/*=====================================================================
QGroundControl Open Source Ground Control Station
(c) 2009 - 2011 QGROUNDCONTROL PROJECT <http://www.qgroundcontrol.org>
This file is part of the QGROUNDCONTROL project
QGROUNDCONTROL is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
QGROUNDCONTROL is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with QGROUNDCONTROL. If not, see <http://www.gnu.org/licenses/>.
======================================================================*/
/**
* @file QGCXPlaneLink.cc
* Implementation of X-Plane interface
* @author Lorenz Meier <mavteam@student.ethz.ch>
*
*/
#include <QTimer>
#include <QList>
#include <QDebug>
#include <QMutexLocker>
#include <QNetworkInterface>
#include <iostream>
#include "QGCXPlaneLink.h"
#include "QGC.h"
#include <QHostInfo>
#include "UAS.h"
#include "UASInterface.h"
#include "MainWindow.h"
QGCXPlaneLink::QGCXPlaneLink(UASInterface* mav, QString remoteHost, QHostAddress localHost, quint16 localPort) :
mav(mav),
remoteHost(QHostAddress("127.0.0.1")),
remotePort(49000),
socket(NULL),
process(NULL),
terraSync(NULL),
airframeID(QGCXPlaneLink::AIRFRAME_UNKNOWN),
xPlaneConnected(false),
xPlaneVersion(0),
simUpdateLast(QGC::groundTimeMilliseconds()),
simUpdateLastText(QGC::groundTimeMilliseconds()),
simUpdateHz(0),
_sensorHilEnabled(false)
{
this->localHost = localHost;
this->localPort = localPort/*+mav->getUASID()*/;
this->connectState = false;
this->name = tr("X-Plane Link (localPort:%1)").arg(localPort);
setRemoteHost(remoteHost);
loadSettings();
}
QGCXPlaneLink::~QGCXPlaneLink()
{
storeSettings();
// if(connectState) {
// disconnectSimulation();
// }
}
void QGCXPlaneLink::loadSettings()
{
// Load defaults from settings
QSettings settings;
settings.sync();
settings.beginGroup("QGC_XPLANE_LINK");
setRemoteHost(settings.value("REMOTE_HOST", QString("%1:%2").arg(remoteHost.toString()).arg(remotePort)).toString());
setVersion(settings.value("XPLANE_VERSION", 10).toInt());
selectAirframe(settings.value("AIRFRAME", "default").toString());
_sensorHilEnabled = settings.value("SENSOR_HIL", _sensorHilEnabled).toBool();
settings.endGroup();
}
void QGCXPlaneLink::storeSettings()
{
// Store settings
QSettings settings;
settings.beginGroup("QGC_XPLANE_LINK");
settings.setValue("REMOTE_HOST", QString("%1:%2").arg(remoteHost.toString()).arg(remotePort));
settings.setValue("XPLANE_VERSION", xPlaneVersion);
settings.setValue("AIRFRAME", airframeName);
settings.setValue("SENSOR_HIL", _sensorHilEnabled);
settings.endGroup();
settings.sync();
}
void QGCXPlaneLink::setVersion(const QString& version)
{
unsigned int oldVersion = xPlaneVersion;
if (version.contains("9"))
{
xPlaneVersion = 9;
}
else if (version.contains("10"))
{
xPlaneVersion = 10;
}
else if (version.contains("11"))
{
xPlaneVersion = 11;
}
else if (version.contains("12"))
{
xPlaneVersion = 12;
}
if (oldVersion != xPlaneVersion)
{
emit versionChanged(QString("X-Plane %1").arg(xPlaneVersion));
}
}
void QGCXPlaneLink::setVersion(unsigned int version)
{
bool changed = (xPlaneVersion != version);
xPlaneVersion = version;
if (changed) emit versionChanged(QString("X-Plane %1").arg(xPlaneVersion));
}
/**
* @brief Runs the thread
