state.system_status, time);

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            // Set new type if it has changed
            if (this->type != state.type)
            {
                this->type = state.type;
                if (airframe == 0)
                {
                    switch (type)
                    {
                    case MAV_TYPE_FIXED_WING:
                        setAirframe(UASInterface::QGC_AIRFRAME_EASYSTAR);
                        break;
                    case MAV_TYPE_QUADROTOR:
                        setAirframe(UASInterface::QGC_AIRFRAME_CHEETAH);
                        break;
                    case MAV_TYPE_HEXAROTOR:
                        setAirframe(UASInterface::QGC_AIRFRAME_HEXCOPTER);
                        break;
                    default:
                        // Do nothing
                        break;
                    }
                }
                this->autopilot = state.autopilot;
                emit systemTypeSet(this, type);
            }

            bool currentlyArmed = state.base_mode & MAV_MODE_FLAG_DECODE_POSITION_SAFETY;

            if (systemIsArmed != currentlyArmed)
            {
                systemIsArmed = currentlyArmed;
                emit armingChanged(systemIsArmed);
                if (systemIsArmed)
                {
                    emit armed();
                }
                else
                {
                    emit disarmed();
                }
            }

            QString audiostring = QString("System %1").arg(uasId);
            QString stateAudio = "";
            QString modeAudio = "";
            QString navModeAudio = "";
            bool statechanged = false;
            bool modechanged = false;

            QString audiomodeText = getAudioModeTextFor(static_cast<int>(state.base_mode));

            if ((state.system_status != this->status) && state.system_status != MAV_STATE_UNINIT)
            {
                statechanged = true;
                this->status = state.system_status;
                getStatusForCode((int)state.system_status, uasState, stateDescription);
                emit statusChanged(this, uasState, stateDescription);
                emit statusChanged(this->status);

                shortStateText = uasState;

                // Adjust for better audio
                if (uasState == QString("STANDBY")) uasState = QString("standing by");
                if (uasState == QString("EMERGENCY")) uasState = QString("emergency condition");
                if (uasState == QString("CRITICAL")) uasState = QString("critical condition");
                if (uasState == QString("SHUTDOWN")) uasState = QString("shutting down");

                stateAudio = uasState;
            }

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            if (this->base_mode != state.base_mode || this->custom_mode != state.custom_mode)
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            {
                modechanged = true;
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                this->base_mode = state.base_mode;
                this->custom_mode = state.custom_mode;
                shortModeText = getShortModeTextFor(this->base_mode, this->custom_mode, this->autopilot);
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                emit modeChanged(this->getUASID(), shortModeText, "");

                modeAudio = " is now in " + audiomodeText;
            }

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            // We got the mode
            receivedMode = true;

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            // AUDIO
            if (modechanged && statechanged)
            {
                // Output both messages
                audiostring += modeAudio + " and " + stateAudio;
            }
            else if (modechanged || statechanged)
            {
                // Output the one message
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                audiostring += modeAudio + stateAudio;
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            }

            if (statechanged && ((int)state.system_status == (int)MAV_STATE_CRITICAL || state.system_status == (int)MAV_STATE_EMERGENCY))
            {
                GAudioOutput::instance()->say(QString("emergency for system %1").arg(this->getUASID()));
                QTimer::singleShot(3000, GAudioOutput::instance(), SLOT(startEmergency()));
            }
            else if (modechanged || statechanged)
            {
                GAudioOutput::instance()->stopEmergency();
                GAudioOutput::instance()->say(audiostring.toLower());
            }
        }

            break;
        case MAVLINK_MSG_ID_SYS_STATUS:
        {
            if (multiComponentSourceDetected && wrongComponent)
            {
                break;
            }
            mavlink_sys_status_t state;
            mavlink_msg_sys_status_decode(&message, &state);

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            // Prepare for sending data to the realtime plotter, which is every field excluding onboard_control_sensors_present.
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            quint64 time = getUnixTime();
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            QString name = QString("M%1:SYS_STATUS.%2").arg(message.sysid);
            emit valueChanged(uasId, name.arg("sensors_enabled"), "bits", state.onboard_control_sensors_enabled, time);
            emit valueChanged(uasId, name.arg("sensors_health"), "bits", state.onboard_control_sensors_health, time);
            emit valueChanged(uasId, name.arg("errors_comm"), "-", state.errors_comm, time);
            emit valueChanged(uasId, name.arg("errors_count1"), "-", state.errors_count1, time);
            emit valueChanged(uasId, name.arg("errors_count2"), "-", state.errors_count2, time);
            emit valueChanged(uasId, name.arg("errors_count3"), "-", state.errors_count3, time);
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            emit valueChanged(uasId, name.arg("errors_count4"), "-", state.errors_count4, time);

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            // Process CPU load.
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            emit loadChanged(this,state.load/10.0f);
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            emit valueChanged(uasId, name.arg("load"), "%", state.load/10.0f, time);
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            // Battery charge/time remaining/voltage calculations
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            currentVoltage = state.voltage_battery/1000.0f;
            lpVoltage = filterVoltage(currentVoltage);
            tickLowpassVoltage = tickLowpassVoltage*0.8f + 0.2f*currentVoltage;

            // We don't want to tick above the threshold
            if (tickLowpassVoltage > tickVoltage)
            {
                lastTickVoltageValue = tickLowpassVoltage;
            }

            if ((startVoltage > 0.0f) && (tickLowpassVoltage < tickVoltage) && (fabs(lastTickVoltageValue - tickLowpassVoltage) > 0.1f)
                    /* warn if lower than treshold */
                    && (lpVoltage < tickVoltage)
                    /* warn only if we have at least the voltage of an empty LiPo cell, else we're sampling something wrong */
                    && (currentVoltage > 3.3f)
                    /* warn only if current voltage is really still lower by a reasonable amount */
                    && ((currentVoltage - 0.2f) < tickVoltage)
                    /* warn only every 12 seconds */
                    && (QGC::groundTimeUsecs() - lastVoltageWarning) > 12000000)
            {
                GAudioOutput::instance()->say(QString("voltage warning: %1 volts").arg(lpVoltage, 0, 'f', 1, QChar(' ')));
                lastVoltageWarning = QGC::groundTimeUsecs();
                lastTickVoltageValue = tickLowpassVoltage;
            }

            if (startVoltage == -1.0f && currentVoltage > 0.1f) startVoltage = currentVoltage;
            timeRemaining = calculateTimeRemaining();
            if (!batteryRemainingEstimateEnabled && chargeLevel != -1)
            {
                chargeLevel = state.battery_remaining;
            }
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            emit batteryChanged(this, lpVoltage, currentCurrent, getChargeLevel(), timeRemaining);
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            emit valueChanged(uasId, name.arg("battery_remaining"), "%", getChargeLevel(), time);
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            // emit voltageChanged(message.sysid, currentVoltage);
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            emit valueChanged(uasId, name.arg("battery_voltage"), "V", currentVoltage, time);
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            // And if the battery current draw is measured, log that also.
            if (state.current_battery != -1)
            {
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                currentCurrent = ((double)state.current_battery)/100.0f;
                emit valueChanged(uasId, name.arg("battery_current"), "A", currentCurrent, time);
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            }
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            // LOW BATTERY ALARM
            if (lpVoltage < warnVoltage && (currentVoltage - 0.2f) < warnVoltage && (currentVoltage > 3.3))
            {
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                // An audio alarm. Does not generate any signals.
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                startLowBattAlarm();
            }
            else
            {
                stopLowBattAlarm();
            }

            // control_sensors_enabled:
            // relevant bits: 11: attitude stabilization, 12: yaw position, 13: z/altitude control, 14: x/y position control
            emit attitudeControlEnabled(state.onboard_control_sensors_enabled & (1 << 11));
            emit positionYawControlEnabled(state.onboard_control_sensors_enabled & (1 << 12));
            emit positionZControlEnabled(state.onboard_control_sensors_enabled & (1 << 13));
            emit positionXYControlEnabled(state.onboard_control_sensors_enabled & (1 << 14));

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            // Trigger drop rate updates as needed. Here we convert the incoming
            // drop_rate_comm value from 1/100 of a percent in a uint16 to a true
            // percentage as a float. We also cap the incoming value at 100% as defined
            // by the MAVLink specifications.
            if (state.drop_rate_comm > 10000)
            {
                state.drop_rate_comm = 10000;
            }
            emit dropRateChanged(this->getUASID(), state.drop_rate_comm/100.0f);
            emit valueChanged(uasId, name.arg("drop_rate_comm"), "%", state.drop_rate_comm/100.0f, time);
        }
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            break;
        case MAVLINK_MSG_ID_ATTITUDE:
        {
            mavlink_attitude_t attitude;
            mavlink_msg_attitude_decode(&message, &attitude);
            quint64 time = getUnixReferenceTime(attitude.time_boot_ms);

            emit attitudeChanged(this, message.compid, QGC::limitAngleToPMPIf(attitude.roll), QGC::limitAngleToPMPIf(attitude.pitch), QGC::limitAngleToPMPIf(attitude.yaw), time);

            if (!wrongComponent)
            {
                lastAttitude = time;
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                setRoll(QGC::limitAngleToPMPIf(attitude.roll));
                setPitch(QGC::limitAngleToPMPIf(attitude.pitch));
                setYaw(QGC::limitAngleToPMPIf(attitude.yaw));
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                attitudeKnown = true;
                emit attitudeChanged(this, getRoll(), getPitch(), getYaw(), time);
                emit attitudeRotationRatesChanged(uasId, attitude.rollspeed, attitude.pitchspeed, attitude.yawspeed, time);
            }
        }
            break;
        case MAVLINK_MSG_ID_ATTITUDE_QUATERNION:
        {
            mavlink_attitude_quaternion_t attitude;
            mavlink_msg_attitude_quaternion_decode(&message, &attitude);
            quint64 time = getUnixReferenceTime(attitude.time_boot_ms);

            double a = attitude.q1;
            double b = attitude.q2;
            double c = attitude.q3;
            double d = attitude.q4;

            double aSq = a * a;
            double bSq = b * b;
            double cSq = c * c;
            double dSq = d * d;
            float dcm[3][3];
            dcm[0][0] = aSq + bSq - cSq - dSq;
            dcm[0][1] = 2.0 * (b * c - a * d);
            dcm[0][2] = 2.0 * (a * c + b * d);
            dcm[1][0] = 2.0 * (b * c + a * d);
            dcm[1][1] = aSq - bSq + cSq - dSq;
            dcm[1][2] = 2.0 * (c * d - a * b);
            dcm[2][0] = 2.0 * (b * d - a * c);
            dcm[2][1] = 2.0 * (a * b + c * d);
            dcm[2][2] = aSq - bSq - cSq + dSq;

            float phi, theta, psi;
            theta = asin(-dcm[2][0]);

            if (fabs(theta - M_PI_2) < 1.0e-3f) {
                phi = 0.0f;
                psi = (atan2(dcm[1][2] - dcm[0][1],
                        dcm[0][2] + dcm[1][1]) + phi);

            } else if (fabs(theta + M_PI_2) < 1.0e-3f) {
                phi = 0.0f;
                psi = atan2f(dcm[1][2] - dcm[0][1],
                          dcm[0][2] + dcm[1][1] - phi);

            } else {
                phi = atan2f(dcm[2][1], dcm[2][2]);
                psi = atan2f(dcm[1][0], dcm[0][0]);
            }

            emit attitudeChanged(this, message.compid, QGC::limitAngleToPMPIf(phi),
                                 QGC::limitAngleToPMPIf(theta),
                                 QGC::limitAngleToPMPIf(psi), time);

            if (!wrongComponent)
            {
                lastAttitude = time;
                setRoll(QGC::limitAngleToPMPIf(phi));
                setPitch(QGC::limitAngleToPMPIf(theta));
                setYaw(QGC::limitAngleToPMPIf(psi));
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                attitudeKnown = true;
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                emit attitudeChanged(this, getRoll(), getPitch(), getYaw(), time);
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                emit attitudeRotationRatesChanged(uasId, attitude.rollspeed, attitude.pitchspeed, attitude.yawspeed, time);
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            }
        }
            break;
        case MAVLINK_MSG_ID_LOCAL_POSITION_NED_SYSTEM_GLOBAL_OFFSET:
        {
            mavlink_local_position_ned_system_global_offset_t offset;
            mavlink_msg_local_position_ned_system_global_offset_decode(&message, &offset);
            nedPosGlobalOffset.setX(offset.x);
            nedPosGlobalOffset.setY(offset.y);
            nedPosGlobalOffset.setZ(offset.z);
            nedAttGlobalOffset.setX(offset.roll);
            nedAttGlobalOffset.setY(offset.pitch);
            nedAttGlobalOffset.setZ(offset.yaw);
        }
            break;
        case MAVLINK_MSG_ID_HIL_CONTROLS:
        {
            mavlink_hil_controls_t hil;
            mavlink_msg_hil_controls_decode(&message, &hil);
            emit hilControlsChanged(hil.time_usec, hil.roll_ailerons, hil.pitch_elevator, hil.yaw_rudder, hil.throttle, hil.mode, hil.nav_mode);
        }
            break;
        case MAVLINK_MSG_ID_VFR_HUD:
        {
            mavlink_vfr_hud_t hud;
            mavlink_msg_vfr_hud_decode(&message, &hud);
            quint64 time = getUnixTime();
            // Display updated values
            emit thrustChanged(this, hud.throttle/100.0);

            if (!attitudeKnown)
            {
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                setYaw(QGC::limitAngleToPMPId((((double)hud.heading)/180.0)*M_PI));
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                emit attitudeChanged(this, getRoll(), getPitch(), getYaw(), time);
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            }

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            setAltitudeAMSL(hud.alt);
            setGroundSpeed(hud.groundspeed);
            if (!isnan(hud.airspeed))
                setAirSpeed(hud.airspeed);
            speedZ = -hud.climb;
            emit altitudeChanged(this, altitudeAMSL, altitudeRelative, -speedZ, time);
            emit speedChanged(this, groundSpeed, airSpeed, time);
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        }
            break;
        case MAVLINK_MSG_ID_LOCAL_POSITION_NED:
            //std::cerr << std::endl;
            //std::cerr << "Decoded attitude message:" << " roll: " << std::dec << mavlink_msg_attitude_get_roll(message.payload) << " pitch: " << mavlink_msg_attitude_get_pitch(message.payload) << " yaw: " << mavlink_msg_attitude_get_yaw(message.payload) << std::endl;
        {
            mavlink_local_position_ned_t pos;
            mavlink_msg_local_position_ned_decode(&message, &pos);
            quint64 time = getUnixTime(pos.time_boot_ms);