*
**/
void QGCXPlaneLink::run()
{
exec();
}
void QGCXPlaneLink::setPort(int localPort)
{
this->localPort = localPort;
disconnectSimulation();
connectSimulation();
}
void QGCXPlaneLink::processError(QProcess::ProcessError err)
{
switch(err)
{
case QProcess::FailedToStart:
MainWindow::instance()->showCriticalMessage(tr("X-Plane Failed to Start"), tr("Please check if the path and command is correct"));
break;
case QProcess::Crashed:
MainWindow::instance()->showCriticalMessage(tr("X-Plane Crashed"), tr("This is a X-Plane-related problem. Please upgrade X-Plane"));
break;
case QProcess::Timedout:
MainWindow::instance()->showCriticalMessage(tr("X-Plane Start Timed Out"), tr("Please check if the path and command is correct"));
break;
case QProcess::WriteError:
MainWindow::instance()->showCriticalMessage(tr("Could not Communicate with X-Plane"), tr("Please check if the path and command is correct"));
break;
case QProcess::ReadError:
MainWindow::instance()->showCriticalMessage(tr("Could not Communicate with X-Plane"), tr("Please check if the path and command is correct"));
break;
case QProcess::UnknownError:
default:
MainWindow::instance()->showCriticalMessage(tr("X-Plane Error"), tr("Please check if the path and command is correct."));
break;
}
}
QString QGCXPlaneLink::getRemoteHost()
{
return QString("%1:%2").arg(remoteHost.toString()).arg(remotePort);
}
/**
* @param newHost Hostname in standard formatting, e.g. localhost:14551 or 192.168.1.1:14551
*/
void QGCXPlaneLink::setRemoteHost(const QString& newHost)
{
if (newHost.length() == 0)
return;
if (newHost.contains(":"))
{
QHostInfo info = QHostInfo::fromName(newHost.split(":").first());
if (info.error() == QHostInfo::NoError)
{
// Add newHost
QList<QHostAddress> newHostAddresses = info.addresses();
QHostAddress address;
for (int i = 0; i < newHostAddresses.size(); i++)
{
// Exclude loopback IPv4 and all IPv6 addresses
if (!newHostAddresses.at(i).toString().contains(":"))
{
address = newHostAddresses.at(i);
}
}
remoteHost = address;
// Set localPort according to user input
remotePort = newHost.split(":").last().toInt();
}
}
else
{
QHostInfo info = QHostInfo::fromName(newHost);
if (info.error() == QHostInfo::NoError)
{
// Add newHost
remoteHost = info.addresses().first();
if (remotePort == 0) remotePort = 49000;
}
}
if (isConnected())
{
disconnectSimulation();
connectSimulation();
}
emit remoteChanged(QString("%1:%2").arg(remoteHost.toString()).arg(remotePort));
}
void QGCXPlaneLink::updateActuators(uint64_t time, float act1, float act2, float act3, float act4, float act5, float act6, float act7, float act8)
{
if (mav->getSystemType() == MAV_TYPE_QUADROTOR)
// Only update this for multirotors
{
Q_UNUSED(time);
Q_UNUSED(act5);
Q_UNUSED(act6);
Q_UNUSED(act7);
Q_UNUSED(act8);
#pragma pack(push, 1)
struct payload {
char b[5];
int index;
float f[8];
} p;
#pragma pack(pop)
p.b[0] = 'D';
p.b[1] = 'A';
p.b[2] = 'T';
p.b[3] = 'A';
p.b[4] = '\0';
p.index = 25;
memset(p.f, 0, sizeof(p.f));
p.f[0] = act1;
p.f[1] = act2;
p.f[2] = act3;
p.f[3] = act4;
// XXX the system corrects for the scale onboard, do not scale again
// if (airframeID == AIRFRAME_QUAD_X_MK_10INCH_I2C)
// {
// p.f[0] = act1 / 255.0f;
// p.f[1] = act2 / 255.0f;
// p.f[2] = act3 / 255.0f;
// p.f[3] = act4 / 255.0f;
// }
// else if (airframeID == AIRFRAME_QUAD_X_ARDRONE)
// {
// p.f[0] = act1 / 500.0f;
// p.f[1] = act2 / 500.0f;
// p.f[2] = act3 / 500.0f;
// p.f[3] = act4 / 500.0f;
// }
// else
// {
// p.f[0] = (act1 - 1000.0f) / 1000.0f;
// p.f[1] = (act2 - 1000.0f) / 1000.0f;
// p.f[2] = (act3 - 1000.0f) / 1000.0f;
// p.f[3] = (act4 - 1000.0f) / 1000.0f;
// }
// Throttle
writeBytes((const char*)&p, sizeof(p));
}
}
void QGCXPlaneLink::updateControls(uint64_t time, float rollAilerons, float pitchElevator, float yawRudder, float throttle, uint8_t systemMode, uint8_t navMode)
{
// Do not update this control type for
// all multirotors
if (mav->getSystemType() == MAV_TYPE_QUADROTOR ||
mav->getSystemType() == MAV_TYPE_HEXAROTOR ||
mav->getSystemType() == MAV_TYPE_OCTOROTOR)
{
return;
}
#pragma pack(push, 1)
struct payload {
char b[5];
int index;
float f[8];
} p;
#pragma pack(pop)
p.b[0] = 'D';
p.b[1] = 'A';
p.b[2] = 'T';
p.b[3] = 'A';
p.b[4] = '\0';
p.index = 12;
if (mav->getAirframe() == UASInterface::QGC_AIRFRAME_X8 ||
mav->getAirframe() == UASInterface::QGC_AIRFRAME_VIPER_2_0 ||
mav->getAirframe() == UASInterface::QGC_AIRFRAME_CAMFLYER_Q)
{
// de-mix delta-mixed inputs
// pitch input - mixed roll and pitch channels
p.f[0] = 0.5f * (rollAilerons - pitchElevator);
// roll input - mixed roll and pitch channels
p.f[1] = 0.5f * (rollAilerons + pitchElevator);
// yaw
p.f[2] = 0.0f;
}
else
{
// direct pass-through
p.f[0] = -pitchElevator;
p.f[1] = rollAilerons;
p.f[2] = yawRudder;
}
Q_UNUSED(time);
Q_UNUSED(systemMode);
Q_UNUSED(navMode);
// Ail / Elevon / Rudder
writeBytes((const char*)&p, sizeof(p));
p.index = 8;
writeBytes((const char*)&p, sizeof(p));
p.index = 25;
memset(p.f, 0, sizeof(p.f));
p.f[0] = throttle;
p.f[1] = throttle;
p.f[2] = throttle;
p.f[3] = throttle;
// Throttle
writeBytes((const char*)&p, sizeof(p));
}
Eigen::Matrix3f euler_to_wRo(double yaw, double pitch, double roll) {
double c__ = cos(yaw);
double _c_ = cos(pitch);
double __c = cos(roll);
double s__ = sin(yaw);
double _s_ = sin(pitch);
double __s = sin(roll);
double cc_ = c__ * _c_;
double cs_ = c__ * _s_;
double sc_ = s__ * _c_;
double ss_ = s__ * _s_;
double c_c = c__ * __c;
double c_s = c__ * __s;
double s_c = s__ * __c;
double s_s = s__ * __s;
double _cc = _c_ * __c;
double _cs = _c_ * __s;
double csc = cs_ * __c;
double css = cs_ * __s;
double ssc = ss_ * __c;
double sss = ss_ * __s;
Eigen::Matrix3f wRo;
wRo <<
cc_ , css-s_c, csc+s_s,
sc_ , sss+c_c, ssc-c_s,
-_s_ , _cs, _cc;
return wRo;
}
void QGCXPlaneLink::writeBytes(const char* data, qint64 size)
{
if (!data) return;
//#define QGCXPlaneLink_DEBUG
#if 1
QString bytes;
QString ascii;
for (int i=0; i<size; i++)
{
unsigned char v = data[i];
bytes.append(QString().sprintf("%02x ", v));
if (data[i] > 31 && data[i] < 127)
{
ascii.append(data[i]);
}
else
{
ascii.append(219);
}
}
//qDebug() << "Sent" << size << "bytes to" << remoteHost.toString() << ":" << remotePort << "data:";
//qDebug() << bytes;
//qDebug() << "ASCII:" << ascii;
#endif
if (connectState && socket) socket->writeDatagram(data, size, remoteHost, remotePort);
}
/**
* @brief Read a number of bytes from the interface.