            // Emit position always with component ID
            emit localPositionChanged(this, message.compid, pos.x, pos.y, pos.z, time);

            if (!wrongComponent)
            {
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                setLocalX(pos.x);
                setLocalY(pos.y);
                setLocalZ(pos.z);

                speedX = pos.vx;
                speedY = pos.vy;
                speedZ = pos.vz;
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                // Emit
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                emit localPositionChanged(this, localX, localY, localZ, time);
                emit velocityChanged_NED(this, speedX, speedY, speedZ, time);
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                // Set internal state
                if (!positionLock) {
                    // If position was not locked before, notify positive
                    GAudioOutput::instance()->notifyPositive();
                }
                positionLock = true;
                isLocalPositionKnown = true;
            }
        }
            break;
        case MAVLINK_MSG_ID_GLOBAL_VISION_POSITION_ESTIMATE:
        {
            mavlink_global_vision_position_estimate_t pos;
            mavlink_msg_global_vision_position_estimate_decode(&message, &pos);
            quint64 time = getUnixTime(pos.usec);
            emit localPositionChanged(this, message.compid, pos.x, pos.y, pos.z, time);
            emit attitudeChanged(this, message.compid, pos.roll, pos.pitch, pos.yaw, time);
        }
            break;
        case MAVLINK_MSG_ID_GLOBAL_POSITION_INT:
            //std::cerr << std::endl;
            //std::cerr << "Decoded attitude message:" << " roll: " << std::dec << mavlink_msg_attitude_get_roll(message.payload) << " pitch: " << mavlink_msg_attitude_get_pitch(message.payload) << " yaw: " << mavlink_msg_attitude_get_yaw(message.payload) << std::endl;
        {
            mavlink_global_position_int_t pos;
            mavlink_msg_global_position_int_decode(&message, &pos);
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            quint64 time = getUnixTime();
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            setLatitude(pos.lat/(double)1E7);
            setLongitude(pos.lon/(double)1E7);
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            setAltitudeAMSL(pos.alt/1000.0);
            setAltitudeRelative(pos.relative_alt/1000.0);
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            globalEstimatorActive = true;
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            speedX = pos.vx/100.0;
            speedY = pos.vy/100.0;
            speedZ = pos.vz/100.0;
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            emit globalPositionChanged(this, getLatitude(), getLongitude(), getAltitudeAMSL(), time);
            emit altitudeChanged(this, altitudeAMSL, altitudeRelative, -speedZ, time);
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            // We had some frame mess here, global and local axes were mixed.
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            emit velocityChanged_NED(this, speedX, speedY, speedZ, time);
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            setGroundSpeed(qSqrt(speedX*speedX+speedY*speedY));
            emit speedChanged(this, groundSpeed, airSpeed, time);
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            // Set internal state
            if (!positionLock)
            {
                // If position was not locked before, notify positive
                GAudioOutput::instance()->notifyPositive();
            }
            positionLock = true;
            isGlobalPositionKnown = true;
            //TODO fix this hack for forwarding of global position for patch antenna tracking
            forwardMessage(message);
        }
            break;
        case MAVLINK_MSG_ID_GPS_RAW_INT:
        {
            mavlink_gps_raw_int_t pos;
            mavlink_msg_gps_raw_int_decode(&message, &pos);

            quint64 time = getUnixTime(pos.time_usec);
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            emit gpsLocalizationChanged(this, pos.fix_type);
            // TODO: track localization state not only for gps but also for other loc. sources
            int loc_type = pos.fix_type;
            if (loc_type == 1)
            {
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                loc_type = 0;
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            }
            emit localizationChanged(this, loc_type);
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            setSatelliteCount(pos.satellites_visible);
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            if (pos.fix_type > 2)
            {
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                positionLock = true;
                isGlobalPositionKnown = true;
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                latitude_gps = pos.lat/(double)1E7;
                longitude_gps = pos.lon/(double)1E7;
                altitude_gps = pos.alt/1000.0;

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                // If no GLOBAL_POSITION_INT messages ever received, use these raw GPS values instead.
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                if (!globalEstimatorActive) {
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                    setLatitude(latitude_gps);
                    setLongitude(longitude_gps);
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                    setAltitudeAMSL(altitude_gps);
                    emit globalPositionChanged(this, getLatitude(), getLongitude(), getAltitudeAMSL(), time);
                    emit altitudeChanged(this, altitudeAMSL, altitudeRelative, -speedZ, time);
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                    float vel = pos.vel/100.0f;
                    // Smaller than threshold and not NaN
                    if ((vel < 1000000) && !isnan(vel) && !isinf(vel)) {
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                        setGroundSpeed(vel);
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                        emit speedChanged(this, groundSpeed, airSpeed, time);
                    } else {
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                        emit textMessageReceived(uasId, message.compid, MAV_SEVERITY_NOTICE, QString("GCS ERROR: RECEIVED INVALID SPEED OF %1 m/s").arg(vel));
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                    }
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                }
            }
        }
            break;
        case MAVLINK_MSG_ID_GPS_STATUS:
        {
            mavlink_gps_status_t pos;
            mavlink_msg_gps_status_decode(&message, &pos);
            for(int i = 0; i < (int)pos.satellites_visible; i++)
            {
                emit gpsSatelliteStatusChanged(uasId, (unsigned char)pos.satellite_prn[i], (unsigned char)pos.satellite_elevation[i], (unsigned char)pos.satellite_azimuth[i], (unsigned char)pos.satellite_snr[i], static_cast<bool>(pos.satellite_used[i]));
            }
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            setSatelliteCount(pos.satellites_visible);
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        }
            break;
        case MAVLINK_MSG_ID_GPS_GLOBAL_ORIGIN:
        {
            mavlink_gps_global_origin_t pos;
            mavlink_msg_gps_global_origin_decode(&message, &pos);
            emit homePositionChanged(uasId, pos.latitude / 10000000.0, pos.longitude / 10000000.0, pos.altitude / 1000.0);
        }
            break;
        case MAVLINK_MSG_ID_RC_CHANNELS_RAW:
        {
            mavlink_rc_channels_raw_t channels;
            mavlink_msg_rc_channels_raw_decode(&message, &channels);
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            const unsigned int portWidth = 8; // XXX magic number

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            emit remoteControlRSSIChanged(channels.rssi/255.0f);
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            if (channels.chan1_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 0, channels.chan1_raw);
            if (channels.chan2_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 1, channels.chan2_raw);
            if (channels.chan3_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 2, channels.chan3_raw);
            if (channels.chan4_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 3, channels.chan4_raw);
            if (channels.chan5_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 4, channels.chan5_raw);
            if (channels.chan6_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 5, channels.chan6_raw);
            if (channels.chan7_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 6, channels.chan7_raw);
            if (channels.chan8_raw != UINT16_MAX)
                emit remoteControlChannelRawChanged(channels.port * portWidth + 7, channels.chan8_raw);
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        }
            break;
        case MAVLINK_MSG_ID_RC_CHANNELS:
        {
            mavlink_rc_channels_t channels;
            mavlink_msg_rc_channels_decode(&message, &channels);

            // UINT8_MAX indicates this value is unknown
            if (channels.rssi != UINT8_MAX) {
                emit remoteControlRSSIChanged(channels.rssi/100.0f);
            }

            if (channels.chan1_raw != UINT16_MAX && channels.chancount > 0)
                emit remoteControlChannelRawChanged(0, channels.chan1_raw);
            if (channels.chan2_raw != UINT16_MAX && channels.chancount > 1)
                emit remoteControlChannelRawChanged(1, channels.chan2_raw);
            if (channels.chan3_raw != UINT16_MAX && channels.chancount > 2)
                emit remoteControlChannelRawChanged(2, channels.chan3_raw);
            if (channels.chan4_raw != UINT16_MAX && channels.chancount > 3)
                emit remoteControlChannelRawChanged(3, channels.chan4_raw);
            if (channels.chan5_raw != UINT16_MAX && channels.chancount > 4)
                emit remoteControlChannelRawChanged(4, channels.chan5_raw);
            if (channels.chan6_raw != UINT16_MAX && channels.chancount > 5)
                emit remoteControlChannelRawChanged(5, channels.chan6_raw);
            if (channels.chan7_raw != UINT16_MAX && channels.chancount > 6)
                emit remoteControlChannelRawChanged(6, channels.chan7_raw);
            if (channels.chan8_raw != UINT16_MAX && channels.chancount > 7)
                emit remoteControlChannelRawChanged(7, channels.chan8_raw);
            if (channels.chan9_raw != UINT16_MAX && channels.chancount > 8)
                emit remoteControlChannelRawChanged(8, channels.chan9_raw);
            if (channels.chan10_raw != UINT16_MAX && channels.chancount > 9)
                emit remoteControlChannelRawChanged(9, channels.chan10_raw);
            if (channels.chan11_raw != UINT16_MAX && channels.chancount > 10)
                emit remoteControlChannelRawChanged(10, channels.chan11_raw);
            if (channels.chan12_raw != UINT16_MAX && channels.chancount > 11)
                emit remoteControlChannelRawChanged(11, channels.chan12_raw);
            if (channels.chan13_raw != UINT16_MAX && channels.chancount > 12)
                emit remoteControlChannelRawChanged(12, channels.chan13_raw);
            if (channels.chan14_raw != UINT16_MAX && channels.chancount > 13)
                emit remoteControlChannelRawChanged(13, channels.chan14_raw);
            if (channels.chan15_raw != UINT16_MAX && channels.chancount > 14)
                emit remoteControlChannelRawChanged(14, channels.chan15_raw);
            if (channels.chan16_raw != UINT16_MAX && channels.chancount > 15)
                emit remoteControlChannelRawChanged(15, channels.chan16_raw);
            if (channels.chan17_raw != UINT16_MAX && channels.chancount > 16)
                emit remoteControlChannelRawChanged(16, channels.chan17_raw);
            if (channels.chan18_raw != UINT16_MAX && channels.chancount > 17)
                emit remoteControlChannelRawChanged(17, channels.chan18_raw);

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        }
            break;
        case MAVLINK_MSG_ID_RC_CHANNELS_SCALED:
        {
            mavlink_rc_channels_scaled_t channels;
            mavlink_msg_rc_channels_scaled_decode(&message, &channels);
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            const unsigned int portWidth = 8; // XXX magic number

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            emit remoteControlRSSIChanged(channels.rssi/255.0f);
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            if (static_cast<uint16_t>(channels.chan1_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 0, channels.chan1_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan2_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 1, channels.chan2_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan3_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 2, channels.chan3_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan4_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 3, channels.chan4_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan5_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 4, channels.chan5_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan6_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 5, channels.chan6_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan7_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 6, channels.chan7_scaled/10000.0f);
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            if (static_cast<uint16_t>(channels.chan8_scaled) != UINT16_MAX)
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                emit remoteControlChannelScaledChanged(channels.port * portWidth + 7, channels.chan8_scaled/10000.0f);
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        }
            break;
        case MAVLINK_MSG_ID_PARAM_VALUE:
        {
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            mavlink_param_value_t rawValue;
            mavlink_msg_param_value_decode(&message, &rawValue);
            QByteArray bytes(rawValue.param_id, MAVLINK_MSG_PARAM_VALUE_FIELD_PARAM_ID_LEN);
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            // Construct a string stopping at the first NUL (0) character, else copy the whole
            // byte array (max MAVLINK_MSG_PARAM_VALUE_FIELD_PARAM_ID_LEN, so safe)
            QString parameterName(bytes);
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            mavlink_param_union_t paramVal;
            paramVal.param_float = rawValue.param_value;
            paramVal.type = rawValue.param_type;
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            processParamValueMsg(message, parameterName,rawValue,paramVal);
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            processParamValueMsgHook(message, parameterName,rawValue,paramVal);
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         }
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            break;
        case MAVLINK_MSG_ID_COMMAND_ACK:
        {
            mavlink_command_ack_t ack;
            mavlink_msg_command_ack_decode(&message, &ack);
            switch (ack.result)
            {
            case MAV_RESULT_ACCEPTED:
            {
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                emit textMessageReceived(uasId, message.compid, MAV_SEVERITY_INFO, tr("SUCCESS: Executed CMD: %1").arg(ack.command));
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            }
                break;
            case MAV_RESULT_TEMPORARILY_REJECTED:
            {
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                emit textMessageReceived(uasId, message.compid, MAV_SEVERITY_WARNING, tr("FAILURE: Temporarily rejected CMD: %1").arg(ack.command));
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            }
                break;
            case MAV_RESULT_DENIED:
            {
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                emit textMessageReceived(uasId, message.compid, MAV_SEVERITY_ERROR, tr("FAILURE: Denied CMD: %1").arg(ack.command));
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            }
                break;
            case MAV_RESULT_UNSUPPORTED:
            {
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                emit textMessageReceived(uasId, message.compid, MAV_SEVERITY_WARNING, tr("FAILURE: Unsupported CMD: %1").arg(ack.command));
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            }
                break;
            case MAV_RESULT_FAILED:
            {
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                emit textMessageReceived(uasId, message.compid, MAV_SEVERITY_ERROR, tr("FAILURE: Failed CMD: %1").arg(ack.command));
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            }
                break;
            }
        }
        case MAVLINK_MSG_ID_ROLL_PITCH_YAW_THRUST_SETPOINT:
        {
            mavlink_roll_pitch_yaw_thrust_setpoint_t out;
            mavlink_msg_roll_pitch_yaw_thrust_setpoint_decode(&message, &out);
            quint64 time = getUnixTimeFromMs(out.time_boot_ms);
            emit attitudeThrustSetPointChanged(this, out.roll, out.pitch, out.yaw, out.thrust, time);
        }
            break;
        case MAVLINK_MSG_ID_MISSION_COUNT:
        {
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            mavlink_mission_count_t mc;
            mavlink_msg_mission_count_decode(&message, &mc);

            // Special case a 0 for the target system or component, it means that anyone is the target, so we should process this.
            if (mc.target_system == 0) {
                mc.target_system = mavlink->getSystemId();
            }
            if (mc.target_component == 0) {
                mc.target_component = mavlink->getComponentId();
            }

            // Check that this message applies to the UAS.
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            if(mc.target_system == mavlink->getSystemId())
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            {
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                if (mc.target_component != mavlink->getComponentId()) {
                    qDebug() << "The target component ID is not set correctly. This is currently only a warning, but will be turned into an error.";
                    qDebug() << "Expecting" << mavlink->getComponentId() << "but got" << mc.target_component;
                }

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                waypointManager.handleWaypointCount(message.sysid, message.compid, mc.count);
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            }
            else
            {
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                qDebug() << QString("Received mission count message, but was wrong system id. Expected %1, received %2").arg(mavlink->getSystemId()).arg(mc.target_system);
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            }
        }
            break;

        case MAVLINK_MSG_ID_MISSION_ITEM:
        {
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            mavlink_mission_item_t mi;
            mavlink_msg_mission_item_decode(&message, &mi);

            // Special case a 0 for the target system or component, it means that anyone is the target, so we should process this.
            if (mi.target_system == 0) {
                mi.target_system = mavlink->getSystemId();
            }
            if (mi.target_component == 0) {
                mi.target_component = mavlink->getComponentId();
            }

            // Check that the item pertains to this UAS.
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            if(mi.target_system == mavlink->getSystemId())
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            {
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                if (mi.target_component != mavlink->getComponentId()) {
                    qDebug() << "The target component ID is not set correctly. This is currently only a warning, but will be turned into an error.";
                    qDebug() << "Expecting" << mavlink->getComponentId() << "but got" << mi.target_component;
                }

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                waypointManager.handleWaypoint(message.sysid, message.compid, &mi);
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            }
            else
            {
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                qDebug() << QString("Received mission item message, but was wrong system id. Expected %1, received %2").arg(mavlink->getSystemId()).arg(mi.target_system);
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            }
        }
            break;

        case MAVLINK_MSG_ID_MISSION_ACK:
        {
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            mavlink_mission_ack_t ma;
            mavlink_msg_mission_ack_decode(&message, &ma);

            // Special case a 0 for the target system or component, it means that anyone is the target, so we should process this.
            if (ma.target_system == 0) {
                ma.target_system = mavlink->getSystemId();
            }
            if (ma.target_component == 0) {
                ma.target_component = mavlink->getComponentId();
            }

            // Check that the ack pertains to this UAS.
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            if(ma.target_system == mavlink->getSystemId())
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            {
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                if (ma.target_component != mavlink->getComponentId()) {
                    qDebug() << tr("The target component ID is not set correctly. This is currently only a warning, but will be turned into an error.");
                    qDebug() << "Expecting" << mavlink->getComponentId() << "but got" << ma.target_component;
                }

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                waypointManager.handleWaypointAck(message.sysid, message.compid, &ma);
            }
            else
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            {
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                qDebug() << QString("Received mission ack message, but was wrong system id. Expected %1, received %2").arg(mavlink->getSystemId()).arg(ma.target_system);
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            }
        }
            break;

        case MAVLINK_MSG_ID_MISSION_REQUEST:
        {
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            mavlink_mission_request_t mr;
            mavlink_msg_mission_request_decode(&message, &mr);

            // Special case a 0 for the target system or component, it means that anyone is the target, so we should process this.
            if (mr.target_system == 0) {
                mr.target_system = mavlink->getSystemId();
            }
            if (mr.target_component == 0) {
                mr.target_component = mavlink->getComponentId();
            }

            // Check that the request pertains to this UAS.
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            if(mr.target_system == mavlink->getSystemId())
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            {
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                if (mr.target_component != mavlink->getComponentId()) {
                    qDebug() << QString("The target component ID is not set correctly. This is currently only a warning, but will be turned into an error.");
                    qDebug() << "Expecting" << mavlink->getComponentId() << "but got" << mr.target_component;
                }

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                waypointManager.handleWaypointRequest(message.sysid, message.compid, &mr);
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            }
            else
            {
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                qDebug() << QString("Received mission request message, but was wrong system id. Expected %1, received %2").arg(mavlink->getSystemId()).arg(mr.target_system);
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            }
        }
            break;

        case MAVLINK_MSG_ID_MISSION_ITEM_REACHED:
        {
            mavlink_mission_item_reached_t wpr;
            mavlink_msg_mission_item_reached_decode(&message, &wpr);
            waypointManager.handleWaypointReached(message.sysid, message.compid, &wpr);
            QString text = QString("System %1 reached waypoint %2").arg(getUASName()).arg(wpr.seq);
            GAudioOutput::instance()->say(text);
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            emit textMessageReceived(message.sysid, message.compid, MAV_SEVERITY_INFO, text);
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        }
            break;

        case MAVLINK_MSG_ID_MISSION_CURRENT:
        {
            mavlink_mission_current_t wpc;
            mavlink_msg_mission_current_decode(&message, &wpc);
            waypointManager.handleWaypointCurrent(message.sysid, message.compid, &wpc);
        }
            break;

        case MAVLINK_MSG_ID_LOCAL_POSITION_SETPOINT:
        {
            if (multiComponentSourceDetected && wrongComponent)
            {
                break;
            }
            mavlink_local_position_setpoint_t p;
            mavlink_msg_local_position_setpoint_decode(&message, &p);
            emit positionSetPointsChanged(uasId, p.x, p.y, p.z, p.yaw, QGC::groundTimeUsecs());
        }
            break;
        case MAVLINK_MSG_ID_SET_LOCAL_POSITION_SETPOINT:
        {
            mavlink_set_local_position_setpoint_t p;
            mavlink_msg_set_local_position_setpoint_decode(&message, &p);
            emit userPositionSetPointsChanged(uasId, p.x, p.y, p.z, p.yaw);
        }
            break;
        case MAVLINK_MSG_ID_STATUSTEXT:
        {
            QByteArray b;
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            b.resize(MAVLINK_MSG_STATUSTEXT_FIELD_TEXT_LEN+1);
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            mavlink_msg_statustext_get_text(&message, b.data());
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            // Ensure NUL-termination
            b[b.length()-1] = '\0';
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            QString text = QString(b);
            int severity = mavlink_msg_statustext_get_severity(&message);

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            if (text.startsWith("#") || severity <= MAV_SEVERITY_WARNING)
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            {
                text.remove("#audio:");
                emit textMessageReceived(uasId, message.compid, severity, QString("Audio message: ") + text);
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                GAudioOutput::instance()->say(text.toLower(), severity);
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            }
            else
            {
                emit textMessageReceived(uasId, message.compid, severity, text);
            }
        }
            break;
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#if 0
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        case MAVLINK_MSG_ID_SERVO_OUTPUT_RAW:
        {
            mavlink_servo_output_raw_t raw;
            mavlink_msg_servo_output_raw_decode(&message, &raw);

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            if (hilEnabled && raw.port == 0)
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            {
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                emit hilActuatorsChanged(static_cast<uint64_t>(getUnixTimeFromMs(raw.time_usec)), static_cast<float>(raw.servo1_raw),
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                                     static_cast<float>(raw.servo2_raw), static_cast<float>(raw.servo3_raw),
                                     static_cast<float>(raw.servo4_raw), static_cast<float>(raw.servo5_raw), static_cast<float>(raw.servo6_raw),
                                     static_cast<float>(raw.servo7_raw), static_cast<float>(raw.servo8_raw));
            }
        }
        break;
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#endif
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        case MAVLINK_MSG_ID_DATA_TRANSMISSION_HANDSHAKE:
        {
            mavlink_data_transmission_handshake_t p;
            mavlink_msg_data_transmission_handshake_decode(&message, &p);
            imageSize = p.size;
            imagePackets = p.packets;
            imagePayload = p.payload;
            imageQuality = p.jpg_quality;
            imageType = p.type;
            imageWidth = p.width;
            imageHeight = p.height;
            imageStart = QGC::groundTimeMilliseconds();
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            imagePacketsArrived = 0;

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        }
            break;

        case MAVLINK_MSG_ID_ENCAPSULATED_DATA:
        {
            mavlink_encapsulated_data_t img;
            mavlink_msg_encapsulated_data_decode(&message, &img);
            int seq = img.seqnr;
            int pos = seq * imagePayload;

            // Check if we have a valid transaction
            if (imagePackets == 0)
            {
                // NO VALID TRANSACTION - ABORT
                // Restart statemachine
                imagePacketsArrived = 0;
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                break;
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            }

            for (int i = 0; i < imagePayload; ++i)
            {
                if (pos <= imageSize) {
                    imageRecBuffer[pos] = img.data[i];
                }
                ++pos;
            }

            ++imagePacketsArrived;

            // emit signal if all packets arrived
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            if (imagePacketsArrived >= imagePackets)
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            {
                // Restart statemachine
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                imagePackets = 0;
                imagePacketsArrived = 0;
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                emit imageReady(this);
                //qDebug() << "imageReady emitted. all packets arrived";
            }
        }
            break;


            //        case MAVLINK_MSG_ID_OBJECT_DETECTION_EVENT:
            //        {
            //            mavlink_object_detection_event_t event;
            //            mavlink_msg_object_detection_event_decode(&message, &event);
            //            QString str(event.name);
            //            emit objectDetected(event.time, event.object_id, event.type, str, event.quality, event.bearing, event.distance);
            //        }
            //        break;
            // WILL BE ENABLED ONCE MESSAGE IS IN COMMON MESSAGE SET
            //        case MAVLINK_MSG_ID_MEMORY_VECT:
            //        {
            //            mavlink_memory_vect_t vect;
            //            mavlink_msg_memory_vect_decode(&message, &vect);
            //            QString str("mem_%1");
            //            quint64 time = getUnixTime(0);
            //            int16_t *mem0 = (int16_t *)&vect.value[0];
            //            uint16_t *mem1 = (uint16_t *)&vect.value[0];
            //            int32_t *mem2 = (int32_t *)&vect.value[0];
            //            // uint32_t *mem3 = (uint32_t *)&vect.value[0]; causes overload problem
            //            float *mem4 = (float *)&vect.value[0];
            //            if ( vect.ver == 0) vect.type = 0, vect.ver = 1; else ;
            //            if ( vect.ver == 1)
            //            {
            //                switch (vect.type) {
            //                default:
            //                case 0:
            //                    for (int i = 0; i < 16; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "i16", mem0[i], time);
            //                    break;
            //                case 1:
            //                    for (int i = 0; i < 16; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "ui16", mem1[i], time);
            //                    break;
            //                case 2:
            //                    for (int i = 0; i < 16; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "Q15", (float)mem0[i]/32767.0, time);
            //                    break;
            //                case 3:
            //                    for (int i = 0; i < 16; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*2)), "1Q14", (float)mem0[i]/16383.0, time);
            //                    break;
            //                case 4:
            //                    for (int i = 0; i < 8; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*4)), "i32", mem2[i], time);
            //                    break;
            //                case 5:
            //                    for (int i = 0; i < 8; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*4)), "i32", mem2[i], time);
            //                    break;
            //                case 6:
            //                    for (int i = 0; i < 8; i++)
            //                        // FIXME REMOVE LATER emit valueChanged(uasId, str.arg(vect.address+(i*4)), "float", mem4[i], time);
            //                    break;
            //                }
            //            }
            //        }
            //        break;
#ifdef MAVLINK_ENABLED_UALBERTA
        case MAVLINK_MSG_ID_NAV_FILTER_BIAS:
        {
            mavlink_nav_filter_bias_t bias;
            mavlink_msg_nav_filter_bias_decode(&message, &bias);
            quint64 time = getUnixTime();
            // FIXME REMOVE LATER emit valueChanged(uasId, "b_f[0]", "raw", bias.accel_0, time);
            // FIXME REMOVE LATER emit valueChanged(uasId, "b_f[1]", "raw", bias.accel_1, time);
            // FIXME REMOVE LATER emit valueChanged(uasId, "b_f[2]", "raw", bias.accel_2, time);
            // FIXME REMOVE LATER emit valueChanged(uasId, "b_w[0]", "raw", bias.gyro_0, time);
            // FIXME REMOVE LATER emit valueChanged(uasId, "b_w[1]", "raw", bias.gyro_1, time);
            // FIXME REMOVE LATER emit valueChanged(uasId, "b_w[2]", "raw", bias.gyro_2, time);
        }
            break;
        case MAVLINK_MSG_ID_RADIO_CALIBRATION:
        {
            mavlink_radio_calibration_t radioMsg;
            mavlink_msg_radio_calibration_decode(&message, &radioMsg);
            QVector<uint16_t> aileron;
            QVector<uint16_t> elevator;
            QVector<uint16_t> rudder;
            QVector<uint16_t> gyro;
            QVector<uint16_t> pitch;
            QVector<uint16_t> throttle;

            for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_AILERON_LEN; ++i)
                aileron << radioMsg.aileron[i];
            for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_ELEVATOR_LEN; ++i)
                elevator << radioMsg.elevator[i];
            for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_RUDDER_LEN; ++i)
                rudder << radioMsg.rudder[i];
            for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_GYRO_LEN; ++i)
                gyro << radioMsg.gyro[i];
            for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_PITCH_LEN; ++i)
                pitch << radioMsg.pitch[i];
            for (int i=0; i<MAVLINK_MSG_RADIO_CALIBRATION_FIELD_THROTTLE_LEN; ++i)
                throttle << radioMsg.throttle[i];

            QPointer<RadioCalibrationData> radioData = new RadioCalibrationData(aileron, elevator, rudder, gyro, pitch, throttle);
            emit radioCalibrationReceived(radioData);
            delete radioData;
        }
            break;

#endif
        case MAVLINK_MSG_ID_NAV_CONTROLLER_OUTPUT:
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        {
            //mavlink_set_local_position_setpoint_t p;
            //mavlink_msg_set_local_position_setpoint_decode(&message, &p);
            //emit userPositionSetPointsChanged(uasId, p.x, p.y, p.z, p.yaw);
            mavlink_nav_controller_output_t p;
            mavlink_msg_nav_controller_output_decode(&message,&p);
            setDistToWaypoint(p.wp_dist);
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            setBearingToWaypoint(p.nav_bearing);
            //setAltitudeError(p.alt_error);
            //setSpeedError(p.aspd_error);
            //setCrosstrackingError(p.xtrack_error);
            emit navigationControllerErrorsChanged(this, p.alt_error, p.aspd_error, p.xtrack_error);
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        }
            break;
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        // Messages to ignore
        case MAVLINK_MSG_ID_RAW_IMU:
        case MAVLINK_MSG_ID_SCALED_IMU:
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        case MAVLINK_MSG_ID_RAW_PRESSURE:
        case MAVLINK_MSG_ID_SCALED_PRESSURE:
        case MAVLINK_MSG_ID_OPTICAL_FLOW:
        case MAVLINK_MSG_ID_DEBUG_VECT:
        case MAVLINK_MSG_ID_DEBUG:
        case MAVLINK_MSG_ID_NAMED_VALUE_FLOAT:
        case MAVLINK_MSG_ID_NAMED_VALUE_INT:
        case MAVLINK_MSG_ID_MANUAL_CONTROL:
        case MAVLINK_MSG_ID_HIGHRES_IMU:
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        case MAVLINK_MSG_ID_DISTANCE_SENSOR:
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            break;
        default:
        {
            if (!unknownPackets.contains(message.msgid))
            {
                unknownPackets.append(message.msgid);
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                emit unknownPacketReceived(uasId, message.compid, message.msgid);
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                qWarning() << "Unknown message from system:" << uasId << "message:" << message.msgid;
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            }
        }
            break;
        }
    }
}