*
* @param data Pointer to the data byte array to write the bytes to
* @param maxLength The maximum number of bytes to write
**/
void QGCXPlaneLink::readBytes()
{
// Only emit updates on attitude message
bool emitUpdate = false;
quint16 fields_changed = 0;
const qint64 maxLength = 1000;
char data[maxLength];
QHostAddress sender;
quint16 senderPort;
unsigned int s = socket->pendingDatagramSize();
if (s > maxLength) std::cerr << __FILE__ << __LINE__ << " UDP datagram overflow, allowed to read less bytes than datagram size" << std::endl;
socket->readDatagram(data, maxLength, &sender, &senderPort);
QByteArray b(data, s);
/*// Print string
QString state(b)*/;
// Calculate the number of data segments a 36 bytes
// XPlane always has 5 bytes header: 'DATA@'
unsigned nsegs = (s-5)/36;
//qDebug() << "XPLANE:" << "LEN:" << s << "segs:" << nsegs;
#pragma pack(push, 1)
struct payload {
int index;
float f[8];
} p;
#pragma pack(pop)
bool oldConnectionState = xPlaneConnected;
if (data[0] == 'D' &&
data[1] == 'A' &&
data[2] == 'T' &&
data[3] == 'A')
{
xPlaneConnected = true;
for (unsigned i = 0; i < nsegs; i++)
{
// Get index
unsigned ioff = (5+i*36);;
memcpy(&(p), data+ioff, sizeof(p));
if (p.index == 3)
{
airspeed = p.f[6] * 0.44704f;
groundspeed = p.f[7] * 0.44704;
//qDebug() << "SPEEDS:" << "airspeed" << airspeed << "m/s, groundspeed" << groundspeed << "m/s";
}
if (p.index == 4)
{
// Do not actually use the XPlane value, but calculate our own
Eigen::Vector3f g(0, 0, -9.81f);
Eigen::Matrix3f R = euler_to_wRo(yaw, pitch, roll);
Eigen::Vector3f gr = R.transpose().eval() * g;
// TODO Add centrip. accel
xacc = gr[0];
yacc = gr[1];
zacc = gr[2];
fields_changed |= (1 << 0) | (1 << 1) | (1 << 2);
}
else if (p.index == 6 && xPlaneVersion == 10)
{
// inHg to hPa (hecto Pascal / millibar)
abs_pressure = p.f[0] * 33.863886666718317f;
temperature = p.f[1];
fields_changed |= (1 << 9) | (1 << 12);
}
// Forward controls from X-Plane to MAV, not very useful
// better: Connect Joystick to QGroundControl
// else if (p.index == 8)
// {
// //qDebug() << "MAN:" << p.f[0] << p.f[3] << p.f[7];
// man_roll = p.f[0];
// man_pitch = p.f[1];
// man_yaw = p.f[2];
// UAS* uas = dynamic_cast<UAS*>(mav);
// if (uas) uas->setManualControlCommands(man_roll, man_pitch, man_yaw, 0.6);
// }
else if ((xPlaneVersion == 10 && p.index == 16) || (xPlaneVersion == 9 && p.index == 17))
{
// Cross checked with XPlane flight
pitchspeed = p.f[0];
rollspeed = p.f[1];
yawspeed = p.f[2];
fields_changed |= (1 << 3) | (1 << 4) | (1 << 5);
}
else if ((xPlaneVersion == 10 && p.index == 17) || (xPlaneVersion == 9 && p.index == 18))
{
//qDebug() << "HDNG" << "pitch" << p.f[0] << "roll" << p.f[1] << "hding true" << p.f[2] << "hding mag" << p.f[3];
pitch = p.f[0] / 180.0f * M_PI;
roll = p.f[1] / 180.0f * M_PI;