#if defined(QGC_PROTOBUF_ENABLED)
/**
* Receive an extended message.
* @param link
* @param message
*/
void UAS::receiveExtendedMessage(LinkInterface* link, std::tr1::shared_ptr<google::protobuf::Message> message)
{
    if (!link)
    {
        return;
    }
    if (!links->contains(link))
    {
        addLink(link);
    }

    const google::protobuf::Descriptor* descriptor = message->GetDescriptor();
    if (!descriptor)
    {
        return;
    }

    const google::protobuf::FieldDescriptor* headerField = descriptor->FindFieldByName("header");
    if (!headerField)
    {
        return;
    }

    const google::protobuf::Descriptor* headerDescriptor = headerField->message_type();
    if (!headerDescriptor)
    {
        return;
    }

    const google::protobuf::FieldDescriptor* sourceSysIdField = headerDescriptor->FindFieldByName("source_sysid");
    if (!sourceSysIdField)
    {
        return;
    }

    const google::protobuf::Reflection* reflection = message->GetReflection();
    const google::protobuf::Message& headerMsg = reflection->GetMessage(*message, headerField);
    const google::protobuf::Reflection* headerReflection = headerMsg.GetReflection();

    int source_sysid = headerReflection->GetInt32(headerMsg, sourceSysIdField);

    if (source_sysid != uasId)
    {
        return;
    }

#ifdef QGC_USE_PIXHAWK_MESSAGES
    if (message->GetTypeName() == overlay.GetTypeName())
    {
        receivedOverlayTimestamp = QGC::groundTimeSeconds();
        overlayMutex.lock();
        overlay.CopyFrom(*message);
        overlayMutex.unlock();
        emit overlayChanged(this);
    }
    else if (message->GetTypeName() == obstacleList.GetTypeName())
    {
        receivedObstacleListTimestamp = QGC::groundTimeSeconds();
        obstacleListMutex.lock();
        obstacleList.CopyFrom(*message);
        obstacleListMutex.unlock();
        emit obstacleListChanged(this);
    }
    else if (message->GetTypeName() == path.GetTypeName())
    {
        receivedPathTimestamp = QGC::groundTimeSeconds();
        pathMutex.lock();
        path.CopyFrom(*message);
        pathMutex.unlock();
        emit pathChanged(this);
    }
    else if (message->GetTypeName() == pointCloud.GetTypeName())
    {
        receivedPointCloudTimestamp = QGC::groundTimeSeconds();
        pointCloudMutex.lock();
        pointCloud.CopyFrom(*message);
        pointCloudMutex.unlock();
        emit pointCloudChanged(this);
    }
    else if (message->GetTypeName() == rgbdImage.GetTypeName())
    {
        receivedRGBDImageTimestamp = QGC::groundTimeSeconds();
        rgbdImageMutex.lock();
        rgbdImage.CopyFrom(*message);
        rgbdImageMutex.unlock();
        emit rgbdImageChanged(this);
    }
#endif
}

#endif

/**
* Set the home position of the UAS.
* @param lat The latitude fo the home position
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* @param lon The longitude of the home position
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* @param alt The altitude of the home position
*/
void UAS::setHomePosition(double lat, double lon, double alt)
{
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    if (blockHomePositionChanges)
        return;

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    QString uasName = (getUASName() == "")?
                tr("UAS") + QString::number(getUASID())
              : getUASName();

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    QMessageBox msgBox;
    msgBox.setIcon(QMessageBox::Warning);
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    msgBox.setText(tr("Set a new home position for vehicle %1").arg(uasName));
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    msgBox.setInformativeText("Do you want to set a new origin? Waypoints defined in the local frame will be shifted in their physical location");
    msgBox.setStandardButtons(QMessageBox::Yes | QMessageBox::Cancel);
    msgBox.setDefaultButton(QMessageBox::Cancel);
    int ret = msgBox.exec();

    // Close the message box shortly after the click to prevent accidental clicks
    QTimer::singleShot(5000, &msgBox, SLOT(reject()));


    if (ret == QMessageBox::Yes)
    {
        mavlink_message_t msg;
        mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, this->getUASID(), 0, MAV_CMD_DO_SET_HOME, 1, 0, 0, 0, 0, lat, lon, alt);
        // Send message twice to increase chance that it reaches its goal
        sendMessage(msg);

        // Send new home position to UAS
        mavlink_set_gps_global_origin_t home;
        home.target_system = uasId;
        home.latitude = lat*1E7;
        home.longitude = lon*1E7;
        home.altitude = alt*1000;
        qDebug() << "lat:" << home.latitude << " lon:" << home.longitude;
        mavlink_msg_set_gps_global_origin_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &home);
        sendMessage(msg);
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    } else {
        blockHomePositionChanges = true;
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    }
}

/**
* Set the origin to the current GPS location.
**/
void UAS::setLocalOriginAtCurrentGPSPosition()
{
    QMessageBox msgBox;
    msgBox.setIcon(QMessageBox::Warning);
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    msgBox.setText("Set the home position at the current GPS position?");
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    msgBox.setInformativeText("Do you want to set a new origin? Waypoints defined in the local frame will be shifted in their physical location");
    msgBox.setStandardButtons(QMessageBox::Yes | QMessageBox::Cancel);
    msgBox.setDefaultButton(QMessageBox::Cancel);
    int ret = msgBox.exec();

    // Close the message box shortly after the click to prevent accidental clicks
    QTimer::singleShot(5000, &msgBox, SLOT(reject()));


    if (ret == QMessageBox::Yes)
    {
        mavlink_message_t msg;
        mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, this->getUASID(), 0, MAV_CMD_DO_SET_HOME, 1, 1, 0, 0, 0, 0, 0, 0);
        // Send message twice to increase chance that it reaches its goal
        sendMessage(msg);
    }
}

/**
* Set a local position setpoint.
* @param x postion
* @param y position
* @param z position
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*/
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void UAS::setLocalPositionSetpoint(float x, float y, float z, float yaw)
{
#ifdef MAVLINK_ENABLED_PIXHAWK
    mavlink_message_t msg;
    mavlink_msg_set_local_position_setpoint_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_FRAME_LOCAL_NED, x, y, z, yaw/M_PI*180.0);
    sendMessage(msg);
#else
    Q_UNUSED(x);
    Q_UNUSED(y);
    Q_UNUSED(z);
    Q_UNUSED(yaw);
#endif
}

/**
* Set a offset of the local position.
* @param x position
* @param y position
* @param z position
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* @param yaw
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*/
void UAS::setLocalPositionOffset(float x, float y, float z, float yaw)
{
#ifdef MAVLINK_ENABLED_PIXHAWK
    mavlink_message_t msg;
    mavlink_msg_set_position_control_offset_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, x, y, z, yaw);
    sendMessage(msg);
#else
    Q_UNUSED(x);
    Q_UNUSED(y);
    Q_UNUSED(z);
    Q_UNUSED(yaw);
#endif
}

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void UAS::startRadioControlCalibration(int param)
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{
    mavlink_message_t msg;
    // Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
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    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 0, 0, param, 0, 0, 0);
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    sendMessage(msg);
}

void UAS::endRadioControlCalibration()
{
    mavlink_message_t msg;
    // Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 0, 0, 0, 0, 0, 0);
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    sendMessage(msg);
}

void UAS::startDataRecording()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_DO_CONTROL_VIDEO, 1, -1, -1, -1, 2, 0, 0, 0);
    sendMessage(msg);
}

void UAS::stopDataRecording()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_DO_CONTROL_VIDEO, 1, -1, -1, -1, 0, 0, 0, 0);
    sendMessage(msg);
}

void UAS::startMagnetometerCalibration()
{
    mavlink_message_t msg;
    // Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 1, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

void UAS::startGyroscopeCalibration()
{
    mavlink_message_t msg;
    // Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 1, 0, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

void UAS::startPressureCalibration()
{
    mavlink_message_t msg;
    // Param 1: gyro cal, param 2: mag cal, param 3: pressure cal, Param 4: radio
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_IMU, MAV_CMD_PREFLIGHT_CALIBRATION, 1, 0, 0, 1, 0, 0, 0, 0);
    sendMessage(msg);
}

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/**
* Check if time is smaller than 40 years, assuming no system without Unix
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* timestamp runs longer than 40 years continuously without reboot. In worst case
* this will add/subtract the communication delay between GCS and MAV, it will
* never alter the timestamp in a safety critical way.
*/
quint64 UAS::getUnixReferenceTime(quint64 time)
{
    // Same as getUnixTime, but does not react to attitudeStamped mode
    if (time == 0)
    {
        //        qDebug() << "XNEW time:" <<QGC::groundTimeMilliseconds();
        return QGC::groundTimeMilliseconds();
    }
    // Check if time is smaller than 40 years,
    // assuming no system without Unix timestamp
    // runs longer than 40 years continuously without
    // reboot. In worst case this will add/subtract the
    // communication delay between GCS and MAV,
    // it will never alter the timestamp in a safety
    // critical way.
    //
    // Calculation:
    // 40 years
    // 365 days
    // 24 hours
    // 60 minutes
    // 60 seconds
    // 1000 milliseconds
    // 1000 microseconds
#ifndef _MSC_VER
    else if (time < 1261440000000000LLU)
#else
    else if (time < 1261440000000000)
#endif
    {
        //        qDebug() << "GEN time:" << time/1000 + onboardTimeOffset;
        if (onboardTimeOffset == 0)
        {
            onboardTimeOffset = QGC::groundTimeMilliseconds() - time/1000;
        }
        return time/1000 + onboardTimeOffset;
    }
    else
    {
        // Time is not zero and larger than 40 years -> has to be
        // a Unix epoch timestamp. Do nothing.
        return time/1000;
    }
}

/**
* @warning If attitudeStamped is enabled, this function will not actually return
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* the precise time stamp of this measurement augmented to UNIX time, but will
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* MOVE the timestamp IN TIME to match the last measured attitude. There is no
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* reason why one would want this, except for system setups where the onboard
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* clock is not present or broken and datasets should be collected that are still
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* roughly synchronized. PLEASE NOTE THAT ENABLING ATTITUDE STAMPED RUINS THE
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* SCIENTIFIC NATURE OF THE CORRECT LOGGING FUNCTIONS OF QGROUNDCONTROL!
*/
quint64 UAS::getUnixTimeFromMs(quint64 time)
{
    return getUnixTime(time*1000);
}

/**
* @warning If attitudeStamped is enabled, this function will not actually return
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* the precise time stam of this measurement augmented to UNIX time, but will
* MOVE the timestamp IN TIME to match the last measured attitude. There is no
* reason why one would want this, except for system setups where the onboard
* clock is not present or broken and datasets should be collected that are
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* still roughly synchronized. PLEASE NOTE THAT ENABLING ATTITUDE STAMPED
* RUINS THE SCIENTIFIC NATURE OF THE CORRECT LOGGING FUNCTIONS OF QGROUNDCONTROL!
*/
quint64 UAS::getUnixTime(quint64 time)
{
    quint64 ret = 0;
    if (attitudeStamped)
    {
        ret = lastAttitude;
    }

    if (time == 0)
    {
        ret = QGC::groundTimeMilliseconds();
    }
    // Check if time is smaller than 40 years,
    // assuming no system without Unix timestamp
    // runs longer than 40 years continuously without
    // reboot. In worst case this will add/subtract the
    // communication delay between GCS and MAV,
    // it will never alter the timestamp in a safety
    // critical way.
    //
    // Calculation:
    // 40 years
    // 365 days
    // 24 hours
    // 60 minutes
    // 60 seconds
    // 1000 milliseconds
    // 1000 microseconds
#ifndef _MSC_VER
    else if (time < 1261440000000000LLU)
#else
    else if (time < 1261440000000000)
#endif
    {
        //        qDebug() << "GEN time:" << time/1000 + onboardTimeOffset;
        if (onboardTimeOffset == 0 || time < (lastNonNullTime - 100))
        {
            lastNonNullTime = time;
            onboardTimeOffset = QGC::groundTimeMilliseconds() - time/1000;
        }
        if (time > lastNonNullTime) lastNonNullTime = time;

        ret = time/1000 + onboardTimeOffset;
    }
    else
    {
        // Time is not zero and larger than 40 years -> has to be
        // a Unix epoch timestamp. Do nothing.
        ret = time/1000;
    }

    return ret;
}

/**
* @param component that will be searched for in the map of parameters.
*/
QList<QString> UAS::getParameterNames(int component)
{
    if (parameters.contains(component))
    {
        return parameters.value(component)->keys();
    }
    else
    {
        return QList<QString>();
    }
}

QList<int> UAS::getComponentIds()
{
    return parameters.keys();
}

/**
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* @param newBaseMode that UAS is to be set to.
* @param newCustomMode that UAS is to be set to.
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*/
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void UAS::setMode(uint8_t newBaseMode, uint32_t newCustomMode)
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{
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    if (receivedMode)
    {
        //this->mode = mode; //no call assignament, update receive message from UAS
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        // Strip armed / disarmed call for safety reasons, this is not relevant for setting the mode
        newBaseMode &= ~MAV_MODE_FLAG_SAFETY_ARMED;
        // Now set current state (request no change)
        newBaseMode |= this->base_mode & MAV_MODE_FLAG_SAFETY_ARMED;
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//        // Strip HIL part, replace it with current system state
//        newBaseMode &= (~MAV_MODE_FLAG_HIL_ENABLED);
//        // Now set current state (request no change)
//        newBaseMode |= this->base_mode & MAV_MODE_FLAG_HIL_ENABLED;
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        setModeArm(newBaseMode, newCustomMode);
    }
    else
    {
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        qDebug() << "WARNING: setMode called before base_mode bitmask was received from UAS, new mode was not sent to system";
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    }
}

/**
* @param newBaseMode that UAS is to be set to.
* @param newCustomMode that UAS is to be set to.
*/
void UAS::setModeArm(uint8_t newBaseMode, uint32_t newCustomMode)
{
    if (receivedMode)
    {
        mavlink_message_t msg;
        mavlink_msg_set_mode_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, (uint8_t)uasId, newBaseMode, newCustomMode);
        qDebug() << "mavlink_msg_set_mode_pack 1";
        sendMessage(msg);
        qDebug() << "SENDING REQUEST TO SET MODE TO SYSTEM" << uasId << ", MODE " << newBaseMode << " " << newCustomMode;
    }
    else
    {
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        qDebug() << "WARNING: setModeArm called before base_mode bitmask was received from UAS, new mode was not sent to system";
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    }
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}

/**
* Send a message to every link that is connected.
* @param message that is to be sent
*/
void UAS::sendMessage(mavlink_message_t message)
{
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    if (!LinkManager::instance())
    {
        qWarning() << "LINKMANAGER NOT AVAILABLE!";
        return;
    }

    if (links->count() < 1) {
        qDebug() << "NO LINK AVAILABLE TO SEND!";
    }

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    // Emit message on all links that are currently connected
    foreach (LinkInterface* link, *links)
    {
        if (LinkManager::instance()->getLinks().contains(link))
        {
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            if (link->isConnected())
                sendMessage(link, message);
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        }
        else
        {
            // Remove from list
            links->removeAt(links->indexOf(link));
        }
    }
}

/**
* Forward a message to all links that are currently connected.
* @param message that is to be forwarded
*/
void UAS::forwardMessage(mavlink_message_t message)
{
    // Emit message on all links that are currently connected
    QList<LinkInterface*>link_list = LinkManager::instance()->getLinksForProtocol(mavlink);

    foreach(LinkInterface* link, link_list)
    {
        if (link)
        {
            SerialLink* serial = dynamic_cast<SerialLink*>(link);
            if(serial != 0)
            {
                for(int i=0; i<links->size(); i++)
                {
                    if(serial != links->at(i))
                    {
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                        if (link->isConnected()) {
                            qDebug()<<"Antenna tracking: Forwarding Over link: "<<serial->getName()<<" "<<serial;
                            sendMessage(serial, message);
                        }
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                    }
                }
            }
        }
    }
}

/**
* Send a message to the link that is connected.
* @param link that the message will be sent to
* @message that is to be sent
*/
void UAS::sendMessage(LinkInterface* link, mavlink_message_t message)
{
    if(!link) return;
    // Create buffer
    uint8_t buffer[MAVLINK_MAX_PACKET_LEN];
    // Write message into buffer, prepending start sign
    int len = mavlink_msg_to_send_buffer(buffer, &message);
    static uint8_t messageKeys[256] = MAVLINK_MESSAGE_CRCS;
    mavlink_finalize_message_chan(&message, mavlink->getSystemId(), mavlink->getComponentId(), link->getId(), message.len, messageKeys[message.msgid]);
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    // If link is connected
    if (link->isConnected())
    {
        // Send the portion of the buffer now occupied by the message
        link->writeBytes((const char*)buffer, len);
    }
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    else
    {
        qDebug() << "LINK NOT CONNECTED, NOT SENDING!";
    }
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}

/**
 * @param value battery voltage
 */
float UAS::filterVoltage(float value) const
{
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    return lpVoltage * 0.6f + value * 0.4f;
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}

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/**
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* Get the status of the code and a description of the status.
* Status can be unitialized, booting up, calibrating sensors, active
* standby, cirtical, emergency, shutdown or unknown.
*/
void UAS::getStatusForCode(int statusCode, QString& uasState, QString& stateDescription)
{
    switch (statusCode)
    {
    case MAV_STATE_UNINIT:
        uasState = tr("UNINIT");
        stateDescription = tr("Unitialized, booting up.");
        break;
    case MAV_STATE_BOOT:
        uasState = tr("BOOT");
        stateDescription = tr("Booting system, please wait.");
        break;
    case MAV_STATE_CALIBRATING:
        uasState = tr("CALIBRATING");
        stateDescription = tr("Calibrating sensors, please wait.");
        break;
    case MAV_STATE_ACTIVE:
        uasState = tr("ACTIVE");
        stateDescription = tr("Active, normal operation.");
        break;
    case MAV_STATE_STANDBY:
        uasState = tr("STANDBY");
        stateDescription = tr("Standby mode, ready for launch.");
        break;
    case MAV_STATE_CRITICAL:
        uasState = tr("CRITICAL");
        stateDescription = tr("FAILURE: Continuing operation.");
        break;
    case MAV_STATE_EMERGENCY:
        uasState = tr("EMERGENCY");
        stateDescription = tr("EMERGENCY: Land Immediately!");
        break;
        //case MAV_STATE_HILSIM:
        //uasState = tr("HIL SIM");
        //stateDescription = tr("HIL Simulation, Sensors read from SIM");
        //break;

    case MAV_STATE_POWEROFF:
        uasState = tr("SHUTDOWN");
        stateDescription = tr("Powering off system.");
        break;

    default:
        uasState = tr("UNKNOWN");
        stateDescription = tr("Unknown system state");
        break;
    }
}

QImage UAS::getImage()
{

//    qDebug() << "IMAGE TYPE:" << imageType;

    // RAW greyscale
    if (imageType == MAVLINK_DATA_STREAM_IMG_RAW8U)
    {
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        int imgColors = 255;
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        // Construct PGM header
        QString header("P5\n%1 %2\n%3\n");
        header = header.arg(imageWidth).arg(imageHeight).arg(imgColors);

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        QByteArray tmpImage(header.toStdString().c_str(), header.toStdString().size());
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        tmpImage.append(imageRecBuffer);

        //qDebug() << "IMAGE SIZE:" << tmpImage.size() << "HEADER SIZE: (15):" << header.size() << "HEADER: " << header;

        if (imageRecBuffer.isNull())
        {
            qDebug()<< "could not convertToPGM()";
            return QImage();
        }

        if (!image.loadFromData(tmpImage, "PGM"))
        {
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            qDebug()<< __FILE__ << __LINE__ << "could not create extracted image";
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            return QImage();
        }

    }
    // BMP with header
    else if (imageType == MAVLINK_DATA_STREAM_IMG_BMP ||
             imageType == MAVLINK_DATA_STREAM_IMG_JPEG ||
             imageType == MAVLINK_DATA_STREAM_IMG_PGM ||
             imageType == MAVLINK_DATA_STREAM_IMG_PNG)
    {
        if (!image.loadFromData(imageRecBuffer))
        {
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            qDebug() << __FILE__ << __LINE__ << "Loading data from image buffer failed!";
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            return QImage();
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        }
    }
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    // Restart statemachine
    imagePacketsArrived = 0;
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    imagePackets = 0;
    imageRecBuffer.clear();
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    return image;
}

void UAS::requestImage()
{
    qDebug() << "trying to get an image from the uas...";

    // check if there is already an image transmission going on
    if (imagePacketsArrived == 0)
    {
        mavlink_message_t msg;
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        mavlink_msg_data_transmission_handshake_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, MAVLINK_DATA_STREAM_IMG_JPEG, 0, 0, 0, 0, 0, 50);
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        sendMessage(msg);
    }
}


/* MANAGEMENT */

/**
 *
 * @return The uptime in milliseconds
 *
 */
quint64 UAS::getUptime() const
{
    if(startTime == 0)
    {
        return 0;
    }
    else
    {
        return QGC::groundTimeMilliseconds() - startTime;
    }
}

int UAS::getCommunicationStatus() const
{
    return commStatus;
}

void UAS::requestParameters()
{
    mavlink_message_t msg;
    mavlink_msg_param_request_list_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, this->getUASID(), MAV_COMP_ID_ALL);
    sendMessage(msg);
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    QDateTime time = QDateTime::currentDateTime();
    qDebug() << __FILE__ << ":" << __LINE__ << time.toString() << "LOADING PARAM LIST";
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}

void UAS::writeParametersToStorage()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_PREFLIGHT_STORAGE, 1, 1, -1, -1, -1, 0, 0, 0);
    qDebug() << "SENT COMMAND" << MAV_CMD_PREFLIGHT_STORAGE;
    sendMessage(msg);
}

void UAS::readParametersFromStorage()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, 0, MAV_CMD_PREFLIGHT_STORAGE, 1, 0, -1, -1, -1, 0, 0, 0);
    sendMessage(msg);
}

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bool UAS::isRotaryWing()
{
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    switch (type) {
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        case MAV_TYPE_QUADROTOR:
        /* fallthrough */
        case MAV_TYPE_COAXIAL:
        case MAV_TYPE_HELICOPTER:
        case MAV_TYPE_HEXAROTOR:
        case MAV_TYPE_OCTOROTOR:
        case MAV_TYPE_TRICOPTER:
            return true;
        default:
            return false;
    }
}

bool UAS::isFixedWing()
{
2297
    switch (type) {
2298 2299 2300 2301 2302 2303 2304
        case MAV_TYPE_FIXED_WING:
            return true;
        default:
            return false;
    }
}

2305
/**
2306 2307 2308 2309 2310 2311 2312 2313 2314 2315 2316 2317 2318 2319 2320 2321 2322 2323 2324 2325 2326 2327 2328 2329 2330 2331 2332
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableAllDataTransmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    // 0 is a magic ID and will enable/disable the standard message set except for heartbeat
    stream.req_stream_id = MAV_DATA_STREAM_ALL;
    // Select the update rate in Hz the message should be send
    // All messages will be send with their default rate
    // TODO: use 0 to turn off and get rid of enable/disable? will require
    //  a different magic flag for turning on defaults, possibly something really high like 1111 ?
    stream.req_message_rate = 0;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
}

2333
/**
2334 2335 2336 2337 2338 2339 2340 2341 2342 2343 2344 2345 2346 2347 2348 2349 2350 2351 2352 2353 2354 2355 2356
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableRawSensorDataTransmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_RAW_SENSORS;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
}

2357
/**
2358 2359 2360 2361 2362 2363 2364 2365 2366 2367 2368 2369 2370 2371 2372 2373 2374 2375 2376 2377 2378 2379 2380
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableExtendedSystemStatusTransmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_EXTENDED_STATUS;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
}

2381
/**
2382 2383 2384 2385 2386 2387 2388 2389 2390 2391 2392 2393 2394 2395 2396 2397 2398 2399 2400 2401 2402 2403 2404 2405 2406 2407 2408 2409
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableRCChannelDataTransmission(int rate)
{
#if defined(MAVLINK_ENABLED_UALBERTA_MESSAGES)
    mavlink_message_t msg;
    mavlink_msg_request_rc_channels_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, enabled);
    sendMessage(msg);
#else
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_RC_CHANNELS;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
#endif
}

2410
/**
2411 2412 2413 2414 2415 2416 2417 2418 2419 2420 2421 2422 2423 2424 2425 2426 2427 2428 2429 2430 2431 2432 2433 2434 2435 2436 2437 2438 2439 2440 2441 2442 2443 2444 2445 2446 2447 2448 2449 2450 2451 2452 2453 2454 2455
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableRawControllerDataTransmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_RAW_CONTROLLER;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
}

//void UAS::enableRawSensorFusionTransmission(int rate)
//{
//    // Buffers to write data to
//    mavlink_message_t msg;
//    mavlink_request_data_stream_t stream;
//    // Select the message to request from now on
//    stream.req_stream_id = MAV_DATA_STREAM_RAW_SENSOR_FUSION;
//    // Select the update rate in Hz the message should be send
//    stream.req_message_rate = rate;
//    // Start / stop the message
//    stream.start_stop = (rate) ? 1 : 0;
//    // The system which should take this command
//    stream.target_system = uasId;
//    // The component / subsystem which should take this command
//    stream.target_component = 0;
//    // Encode and send the message
//    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
//    // Send message twice to increase chance of reception
//    sendMessage(msg);
//    sendMessage(msg);
//}

2456
/**
2457 2458 2459 2460 2461 2462 2463 2464 2465 2466 2467 2468 2469 2470 2471 2472 2473 2474 2475 2476 2477 2478 2479
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enablePositionTransmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_POSITION;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
}

2480
/**
2481 2482 2483 2484 2485 2486 2487 2488 2489 2490 2491 2492 2493 2494 2495 2496 2497 2498 2499 2500 2501 2502 2503 2504
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableExtra1Transmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_EXTRA1;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
    sendMessage(msg);
}

2505
/**
2506 2507 2508 2509 2510 2511 2512 2513 2514 2515 2516 2517 2518 2519 2520 2521 2522 2523 2524 2525 2526 2527 2528 2529
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableExtra2Transmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_EXTRA2;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
    sendMessage(msg);
}

2530
/**
2531 2532 2533 2534 2535 2536 2537 2538 2539 2540 2541 2542 2543 2544 2545 2546 2547 2548 2549 2550 2551 2552 2553 2554 2555 2556 2557 2558
* @param rate The update rate in Hz the message should be sent
*/
void UAS::enableExtra3Transmission(int rate)
{
    // Buffers to write data to
    mavlink_message_t msg;
    mavlink_request_data_stream_t stream;
    // Select the message to request from now on
    stream.req_stream_id = MAV_DATA_STREAM_EXTRA3;
    // Select the update rate in Hz the message should be send
    stream.req_message_rate = rate;
    // Start / stop the message
    stream.start_stop = (rate) ? 1 : 0;
    // The system which should take this command
    stream.target_system = uasId;
    // The component / subsystem which should take this command
    stream.target_component = 0;
    // Encode and send the message
    mavlink_msg_request_data_stream_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &stream);
    // Send message twice to increase chance of reception
    sendMessage(msg);
    sendMessage(msg);
}

/**
 * Set a parameter value onboard
 *
 * @param component The component to set the parameter
2559
 * @param id Name of the parameter
2560
 */
2561
void UAS::setParameter(const int compId, const QString& paramId, const QVariant& value)
2562
{
2563
    if (!paramId.isNull())
2564 2565 2566 2567 2568 2569
    {
        mavlink_message_t msg;
        mavlink_param_set_t p;
        mavlink_param_union_t union_value;

        // Assign correct value based on QVariant
2570
        // TODO: This is a hack for MAV_AUTOPILOT_ARDUPILOTMEGA until the new version of MAVLink and a fix for their param handling.
2571
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA)
2572
        {
2573
            switch ((int)value.type())
2574 2575
            {
            case QVariant::Char:
2576
                union_value.param_float = (unsigned char)value.toChar().toLatin1();
2577 2578 2579 2580 2581 2582 2583 2584 2585 2586 2587 2588 2589 2590 2591 2592 2593 2594 2595 2596 2597
                p.param_type = MAV_PARAM_TYPE_INT8;
                break;
            case QVariant::Int:
                union_value.param_float = value.toInt();
                p.param_type = MAV_PARAM_TYPE_INT32;
                break;
            case QVariant::UInt:
                union_value.param_float = value.toUInt();
                p.param_type = MAV_PARAM_TYPE_UINT32;
                break;
            case QMetaType::Float:
                union_value.param_float = value.toFloat();
                p.param_type = MAV_PARAM_TYPE_REAL32;
                break;
            default:
                qCritical() << "ABORTED PARAM SEND, NO VALID QVARIANT TYPE";
                return;
            }
        }
        else
        {
2598
            switch ((int)value.type())
2599 2600
            {
            case QVariant::Char:
2601
                union_value.param_int8 = (unsigned char)value.toChar().toLatin1();
2602 2603 2604 2605 2606 2607 2608 2609 2610 2611 2612 2613 2614 2615 2616 2617 2618 2619
                p.param_type = MAV_PARAM_TYPE_INT8;
                break;
            case QVariant::Int:
                union_value.param_int32 = value.toInt();
                p.param_type = MAV_PARAM_TYPE_INT32;
                break;
            case QVariant::UInt:
                union_value.param_uint32 = value.toUInt();
                p.param_type = MAV_PARAM_TYPE_UINT32;
                break;
            case QMetaType::Float:
                union_value.param_float = value.toFloat();
                p.param_type = MAV_PARAM_TYPE_REAL32;
                break;
            default:
                qCritical() << "ABORTED PARAM SEND, NO VALID QVARIANT TYPE";
                return;
            }
2620 2621 2622 2623
        }

        p.param_value = union_value.param_float;
        p.target_system = (uint8_t)uasId;
2624
        p.target_component = (uint8_t)compId;
2625 2626 2627 2628 2629 2630 2631