yaw = p.f[2] / 180.0f * M_PI;
yaw = yaw;
// X-Plane expresses yaw as 0..2 PI
if (yaw > M_PI) {
yaw -= 2.0 * M_PI;
}
if (yaw < -M_PI) {
yaw += 2.0 * M_PI;
}
float yawmag = p.f[3] / 180.0f * M_PI;
if (yawmag > M_PI) {
yawmag -= 2.0 * M_PI;
}
if (yawmag < -M_PI) {
yawmag += 2.0 * M_PI;
}
// Normal rotation matrix, but since we rotate the
// vector [0.25 0 0.45]', we end up with these relevant
// matrix parts.
xmag = cos(-yawmag) * 0.25f;
ymag = sin(-yawmag) * 0.25f;
zmag = 0.45f;
fields_changed |= (1 << 6) | (1 << 7) | (1 << 8);
emitUpdate = true;
}
// else if (p.index == 19)
// {
// qDebug() << "ATT:" << p.f[0] << p.f[1] << p.f[2];
// }
else if (p.index == 20)
{
//qDebug() << "LAT/LON/ALT:" << p.f[0] << p.f[1] << p.f[2];
lat = p.f[0];
lon = p.f[1];
alt = p.f[2] * 0.3048f; // convert feet (MSL) to meters
}
else if (p.index == 21 && xPlaneVersion == 10)
{
vy = p.f[3];
vx = -p.f[5];
vz = p.f[4];
}
else if (p.index == 12)
{
//qDebug() << "AIL/ELEV/RUD" << p.f[0] << p.f[1] << p.f[2];
}
else if (p.index == 25)
{
//qDebug() << "THROTTLE" << p.f[0] << p.f[1] << p.f[2] << p.f[3];
}
else if (p.index == 0)
{
//qDebug() << "STATS" << "fgraphics/s" << p.f[0] << "fsim/s" << p.f[2] << "t frame" << p.f[3] << "cpu load" << p.f[4] << "grnd ratio" << p.f[5] << "filt ratio" << p.f[6];
}
else if (p.index == 11)
{
//qDebug() << "CONTROLS" << "ail" << p.f[0] << "elev" << p.f[1] << "rudder" << p.f[2] << "nwheel" << p.f[3];
}
else
{
//qDebug() << "UNKNOWN #" << p.index << p.f[0] << p.f[1] << p.f[2] << p.f[3];
}
}
}
else if (data[0] == 'S' &&
data[1] == 'N' &&
data[2] == 'A' &&
data[3] == 'P')
{
}
else if (data[0] == 'S' &&
data[1] == 'T' &&
data[2] == 'A' &&
data[3] == 'T')
{
}
else
{
qDebug() << "UNKNOWN PACKET:" << data;
}
// Send updated state
if (emitUpdate && (QGC::groundTimeMilliseconds() - simUpdateLast) > 3)
{
simUpdateHz = simUpdateHz * 0.9f + 0.1f * (1000.0f / (QGC::groundTimeMilliseconds() - simUpdateLast));
if (QGC::groundTimeMilliseconds() - simUpdateLastText > 2000) {
emit statusMessage(tr("Receiving from XPlane at %1 Hz").arg(static_cast<int>(simUpdateHz)));
// Reset lowpass with current value
simUpdateHz = (1000.0f / (QGC::groundTimeMilliseconds() - simUpdateLast));
// Set state
simUpdateLastText = QGC::groundTimeMilliseconds();
}
simUpdateLast = QGC::groundTimeMilliseconds();
if (_sensorHilEnabled)
{
diff_pressure = 0.0f;
pressure_alt = alt;
// set pressure alt to changed
fields_changed |= (1 << 11);
emit sensorHilRawImuChanged(QGC::groundTimeUsecs(), xacc, yacc, zacc, rollspeed, pitchspeed, yawspeed,
xmag, ymag, zmag, abs_pressure, diff_pressure, pressure_alt, temperature, fields_changed);
}
int gps_fix_type = 3;
float eph = 0.3;
float epv = 0.6;
float vel = sqrt(vx*vx + vy*vy + vz*vz);
float cog = atan2(vy, vx);