        //qDebug() << "SENT PARAM:" << value;

        // Copy string into buffer, ensuring not to exceed the buffer size
        for (unsigned int i = 0; i < sizeof(p.param_id); i++)
        {
            // String characters
2632
            if ((int)i < paramId.length())
2633
            {
2634
                p.param_id[i] = paramId.toLatin1()[i];
2635 2636 2637 2638 2639 2640 2641
            }
            else
            {
                // Fill rest with zeros
                p.param_id[i] = 0;
            }
        }
2642
        mavlink_msg_param_set_encode(mavlink->getSystemId(), compId, &msg, &p);
2643 2644 2645 2646
        sendMessage(msg);
    }
}

2647 2648 2649 2650 2651 2652 2653 2654 2655 2656 2657 2658 2659



//TODO update this to use the parameter manager / param data model instead
void UAS::processParamValueMsg(mavlink_message_t& msg, const QString& paramName, const mavlink_param_value_t& rawValue,  mavlink_param_union_t& paramValue)
{
    int compId = msg.compid;

    // Insert component if necessary
    if (!parameters.contains(compId)) {
        parameters.insert(compId, new QMap<QString, QVariant>());
    }

2660 2661 2662 2663
    // Insert parameter into registry
    if (parameters.value(compId)->contains(paramName)) {
        parameters.value(compId)->remove(paramName);
    }
2664 2665 2666 2667 2668

    QVariant param;

    // Insert with correct type
    // TODO: This is a hack for MAV_AUTOPILOT_ARDUPILOTMEGA until the new version of MAVLink and a fix for their param handling.
2669 2670 2671 2672 2673 2674 2675 2676 2677 2678 2679 2680 2681 2682 2683 2684 2685 2686 2687 2688 2689 2690 2691
    switch (rawValue.param_type)
    {
    case MAV_PARAM_TYPE_REAL32:
    {
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA) {
            param = QVariant(paramValue.param_float);
        }
        else {
            param = QVariant(paramValue.param_float);
        }
        parameters.value(compId)->insert(paramName, param);
        // Emit change
        emit parameterChanged(uasId, compId, paramName, param);
        emit parameterChanged(uasId, compId, rawValue.param_count, rawValue.param_index, paramName, param);
//                qDebug() << "RECEIVED PARAM:" << param;
    }
        break;
    case MAV_PARAM_TYPE_UINT8:
    {
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA) {
            param = QVariant(QChar((unsigned char)paramValue.param_float));
        }
        else {
2692
            param = QVariant(QChar((unsigned char)paramValue.param_uint8));
2693 2694 2695 2696 2697 2698 2699 2700 2701 2702 2703 2704 2705 2706
        }
        parameters.value(compId)->insert(paramName, param);
        // Emit change
        emit parameterChanged(uasId, compId, paramName, param);
        emit parameterChanged(uasId, compId, rawValue.param_count, rawValue.param_index, paramName, param);
        //qDebug() << "RECEIVED PARAM:" << param;
    }
        break;
    case MAV_PARAM_TYPE_INT8:
    {
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA) {
            param = QVariant(QChar((char)paramValue.param_float));
        }
        else  {
2707
            param = QVariant(QChar((char)paramValue.param_int8));
2708 2709 2710 2711 2712 2713 2714 2715 2716 2717 2718 2719 2720 2721
        }
        parameters.value(compId)->insert(paramName, param);
        // Emit change
        emit parameterChanged(uasId, compId, paramName, param);
        emit parameterChanged(uasId, compId, rawValue.param_count, rawValue.param_index, paramName, param);
        //qDebug() << "RECEIVED PARAM:" << param;
    }
        break;
    case MAV_PARAM_TYPE_INT16:
    {
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA) {
            param = QVariant((short)paramValue.param_float);
        }
        else {
2722
            param = QVariant(paramValue.param_int16);
2723 2724 2725 2726 2727 2728 2729 2730 2731 2732 2733 2734 2735 2736
        }
        parameters.value(compId)->insert(paramName, param);
        // Emit change
        emit parameterChanged(uasId, compId, paramName, param);
        emit parameterChanged(uasId, compId, rawValue.param_count, rawValue.param_index, paramName, param);
        //qDebug() << "RECEIVED PARAM:" << param;
    }
        break;
    case MAV_PARAM_TYPE_UINT32:
    {
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA) {
            param = QVariant((unsigned int)paramValue.param_float);
        }
        else {
2737
            param = QVariant(paramValue.param_uint32);
2738 2739 2740 2741 2742 2743 2744 2745 2746 2747 2748 2749 2750
        }
        parameters.value(compId)->insert(paramName, param);
        // Emit change
        emit parameterChanged(uasId, compId, paramName, param);
        emit parameterChanged(uasId, compId, rawValue.param_count, rawValue.param_index, paramName, param);
    }
        break;
    case MAV_PARAM_TYPE_INT32:
    {
        if (getAutopilotType() == MAV_AUTOPILOT_ARDUPILOTMEGA) {
            param = QVariant((int)paramValue.param_float);
        }
        else {
2751
            param = QVariant(paramValue.param_int32);
2752 2753 2754 2755 2756 2757 2758 2759 2760 2761
        }
        parameters.value(compId)->insert(paramName, param);
        // Emit change
        emit parameterChanged(uasId, compId, paramName, param);
        emit parameterChanged(uasId, compId, rawValue.param_count, rawValue.param_index, paramName, param);
//                qDebug() << "RECEIVED PARAM:" << param;
    }
        break;
    default:
        qCritical() << "INVALID DATA TYPE USED AS PARAMETER VALUE: " << rawValue.param_type;
2762 2763 2764 2765
    } //switch (value.param_type)

}

2766
/**
2767 2768 2769 2770 2771 2772 2773 2774 2775 2776 2777 2778 2779 2780 2781 2782 2783 2784 2785 2786 2787 2788 2789 2790 2791 2792 2793 2794
* Request parameter, use parameter name to request it.
*/
void UAS::requestParameter(int component, int id)
{
    // Request parameter, use parameter name to request it
    mavlink_message_t msg;
    mavlink_param_request_read_t read;
    read.param_index = id;
    read.param_id[0] = '\0'; // Enforce null termination
    read.target_system = uasId;
    read.target_component = component;
    mavlink_msg_param_request_read_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &read);
    sendMessage(msg);
    //qDebug() << __FILE__ << __LINE__ << "REQUESTING PARAM RETRANSMISSION FROM COMPONENT" << component << "FOR PARAM ID" << id;
}

/**
* Request a parameter, use parameter name to request it.
*/
void UAS::requestParameter(int component, const QString& parameter)
{
    // Request parameter, use parameter name to request it
    mavlink_message_t msg;
    mavlink_param_request_read_t read;
    read.param_index = -1;
    // Copy full param name or maximum max field size
    if (parameter.length() > MAVLINK_MSG_PARAM_REQUEST_READ_FIELD_PARAM_ID_LEN)
    {
2795
        emit textMessageReceived(uasId, 0, MAV_SEVERITY_WARNING, QString("QGC WARNING: Parameter name %1 is more than %2 bytes long. This might lead to errors and mishaps!").arg(parameter).arg(MAVLINK_MSG_PARAM_REQUEST_READ_FIELD_PARAM_ID_LEN-1));
2796 2797 2798 2799 2800 2801 2802
    }
    memcpy(read.param_id, parameter.toStdString().c_str(), qMax(parameter.length(), MAVLINK_MSG_PARAM_REQUEST_READ_FIELD_PARAM_ID_LEN));
    read.param_id[15] = '\0'; // Enforce null termination
    read.target_system = uasId;
    read.target_component = component;
    mavlink_msg_param_request_read_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &read);
    sendMessage(msg);
2803
    //qDebug() << __FILE__ << __LINE__ << "REQUESTING PARAM RETRANSMISSION FROM COMPONENT" << component << "FOR PARAM NAME" << parameter;
2804 2805 2806 2807 2808 2809 2810 2811 2812 2813
}

/**
* @param systemType Type of MAV.
*/
void UAS::setSystemType(int systemType)
{
    if((systemType >= MAV_TYPE_GENERIC) && (systemType < MAV_TYPE_ENUM_END))
    {
      type = systemType;
2814

2815 2816 2817 2818 2819 2820 2821 2822 2823 2824 2825 2826 2827 2828 2829 2830 2831 2832 2833 2834 2835 2836 2837 2838 2839 2840 2841 2842 2843 2844 2845 2846 2847 2848 2849 2850 2851 2852 2853 2854 2855 2856 2857 2858 2859 2860
      // If the airframe is still generic, change it to a close default type
      if (airframe == 0)
      {
          switch (systemType)
          {
          case MAV_TYPE_FIXED_WING:
              airframe = QGC_AIRFRAME_EASYSTAR;
              break;
          case MAV_TYPE_QUADROTOR:
              airframe = QGC_AIRFRAME_MIKROKOPTER;
              break;
          }
      }
      emit systemSpecsChanged(uasId);
   }
}

void UAS::setUASName(const QString& name)
{
    if (name != "")
    {
        this->name = name;
        writeSettings();
        emit nameChanged(name);
        emit systemSpecsChanged(uasId);
    }
}

void UAS::executeCommand(MAV_CMD command)
{
    mavlink_message_t msg;
    mavlink_command_long_t cmd;
    cmd.command = (uint16_t)command;
    cmd.confirmation = 0;
    cmd.param1 = 0.0f;
    cmd.param2 = 0.0f;
    cmd.param3 = 0.0f;
    cmd.param4 = 0.0f;
    cmd.param5 = 0.0f;
    cmd.param6 = 0.0f;
    cmd.param7 = 0.0f;
    cmd.target_system = uasId;
    cmd.target_component = 0;
    mavlink_msg_command_long_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &cmd);
    sendMessage(msg);
}
2861 2862 2863 2864 2865 2866 2867 2868 2869
void UAS::executeCommandAck(int num, bool success)
{
    mavlink_message_t msg;
    mavlink_command_ack_t ack;
    ack.command = num;
    ack.result = (success ? 1 : 0);
    mavlink_msg_command_ack_encode(mavlink->getSystemId(),mavlink->getComponentId(),&msg,&ack);
    sendMessage(msg);
}
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void UAS::executeCommand(MAV_CMD command, int confirmation, float param1, float param2, float param3, float param4, float param5, float param6, float param7, int component)
{
    mavlink_message_t msg;
    mavlink_command_long_t cmd;
    cmd.command = (uint16_t)command;
    cmd.confirmation = confirmation;
    cmd.param1 = param1;
    cmd.param2 = param2;
    cmd.param3 = param3;
    cmd.param4 = param4;
    cmd.param5 = param5;
    cmd.param6 = param6;
    cmd.param7 = param7;
    cmd.target_system = uasId;
    cmd.target_component = component;
    mavlink_msg_command_long_encode(mavlink->getSystemId(), mavlink->getComponentId(), &msg, &cmd);
    sendMessage(msg);
}

/**
 * Launches the system
 *
 */
void UAS::launch()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, this->getUASID(), 0, MAV_CMD_NAV_TAKEOFF, 1, 0, 0, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

/**
 * @warning Depending on the UAS, this might make the rotors of a helicopter spinning
 *
 */
void UAS::armSystem()
{
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    setModeArm(base_mode | MAV_MODE_FLAG_SAFETY_ARMED, custom_mode);
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}

/**
 * @warning Depending on the UAS, this might completely stop all motors.
 *
 */
void UAS::disarmSystem()
{
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    setModeArm(base_mode & ~(MAV_MODE_FLAG_SAFETY_ARMED), custom_mode);
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}

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void UAS::toggleArmedState()
{
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    setModeArm(base_mode ^ (MAV_MODE_FLAG_SAFETY_ARMED), custom_mode);
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}

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void UAS::goAutonomous()
{
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    setMode((base_mode & ~(MAV_MODE_FLAG_MANUAL_INPUT_ENABLED)) | (MAV_MODE_FLAG_AUTO_ENABLED | MAV_MODE_FLAG_STABILIZE_ENABLED | MAV_MODE_FLAG_GUIDED_ENABLED), 0);
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    qDebug() << __FILE__ << __LINE__ << "Going autonomous";
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}

void UAS::goManual()
{
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    setMode((base_mode & ~(MAV_MODE_FLAG_AUTO_ENABLED | MAV_MODE_FLAG_STABILIZE_ENABLED | MAV_MODE_FLAG_GUIDED_ENABLED))  | MAV_MODE_FLAG_MANUAL_INPUT_ENABLED, 0);
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    qDebug() << __FILE__ << __LINE__ << "Going manual";
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}

void UAS::toggleAutonomy()
{
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    setMode(base_mode ^ MAV_MODE_FLAG_AUTO_ENABLED ^ MAV_MODE_FLAG_MANUAL_INPUT_ENABLED ^ MAV_MODE_FLAG_GUIDED_ENABLED ^ MAV_MODE_FLAG_STABILIZE_ENABLED, 0);
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    qDebug() << __FILE__ << __LINE__ << "Toggling autonomy";
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}

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/**
* Set the manual control commands.
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* This can only be done if the system has manual inputs enabled and is armed.
*/
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void UAS::setManualControlCommands(float roll, float pitch, float yaw, float thrust, qint8 xHat, qint8 yHat, quint16 buttons)
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{
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    Q_UNUSED(xHat);
    Q_UNUSED(yHat);

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    // Store the previous manual commands
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    static float manualRollAngle = 0.0;
    static float manualPitchAngle = 0.0;
    static float manualYawAngle = 0.0;
    static float manualThrust = 0.0;
    static quint16 manualButtons = 0;
    static quint8 countSinceLastTransmission = 0; // Track how many calls to this function have occurred since the last MAVLink transmission
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    // We only transmit manual command messages if the system has manual inputs enabled and is armed
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    if(((base_mode & MAV_MODE_FLAG_DECODE_POSITION_MANUAL) && (base_mode & MAV_MODE_FLAG_DECODE_POSITION_SAFETY)) || (base_mode & MAV_MODE_FLAG_HIL_ENABLED))
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    {

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        // Transmit the manual commands only if they've changed OR if it's been a little bit since they were last transmit. To make sure there aren't issues with
        // response rate, we make sure that a message is transmit when the commands have changed, then one more time, and then switch to the lower transmission rate
        // if no command inputs have changed.
        // The default transmission rate is 50Hz, but when no inputs have changed it drops down to 5Hz.
        bool sendCommand = false;
        if (countSinceLastTransmission++ >= 10)
        {
            sendCommand = true;
            countSinceLastTransmission = 0;
        }
        else if ((!isnan(roll) && roll != manualRollAngle) || (!isnan(pitch) && pitch != manualPitchAngle) ||
                   (!isnan(yaw) && yaw != manualYawAngle) || (!isnan(thrust) && thrust != manualThrust) ||
                   buttons != manualButtons)
        {
            sendCommand = true;

            // Ensure that another message will be sent the next time this function is called
            countSinceLastTransmission = 10;
        }

        // Now if we should trigger an update, let's do that
        if (sendCommand)
        {
            // Save the new manual control inputs
            manualRollAngle = roll;
            manualPitchAngle = pitch;
            manualYawAngle = yaw;
            manualThrust = thrust;
            manualButtons = buttons;

            // Store scaling values for all 3 axes
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            const float axesScaling = 1.0 * 1000.0;
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            // Calculate the new commands for roll, pitch, yaw, and thrust
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            const float newRollCommand = roll * axesScaling;
            const float newPitchCommand = pitch * axesScaling;
            const float newYawCommand = yaw * axesScaling;
            const float newThrustCommand = thrust * axesScaling;
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            // Send the MANUAL_COMMAND message
            mavlink_message_t message;
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            mavlink_msg_manual_control_pack(mavlink->getSystemId(), mavlink->getComponentId(), &message, this->uasId, newPitchCommand, newRollCommand, newThrustCommand, newYawCommand, buttons);
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            sendMessage(message);

            // Emit an update in control values to other UI elements, like the HSI display
            emit attitudeThrustSetPointChanged(this, roll, pitch, yaw, thrust, QGC::groundTimeMilliseconds());
        }
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    }
}

void UAS::setManual6DOFControlCommands(double x, double y, double z, double roll, double pitch, double yaw)
{
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    // If system has manual inputs enabled and is armed
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    if(((base_mode & MAV_MODE_FLAG_DECODE_POSITION_MANUAL) && (base_mode & MAV_MODE_FLAG_DECODE_POSITION_SAFETY)) || (base_mode & MAV_MODE_FLAG_HIL_ENABLED))
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    {
        mavlink_message_t message;
        mavlink_msg_setpoint_6dof_pack(mavlink->getSystemId(), mavlink->getComponentId(), &message, this->uasId, (float)x, (float)y, (float)z, (float)roll, (float)pitch, (float)yaw);
        sendMessage(message);
        qDebug() << __FILE__ << __LINE__ << ": SENT 6DOF CONTROL MESSAGE: x" << x << " y: " << y << " z: " << z << " roll: " << roll << " pitch: " << pitch << " yaw: " << yaw;

        //emit attitudeThrustSetPointChanged(this, roll, pitch, yaw, thrust, QGC::groundTimeMilliseconds());
    }
    else
    {
        qDebug() << "3DMOUSE/MANUAL CONTROL: IGNORING COMMANDS: Set mode to MANUAL to send 3DMouse commands first";
    }
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}

/**
* @return the type of the system
*/
int UAS::getSystemType()
{
    return this->type;
}

/**
* Halt the uas.
*/
void UAS::halt()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_OVERRIDE_GOTO, 1, MAV_GOTO_DO_HOLD, MAV_GOTO_HOLD_AT_CURRENT_POSITION, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

/**
* Make the UAS move.
*/
void UAS::go()
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_OVERRIDE_GOTO, 1, MAV_GOTO_DO_CONTINUE, MAV_GOTO_HOLD_AT_CURRENT_POSITION, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

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/**
* Order the robot to return home
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*/
void UAS::home()
{
    mavlink_message_t msg;

    double latitude = UASManager::instance()->getHomeLatitude();
    double longitude = UASManager::instance()->getHomeLongitude();
    double altitude = UASManager::instance()->getHomeAltitude();
    int frame = UASManager::instance()->getHomeFrame();

    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_OVERRIDE_GOTO, 1, MAV_GOTO_DO_CONTINUE, MAV_GOTO_HOLD_AT_CURRENT_POSITION, frame, 0, latitude, longitude, altitude);
    sendMessage(msg);
}

/**
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* Order the robot to land on the runway
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*/
void UAS::land()
{
    mavlink_message_t msg;

    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_NAV_LAND, 1, 0, 0, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

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/**
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* Order the robot to start receiver pairing
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*/
void UAS::pairRX(int rxType, int rxSubType)
{
    mavlink_message_t msg;

    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_START_RX_PAIR, 0, rxType, rxSubType, 0, 0, 0, 0, 0);
    sendMessage(msg);
}

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/**
 * The MAV starts the emergency landing procedure. The behaviour depends on the onboard implementation
 * and might differ between systems.
 */
void UAS::emergencySTOP()
{
    // FIXME MAVLINKV10PORTINGNEEDED
    halt();
}

/**
 * Shut down this mav - All onboard systems are immediately shut down (e.g. the
 *  main power line is cut).
 * @warning This might lead to a crash.
 *
 * The command will not be executed until emergencyKILLConfirm is issues immediately afterwards
 */
bool UAS::emergencyKILL()
{
    halt();
    // FIXME MAVLINKV10PORTINGNEEDED
    //    bool result = false;
    //    QMessageBox msgBox;
    //    msgBox.setIcon(QMessageBox::Critical);
    //    msgBox.setText("EMERGENCY: KILL ALL MOTORS ON UAS");
    //    msgBox.setInformativeText("Do you want to cut power on all systems?");
    //    msgBox.setStandardButtons(QMessageBox::Yes | QMessageBox::Cancel);
    //    msgBox.setDefaultButton(QMessageBox::Cancel);
    //    int ret = msgBox.exec();

    //    // Close the message box shortly after the click to prevent accidental clicks
    //    QTimer::singleShot(5000, &msgBox, SLOT(reject()));


    //    if (ret == QMessageBox::Yes)
    //    {
    //        mavlink_message_t msg;
    //        // TODO Replace MG System ID with static function call and allow to change ID in GUI
    //        mavlink_msg_action_pack(MG::SYSTEM::ID, MG::SYSTEM::COMPID, &msg, this->getUASID(), MAV_COMP_ID_IMU, (int)MAV_ACTION_EMCY_KILL);
    //        // Send message twice to increase chance of reception
    //        sendMessage(msg);
    //        sendMessage(msg);
    //        result = true;
    //    }
    //    return result;
    return false;
}

/**
* If enabled, connect the flight gear link.
*/
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void UAS::enableHilFlightGear(bool enable, QString options, bool sensorHil, QObject * configuration)
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{
    QGCFlightGearLink* link = dynamic_cast<QGCFlightGearLink*>(simulation);
    if (!link || !simulation) {
        // Delete wrong sim
        if (simulation) {
            stopHil();
            delete simulation;
        }
        simulation = new QGCFlightGearLink(this, options);
    }
    // Connect Flight Gear Link
    link = dynamic_cast<QGCFlightGearLink*>(simulation);
    link->setStartupArguments(options);
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    link->sensorHilEnabled(sensorHil);
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    QObject::connect(configuration, SIGNAL(barometerOffsetChanged(float)), link, SLOT(setBarometerOffset(float)));
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    if (enable)
    {
        startHil();
    }
    else
    {
        stopHil();
    }
}

/**
* If enabled, connect the JSBSim link.
*/
void UAS::enableHilJSBSim(bool enable, QString options)
{
    QGCJSBSimLink* link = dynamic_cast<QGCJSBSimLink*>(simulation);
    if (!link || !simulation) {
        // Delete wrong sim
        if (simulation) {
            stopHil();
            delete simulation;
        }
        simulation = new QGCJSBSimLink(this, options);
    }
    // Connect Flight Gear Link
    link = dynamic_cast<QGCJSBSimLink*>(simulation);
    link->setStartupArguments(options);
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    if (enable)
    {
        startHil();
    }
    else
    {
        stopHil();
    }
}

/**
* If enabled, connect the X-plane gear link.
*/
void UAS::enableHilXPlane(bool enable)
{
    QGCXPlaneLink* link = dynamic_cast<QGCXPlaneLink*>(simulation);
    if (!link || !simulation) {
        if (simulation) {
            stopHil();
            delete simulation;
        }
        qDebug() << "CREATED NEW XPLANE LINK";
        simulation = new QGCXPlaneLink(this);
    }
    // Connect X-Plane Link
    if (enable)
    {
        startHil();
    }
    else
    {
        stopHil();
    }
}

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/**
* @param time_us Timestamp (microseconds since UNIX epoch or microseconds since system boot)
* @param roll Roll angle (rad)
* @param pitch Pitch angle (rad)
* @param yaw Yaw angle (rad)
* @param rollspeed Roll angular speed (rad/s)
* @param pitchspeed Pitch angular speed (rad/s)
* @param yawspeed Yaw angular speed (rad/s)
* @param lat Latitude, expressed as * 1E7
* @param lon Longitude, expressed as * 1E7
* @param alt Altitude in meters, expressed as * 1000 (millimeters)
* @param vx Ground X Speed (Latitude), expressed as m/s * 100
* @param vy Ground Y Speed (Longitude), expressed as m/s * 100
* @param vz Ground Z Speed (Altitude), expressed as m/s * 100
* @param xacc X acceleration (mg)
* @param yacc Y acceleration (mg)
* @param zacc Z acceleration (mg)
*/
void UAS::sendHilGroundTruth(quint64 time_us, float roll, float pitch, float yaw, float rollspeed,
                       float pitchspeed, float yawspeed, double lat, double lon, double alt,
                       float vx, float vy, float vz, float ind_airspeed, float true_airspeed, float xacc, float yacc, float zacc)
{
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    Q_UNUSED(time_us);
    Q_UNUSED(xacc);
    Q_UNUSED(yacc);
    Q_UNUSED(zacc);
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        // Emit attitude for cross-check
        emit valueChanged(uasId, "roll sim", "rad", roll, getUnixTime());
        emit valueChanged(uasId, "pitch sim", "rad", pitch, getUnixTime());
        emit valueChanged(uasId, "yaw sim", "rad", yaw, getUnixTime());

        emit valueChanged(uasId, "roll rate sim", "rad/s", rollspeed, getUnixTime());
        emit valueChanged(uasId, "pitch rate sim", "rad/s", pitchspeed, getUnixTime());
        emit valueChanged(uasId, "yaw rate sim", "rad/s", yawspeed, getUnixTime());

        emit valueChanged(uasId, "lat sim", "deg", lat*1e7, getUnixTime());
        emit valueChanged(uasId, "lon sim", "deg", lon*1e7, getUnixTime());
        emit valueChanged(uasId, "alt sim", "deg", alt*1e3, getUnixTime());

        emit valueChanged(uasId, "vx sim", "m/s", vx*1e2, getUnixTime());
        emit valueChanged(uasId, "vy sim", "m/s", vy*1e2, getUnixTime());
        emit valueChanged(uasId, "vz sim", "m/s", vz*1e2, getUnixTime());

        emit valueChanged(uasId, "IAS sim", "m/s", ind_airspeed, getUnixTime());
        emit valueChanged(uasId, "TAS sim", "m/s", true_airspeed, getUnixTime());
}

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/**
* @param time_us Timestamp (microseconds since UNIX epoch or microseconds since system boot)
* @param roll Roll angle (rad)
* @param pitch Pitch angle (rad)
* @param yaw Yaw angle (rad)
* @param rollspeed Roll angular speed (rad/s)
* @param pitchspeed Pitch angular speed (rad/s)
* @param yawspeed Yaw angular speed (rad/s)
* @param lat Latitude, expressed as * 1E7
* @param lon Longitude, expressed as * 1E7
* @param alt Altitude in meters, expressed as * 1000 (millimeters)
* @param vx Ground X Speed (Latitude), expressed as m/s * 100
* @param vy Ground Y Speed (Longitude), expressed as m/s * 100
* @param vz Ground Z Speed (Altitude), expressed as m/s * 100
* @param xacc X acceleration (mg)
* @param yacc Y acceleration (mg)
* @param zacc Z acceleration (mg)
*/
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void UAS::sendHilState(quint64 time_us, float roll, float pitch, float yaw, float rollspeed,
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                       float pitchspeed, float yawspeed, double lat, double lon, double alt,
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                       float vx, float vy, float vz, float ind_airspeed, float true_airspeed, float xacc, float yacc, float zacc)
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{
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    if (this->base_mode & MAV_MODE_FLAG_HIL_ENABLED)
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    {
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        float q[4];

        double cosPhi_2 = cos(double(roll) / 2.0);
        double sinPhi_2 = sin(double(roll) / 2.0);
        double cosTheta_2 = cos(double(pitch) / 2.0);
        double sinTheta_2 = sin(double(pitch) / 2.0);
        double cosPsi_2 = cos(double(yaw) / 2.0);
        double sinPsi_2 = sin(double(yaw) / 2.0);
        q[0] = (cosPhi_2 * cosTheta_2 * cosPsi_2 +
                sinPhi_2 * sinTheta_2 * sinPsi_2);
        q[1] = (sinPhi_2 * cosTheta_2 * cosPsi_2 -
                cosPhi_2 * sinTheta_2 * sinPsi_2);
        q[2] = (cosPhi_2 * sinTheta_2 * cosPsi_2 +
                sinPhi_2 * cosTheta_2 * sinPsi_2);
        q[3] = (cosPhi_2 * cosTheta_2 * sinPsi_2 -
                sinPhi_2 * sinTheta_2 * cosPsi_2);

        mavlink_message_t msg;
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        mavlink_msg_hil_state_quaternion_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg,
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                                   time_us, q, rollspeed, pitchspeed, yawspeed,
                                   lat*1e7f, lon*1e7f, alt*1000, vx*100, vy*100, vz*100, ind_airspeed*100, true_airspeed*100, xacc*1000/9.81, yacc*1000/9.81, zacc*1000/9.81);
        sendMessage(msg);
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    }
    else
    {
        // Attempt to set HIL mode
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        setMode(base_mode | MAV_MODE_FLAG_HIL_ENABLED, custom_mode);
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        qDebug() << __FILE__ << __LINE__ << "HIL is onboard not enabled, trying to enable.";
    }
}