int satellites = 8;
emit sensorHilGpsChanged(QGC::groundTimeUsecs(), lat, lon, alt, gps_fix_type, eph, epv, vel, cog, satellites);
emit hilStateChanged(QGC::groundTimeUsecs(), roll, pitch, yaw, rollspeed,
pitchspeed, yawspeed, lat, lon, alt,
vx, vy, vz, xacc, yacc, zacc);
}
if (!oldConnectionState && xPlaneConnected)
{
emit statusMessage(tr("Receiving from XPlane."));
}
// // Echo data for debugging purposes
// std::cerr << __FILE__ << __LINE__ << "Received datagram:" << std::endl;
// int i;
// for (i=0; i<s; i++)
// {
// unsigned int v=data[i];
// fprintf(stderr,"%02x ", v);
// }
// std::cerr << std::endl;
}
/**
* @brief Get the number of bytes to read.
*
* @return The number of bytes to read
**/
qint64 QGCXPlaneLink::bytesAvailable()
{
return socket->pendingDatagramSize();
}
/**
* @brief Disconnect the connection.
*
* @return True if connection has been disconnected, false if connection couldn't be disconnected.
**/
bool QGCXPlaneLink::disconnectSimulation()
{
if (!connectState) return true;
connectState = false;
if (process) disconnect(process, SIGNAL(error(QProcess::ProcessError)),
this, SLOT(processError(QProcess::ProcessError)));
if (mav)
{
disconnect(mav, SIGNAL(hilControlsChanged(uint64_t, float, float, float, float, uint8_t, uint8_t)), this, SLOT(updateControls(uint64_t,float,float,float,float,uint8_t,uint8_t)));
disconnect(mav, SIGNAL(hilActuatorsChanged(uint64_t, float, float, float, float, float, float, float, float)), this, SLOT(updateActuators(uint64_t,float,float,float,float,float,float,float,float)));
disconnect(this, SIGNAL(hilStateChanged(quint64,float,float,float,float,float,float,double,double,double,float,float,float,float,float,float)), mav, SLOT(sendHilState(quint64,float,float,float,float,float,float,double,double,double,float,float,float,float,float,float)));
disconnect(this, SIGNAL(sensorHilGpsChanged(quint64,double,double,double,int,float,float,float,float,int)), mav, SLOT(sendHilGps(quint64, double, double, double, int, float, float, float, float, int)));
disconnect(this, SIGNAL(sensorHilRawImuChanged(quint64,float,float,float,float,float,float,float,float,float,float,float,float,float,quint16)), mav, SLOT(sendHilSensors(quint64,float,float,float,float,float,float,float,float,float,float,float,float,float,quint16)));
UAS* uas = dynamic_cast<UAS*>(mav);
if (uas)
{
uas->stopHil();
}
}
if (process)
{
process->close();
delete process;
process = NULL;
}
if (terraSync)
{
terraSync->close();
delete terraSync;
terraSync = NULL;
}
if (socket)
{
socket->close();
delete socket;
socket = NULL;
}
emit simulationDisconnected();
emit simulationConnected(false);
return !connectState;
}
void QGCXPlaneLink::selectAirframe(const QString& plane)
{
airframeName = plane;
if (plane.contains("QRO"))
{
if (plane.contains("MK") && airframeID != AIRFRAME_QUAD_X_MK_10INCH_I2C)
{
airframeID = AIRFRAME_QUAD_X_MK_10INCH_I2C;
emit airframeChanged("QRO_X / MK");
}
else if (plane.contains("ARDRONE") && airframeID != AIRFRAME_QUAD_X_ARDRONE)
{
airframeID = AIRFRAME_QUAD_X_ARDRONE;
emit airframeChanged("QRO_X / ARDRONE");
}
else
{
bool changed = (airframeID != AIRFRAME_QUAD_DJI_F450_PWM);
airframeID = AIRFRAME_QUAD_DJI_F450_PWM;
if (changed) emit airframeChanged("QRO_X / DJI-F450 / PWM");
}
}
else
{
bool changed = (airframeID != AIRFRAME_UNKNOWN);
airframeID = AIRFRAME_UNKNOWN;
if (changed) emit airframeChanged("X Plane default");
}
}
void QGCXPlaneLink::setPositionAttitude(double lat, double lon, double alt, double roll, double pitch, double yaw)
{
#pragma pack(push, 1)
struct VEH1_struct
{
char header[5];
quint32 p;
double lat_lon_ele[3];
float psi_the_phi[3];
float gear_flap_vect[3];
} pos;
#pragma pack(pop)
pos.header[0] = 'V';
pos.header[1] = 'E';
pos.header[2] = 'H';
pos.header[3] = '1';
pos.header[4] = '0';
pos.p = 0;
pos.lat_lon_ele[0] = lat;
pos.lat_lon_ele[1] = lon;
pos.lat_lon_ele[2] = alt;
pos.psi_the_phi[0] = roll;
pos.psi_the_phi[1] = pitch;
pos.psi_the_phi[2] = yaw;
pos.gear_flap_vect[0] = 0.0f;
pos.gear_flap_vect[1] = 0.0f;
pos.gear_flap_vect[2] = 0.0f;
writeBytes((const char*)&pos, sizeof(pos));
// pos.header[0] = 'V';
// pos.header[1] = 'E';
// pos.header[2] = 'H';
// pos.header[3] = '1';
// pos.header[4] = '0';
// pos.p = 0;
// pos.lat_lon_ele[0] = -999;
// pos.lat_lon_ele[1] = -999;
// pos.lat_lon_ele[2] = -999;
// pos.psi_the_phi[0] = -999;
// pos.psi_the_phi[1] = -999;
// pos.psi_the_phi[2] = -999;
// pos.gear_flap_vect[0] = -999;
// pos.gear_flap_vect[1] = -999;
// pos.gear_flap_vect[2] = -999;
// writeBytes((const char*)&pos, sizeof(pos));
}
/**
* Sets a random position with an offset of max 1/1000 degree
* and max 100 m altitude
*/
void QGCXPlaneLink::setRandomPosition()
{
// Initialize generator
srand(0);
double offLat = rand() / static_cast<double>(RAND_MAX) / 500.0 + 1.0/500.0;
double offLon = rand() / static_cast<double>(RAND_MAX) / 500.0 + 1.0/500.0;
double offAlt = rand() / static_cast<double>(RAND_MAX) * 200.0 + 100.0;
if (mav->getAltitude() + offAlt < 0)
{
offAlt *= -1.0;
}
setPositionAttitude(mav->getLatitude() + offLat,
mav->getLongitude() + offLon,
mav->getAltitude() + offAlt,
mav->getRoll(),
mav->getPitch(),
mav->getYaw());
}
void QGCXPlaneLink::setRandomAttitude()
{
// Initialize generator
srand(0);
double roll = rand() / static_cast<double>(RAND_MAX) * 2.0 - 1.0;
double pitch = rand() / static_cast<double>(RAND_MAX) * 2.0 - 1.0;
double yaw = rand() / static_cast<double>(RAND_MAX) * 2.0 - 1.0;
setPositionAttitude(mav->getLatitude(),
mav->getLongitude(),
mav->getAltitude(),
roll,
pitch,
yaw);
}
/**
* @brief Connect the connection.