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/*
* @param abs_pressure Absolute Pressure (hPa)
* @param diff_pressure Differential Pressure  (hPa)
*/
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void UAS::sendHilSensors(quint64 time_us, float xacc, float yacc, float zacc, float rollspeed, float pitchspeed, float yawspeed,
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                                    float xmag, float ymag, float zmag, float abs_pressure, float diff_pressure, float pressure_alt, float temperature, quint32 fields_changed)
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{
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    if (this->base_mode & MAV_MODE_FLAG_HIL_ENABLED)
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    {
        mavlink_message_t msg;
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        mavlink_msg_hil_sensor_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg,
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                                   time_us, xacc, yacc, zacc, rollspeed, pitchspeed, yawspeed,
                                     xmag, ymag, zmag, abs_pressure, diff_pressure, pressure_alt, temperature,
                                     fields_changed);
        sendMessage(msg);
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        lastSendTimeSensors = QGC::groundTimeMilliseconds();
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    }
    else
    {
        // Attempt to set HIL mode
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        setMode(base_mode | MAV_MODE_FLAG_HIL_ENABLED, custom_mode);
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        qDebug() << __FILE__ << __LINE__ << "HIL is onboard not enabled, trying to enable.";
    }
}

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void UAS::sendHilGps(quint64 time_us, double lat, double lon, double alt, int fix_type, float eph, float epv, float vel, float vn, float ve, float vd, float cog, int satellites)
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{
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    // Only send at 10 Hz max rate
    if (QGC::groundTimeMilliseconds() - lastSendTimeGPS < 100)
        return;

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    if (this->base_mode & MAV_MODE_FLAG_HIL_ENABLED)
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    {
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        float course = cog;
        // map to 0..2pi
        if (course < 0)
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            course += 2.0f * static_cast<float>(M_PI);
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        // scale from radians to degrees
        course = (course / M_PI) * 180.0f;

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        mavlink_message_t msg;
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        mavlink_msg_hil_gps_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg,
                                   time_us, fix_type, lat*1e7, lon*1e7, alt*1e3, eph*1e2, epv*1e2, vel*1e2, vn*1e2, ve*1e2, vd*1e2, course*1e2, satellites);
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        lastSendTimeGPS = QGC::groundTimeMilliseconds();
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        sendMessage(msg);
    }
    else
    {
        // Attempt to set HIL mode
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        setMode(base_mode | MAV_MODE_FLAG_HIL_ENABLED, custom_mode);
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        qDebug() << __FILE__ << __LINE__ << "HIL is onboard not enabled, trying to enable.";
    }
}


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/**
* Connect flight gear link.
**/
void UAS::startHil()
{
    if (hilEnabled) return;
    hilEnabled = true;
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    sensorHil = false;
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    setMode(base_mode | MAV_MODE_FLAG_HIL_ENABLED, custom_mode);
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    qDebug() << __FILE__ << __LINE__ << "HIL is onboard not enabled, trying to enable.";
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    // Connect HIL simulation link
    simulation->connectSimulation();
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}

/**
* disable flight gear link.
*/
void UAS::stopHil()
{
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    if (simulation && simulation->isConnected()) {
        simulation->disconnectSimulation();
        setMode(base_mode & ~MAV_MODE_FLAG_HIL_ENABLED, custom_mode);
        qDebug() << __FILE__ << __LINE__ << "HIL is onboard not enabled, trying to disable.";
    }
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    hilEnabled = false;
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    sensorHil = false;
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}

void UAS::shutdown()
{
    QMessageBox msgBox;
    msgBox.setIcon(QMessageBox::Critical);
    msgBox.setText("Shutting down the UAS");
    msgBox.setInformativeText("Do you want to shut down the onboard computer?");

    msgBox.setStandardButtons(QMessageBox::Yes | QMessageBox::Cancel);
    msgBox.setDefaultButton(QMessageBox::Cancel);
    int ret = msgBox.exec();

    // Close the message box shortly after the click to prevent accidental clicks
    QTimer::singleShot(5000, &msgBox, SLOT(reject()));

    if (ret == QMessageBox::Yes)
    {
        // If the active UAS is set, execute command
        mavlink_message_t msg;
        mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_PREFLIGHT_REBOOT_SHUTDOWN, 1, 0, 2, 0, 0, 0, 0, 0);
        sendMessage(msg);
    }
}

/**
* @param x position
* @param y position
* @param z position
* @param yaw
*/
void UAS::setTargetPosition(float x, float y, float z, float yaw)
{
    mavlink_message_t msg;
    mavlink_msg_command_long_pack(mavlink->getSystemId(), mavlink->getComponentId(), &msg, uasId, MAV_COMP_ID_ALL, MAV_CMD_NAV_PATHPLANNING, 1, 1, 1, 0, yaw, x, y, z);
    sendMessage(msg);
}

/**
 * @return The name of this system as string in human-readable form
 */
QString UAS::getUASName(void) const
{
    QString result;
    if (name == "")
    {
        result = tr("MAV ") + result.sprintf("%03d", getUASID());
    }
    else
    {
        result = name;
    }
    return result;
}

/**
* @return the state of the uas as a short text.
*/
const QString& UAS::getShortState() const
{
    return shortStateText;
}

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/**
* The mode can be autonomous, guided, manual or armed. It will also return if
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* hardware in the loop is being used.
* @return the audio mode text for the id given.
*/
QString UAS::getAudioModeTextFor(int id)
{
    QString mode;
    uint8_t modeid = id;

    // BASE MODE DECODING
    if (modeid & (uint8_t)MAV_MODE_FLAG_DECODE_POSITION_AUTO)
    {
        mode += "autonomous";
    }
    else if (modeid & (uint8_t)MAV_MODE_FLAG_DECODE_POSITION_GUIDED)
    {
        mode += "guided";
    }
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    else if (modeid & (uint8_t)MAV_MODE_FLAG_DECODE_POSITION_STABILIZE)
    {
        mode += "stabilized";
    }
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    else if (modeid & (uint8_t)MAV_MODE_FLAG_DECODE_POSITION_MANUAL)
    {
        mode += "manual";
    }
    else
    {
        // Nothing else applies, we're in preflight
        mode += "preflight";
    }

    if (modeid != 0)
    {
        mode += " mode";
    }

    // ARMED STATE DECODING
    if (modeid & (uint8_t)MAV_MODE_FLAG_DECODE_POSITION_SAFETY)
    {
        mode.append(" and armed");
    }

    // HARDWARE IN THE LOOP DECODING
    if (modeid & (uint8_t)MAV_MODE_FLAG_DECODE_POSITION_HIL)
    {
        mode.append(" using hardware in the loop simulation");
    }

    return mode;
}

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/**
* The mode returned can be auto, stabilized, test, manual, preflight or unknown.
* @return the short text of the mode for the id given.
*/
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/**
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* The mode returned can be auto, stabilized, test, manual, preflight or unknown.
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* @return the short text of the mode for the id given.
*/
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QString UAS::getShortModeTextFor(uint8_t base_mode, uint32_t custom_mode, int autopilot)
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{
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    QString mode = "";
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    if (base_mode & MAV_MODE_FLAG_CUSTOM_MODE_ENABLED) {
        // use custom_mode - autopilot-specific
        if (autopilot == MAV_AUTOPILOT_PX4) {
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            union px4_custom_mode px4_mode;
            px4_mode.data = custom_mode;
            if (px4_mode.main_mode == PX4_CUSTOM_MAIN_MODE_MANUAL) {
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                mode += "|MANUAL";
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            } else if (px4_mode.main_mode == PX4_CUSTOM_MAIN_MODE_ALTCTL) {
                mode += "|ALTCTL";
            } else if (px4_mode.main_mode == PX4_CUSTOM_MAIN_MODE_POSCTL) {
                mode += "|POSCTL";
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            } else if (px4_mode.main_mode == PX4_CUSTOM_MAIN_MODE_AUTO) {
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                mode += "|AUTO";
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                if (px4_mode.sub_mode == PX4_CUSTOM_SUB_MODE_AUTO_READY) {
                    mode += "|READY";
                } else if (px4_mode.sub_mode == PX4_CUSTOM_SUB_MODE_AUTO_TAKEOFF) {
                    mode += "|TAKEOFF";
                } else if (px4_mode.sub_mode == PX4_CUSTOM_SUB_MODE_AUTO_LOITER) {
                    mode += "|LOITER";
                } else if (px4_mode.sub_mode == PX4_CUSTOM_SUB_MODE_AUTO_MISSION) {
                    mode += "|MISSION";
                } else if (px4_mode.sub_mode == PX4_CUSTOM_SUB_MODE_AUTO_RTL) {
                    mode += "|RTL";
                } else if (px4_mode.sub_mode == PX4_CUSTOM_SUB_MODE_AUTO_LAND) {
                    mode += "|LAND";
                }
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            }
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        }
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    }
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    // fallback to using base_mode
    if (mode.length() == 0) {
        // use base_mode - not autopilot-specific
        if (base_mode == 0) {
            mode += "|PREFLIGHT";
        } else if (base_mode & MAV_MODE_FLAG_DECODE_POSITION_AUTO) {
            mode += "|AUTO";
        } else if (base_mode & MAV_MODE_FLAG_DECODE_POSITION_MANUAL) {
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            mode += "|MANUAL";
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            if (base_mode & MAV_MODE_FLAG_DECODE_POSITION_GUIDED) {
                mode += "|GUIDED";
            } else if (base_mode & MAV_MODE_FLAG_DECODE_POSITION_STABILIZE) {
                mode += "|STABILIZED";
            }
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        }
    }

    if (mode.length() == 0)
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    {
        mode = "|UNKNOWN";
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        qDebug() << __FILE__ << __LINE__ << " Unknown mode: base_mode=" << base_mode << " custom_mode=" << custom_mode << " autopilot=" << autopilot;
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    }

    // ARMED STATE DECODING
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    if (base_mode & MAV_MODE_FLAG_DECODE_POSITION_SAFETY)
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    {
        mode.prepend("A");
    }
    else
    {
        mode.prepend("D");
    }

    // HARDWARE IN THE LOOP DECODING
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    if (base_mode & MAV_MODE_FLAG_DECODE_POSITION_HIL)
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    {
        mode.prepend("HIL:");
    }

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    //qDebug() << "base_mode=" << base_mode << " custom_mode=" << custom_mode << " autopilot=" << autopilot << ": " << mode;
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    return mode;
}

const QString& UAS::getShortMode() const
{
    return shortModeText;
}

/**
* Add the link and connect a signal to it which will be set off when it is destroyed.
*/
void UAS::addLink(LinkInterface* link)
{
    if (!links->contains(link))
    {
        links->append(link);
        connect(link, SIGNAL(destroyed(QObject*)), this, SLOT(removeLink(QObject*)));
    }
}

void UAS::removeLink(QObject* object)
{
    LinkInterface* link = dynamic_cast<LinkInterface*>(object);
    if (link)
    {
        links->removeAt(links->indexOf(link));
    }
}

/**
* @return the list of links
*/
QList<LinkInterface*>* UAS::getLinks()
{
    return links;
}

/**
* @rerturn the map of the components
*/
QMap<int, QString> UAS::getComponents()
{
    return components;
}

/**
* Set the battery type and the  number of cells.
* @param type of the battery
* @param cells Number of cells.
*/
void UAS::setBattery(BatteryType type, int cells)
{
    this->batteryType = type;
    this->cells = cells;
    switch (batteryType)
    {
    case NICD:
        break;
    case NIMH:
        break;
    case LIION:
        break;
    case LIPOLY:
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        fullVoltage = this->cells * lipoFull;
        emptyVoltage = this->cells * lipoEmpty;
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        break;
    case LIFE:
        break;
    case AGZN:
        break;
    }
}

/**
* Set the battery specificaitons: empty voltage, warning voltage, and full voltage.
* @param specifications of the battery
*/
void UAS::setBatterySpecs(const QString& specs)
{
    if (specs.length() == 0 || specs.contains("%"))
    {
        batteryRemainingEstimateEnabled = false;
        bool ok;
        QString percent = specs;
        percent = percent.remove("%");
        float temp = percent.toFloat(&ok);
        if (ok)
        {
            warnLevelPercent = temp;
        }
        else
        {
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            emit textMessageReceived(0, 0, MAV_SEVERITY_WARNING, "Could not set battery options, format is wrong");
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        }
    }
    else
    {
        batteryRemainingEstimateEnabled = true;
        QString stringList = specs;
        stringList = stringList.remove("V");
        stringList = stringList.remove("v");
        QStringList parts = stringList.split(",");
        if (parts.length() == 3)
        {
            float temp;
            bool ok;
            // Get the empty voltage
            temp = parts.at(0).toFloat(&ok);
            if (ok) emptyVoltage = temp;
            // Get the warning voltage
            temp = parts.at(1).toFloat(&ok);
            if (ok) warnVoltage = temp;
            // Get the full voltage
            temp = parts.at(2).toFloat(&ok);
            if (ok) fullVoltage = temp;
        }
        else
        {
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            emit textMessageReceived(0, 0, MAV_SEVERITY_WARNING, "Could not set battery options, format is wrong");
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        }
    }
}

/**
* @return the battery specifications(empty voltage, warning voltage, full voltage)
*/
QString UAS::getBatterySpecs()
{
    if (batteryRemainingEstimateEnabled)
    {
        return QString("%1V,%2V,%3V").arg(emptyVoltage).arg(warnVoltage).arg(fullVoltage);
    }
    else
    {
        return QString("%1%").arg(warnLevelPercent);
    }
}

/**
* @return the time remaining.
*/
int UAS::calculateTimeRemaining()
{
    quint64 dt = QGC::groundTimeMilliseconds() - startTime;
    double seconds = dt / 1000.0f;
    double voltDifference = startVoltage - currentVoltage;
    if (voltDifference <= 0) voltDifference = 0.00000000001f;
    double dischargePerSecond = voltDifference / seconds;
    int remaining = static_cast<int>((currentVoltage - emptyVoltage) / dischargePerSecond);
    // Can never be below 0
    if (remaining < 0) remaining = 0;
    return remaining;
}

/**
 * @return charge level in percent - 0 - 100
 */
float UAS::getChargeLevel()
{
    if (batteryRemainingEstimateEnabled)
    {
        if (lpVoltage < emptyVoltage)
        {
            chargeLevel = 0.0f;
        }
        else if (lpVoltage > fullVoltage)
        {
            chargeLevel = 100.0f;
        }
        else
        {
            chargeLevel = 100.0f * ((lpVoltage - emptyVoltage)/(fullVoltage - emptyVoltage));
        }
    }
    return chargeLevel;
}

void UAS::startLowBattAlarm()
{
    if (!lowBattAlarm)
    {
        GAudioOutput::instance()->alert(tr("system %1 has low battery").arg(getUASName()));
        QTimer::singleShot(3000, GAudioOutput::instance(), SLOT(startEmergency()));
        lowBattAlarm = true;
    }
}

void UAS::stopLowBattAlarm()
{
    if (lowBattAlarm)
    {
        GAudioOutput::instance()->stopEmergency();
        lowBattAlarm = false;
    }
}