*
* @return True if connection has been established, false if connection couldn't be established.
**/
bool QGCXPlaneLink::connectSimulation()
{
qDebug() << "STARTING X-PLANE LINK, CONNECTING TO" << remoteHost << ":" << remotePort;
// XXX Hack
storeSettings();
start(LowPriority);
if (!mav) return false;
if (connectState) return false;
socket = new QUdpSocket(this);
connectState = socket->bind(localHost, localPort);
if (!connectState) return false;
QObject::connect(socket, SIGNAL(readyRead()), this, SLOT(readBytes()));
connect(mav, SIGNAL(hilControlsChanged(uint64_t, float, float, float, float, uint8_t, uint8_t)), this, SLOT(updateControls(uint64_t,float,float,float,float,uint8_t,uint8_t)));
connect(mav, SIGNAL(hilActuatorsChanged(uint64_t, float, float, float, float, float, float, float, float)), this, SLOT(updateActuators(uint64_t,float,float,float,float,float,float,float,float)));
connect(this, SIGNAL(hilStateChanged(quint64,float,float,float,float,float,float,double,double,double,float,float,float,float,float,float)), mav, SLOT(sendHilState(quint64,float,float,float,float,float,float,double,double,double,float,float,float,float,float,float)));
connect(this, SIGNAL(sensorHilGpsChanged(quint64,double,double,double,int,float,float,float,float,int)), mav, SLOT(sendHilGps(quint64, double, double, double, int, float, float, float, float, int)));
connect(this, SIGNAL(sensorHilRawImuChanged(quint64,float,float,float,float,float,float,float,float,float,float,float,float,float,quint16)), mav, SLOT(sendHilSensors(quint64,float,float,float,float,float,float,float,float,float,float,float,float,float,quint16)));
UAS* uas = dynamic_cast<UAS*>(mav);
if (uas)
{
uas->startHil();
}
#pragma pack(push, 1)
struct iset_struct
{
char b[5];
int index; // (0->20 in the lsit below)
char str_ipad_them[16];
char str_port_them[6];
char padding[2];
int use_ip;
} ip; // to use this option, 0 not to.
#pragma pack(pop)
ip.b[0] = 'I';
ip.b[1] = 'S';
ip.b[2] = 'E';
ip.b[3] = 'T';
ip.b[4] = '0';
QList<QHostAddress> hostAddresses = QNetworkInterface::allAddresses();
QString localAddrStr;
QString localPortStr = QString("%1").arg(localPort);
for (int i = 0; i < hostAddresses.size(); i++)
{
// Exclude loopback IPv4 and all IPv6 addresses
if (hostAddresses.at(i) != QHostAddress("127.0.0.1") && !hostAddresses.at(i).toString().contains(":"))
{
localAddrStr = hostAddresses.at(i).toString();
break;
}
}
//qDebug() << "REQ SEND TO:" << localAddrStr << localPortStr;
ip.index = 0;
strncpy(ip.str_ipad_them, localAddrStr.toAscii(), qMin((int)sizeof(ip.str_ipad_them), 16));
strncpy(ip.str_port_them, localPortStr.toAscii(), qMin((int)sizeof(ip.str_port_them), 6));
ip.use_ip = 1;
writeBytes((const char*)&ip, sizeof(ip));
return connectState;
}
/**
* @brief Check if connection is active.
*
* @return True if link is connected, false otherwise.
**/
bool QGCXPlaneLink::isConnected()
{
return connectState;
}
QString QGCXPlaneLink::getName()
{
return name;
}
void QGCXPlaneLink::setName(QString name)
{
this->name = name;
// emit nameChanged(this->name);
}