using System;
using System.Collections.Generic;
using System.Drawing;
using System.Text;
using System.Windows.Forms;
using System.Net;
using System.Net.Sockets;
using System.IO.Ports;
using System.IO;
using System.Xml; // config file
using System.Runtime.InteropServices; // dll imports
using log4net;
using ZedGraph; // Graphs
using ArdupilotMega;
using System.Reflection;
using ArdupilotMega.Controls;
using System.Drawing.Drawing2D;

using ArdupilotMega.HIL;

// Written by Michael Oborne
namespace ArdupilotMega.GCSViews
{
    public partial class Simulation : MyUserControl
    {
        private static readonly ILog log = LogManager.GetLogger(MethodBase.GetCurrentMethod().DeclaringType);
        MAVLink comPort = MainV2.comPort;
        UdpClient XplanesSEND;
        UdpClient MavLink;
        Socket SimulatorRECV;
        TcpClient JSBSimSEND;
        UdpClient SITLSEND;
        EndPoint Remote = (EndPoint)(new IPEndPoint(IPAddress.Any, 0));
        byte[] udpdata = new byte[113 * 9 + 5]; // 113 types - 9 items per type (index+8) + 5 byte header
        float[][] DATA = new float[113][];
        TDataFromAeroSimRC aeroin = new TDataFromAeroSimRC();
        DateTime now = DateTime.Now;
        DateTime lastgpsupdate = DateTime.Now;
        List<string> position = new List<string>();
        int REV_pitch = 1;
        int REV_roll = 1;
        int REV_rudder = 1;
        int GPS_rate = 200;
        bool displayfull = false;
        int packetssent = 0;
        //string logdata = "";
        int tickStart = 0;
        public static int threadrun = 0;
        string simIP = "127.0.0.1";
        int simPort = 49000;
        int recvPort = 49005;

        // gps buffer
        int gpsbufferindex = 0;

        sitl_fdm[] sitl_fdmbuffer = new sitl_fdm[5];

        // set defaults
        int rollgain = 10000;
        int pitchgain = 10000;
        int ruddergain = 10000;
        int throttlegain = 10000;

        // for servo graph
        RollingPointPairList list = new RollingPointPairList(1200);
        RollingPointPairList list2 = new RollingPointPairList(1200);
        RollingPointPairList list3 = new RollingPointPairList(1200);
        RollingPointPairList list4 = new RollingPointPairList(1200);

        [StructLayout(LayoutKind.Sequential, Pack = 1)]
        public struct fgIMUData
        {
            // GPS
            public double latitude;
            public double longitude;
            public double altitude;
            public double heading;
            public double velocityN;
            public double velocityE;

            // IMU
            public double accelX;
            public double accelY;
            public double accelZ;
            public double rateRoll;
            public double ratePitch;
            public double rateYaw;

            // trailer
            public uint magic;
        }

        [StructLayout(LayoutKind.Sequential, Pack = 1)]
        public struct sitl_fdm
        {
            // this is the packet sent by the simulator
            // to the APM executable to update the simulator state
            // All values are little-endian
            public double latitude, longitude; // degrees
            public double altitude;  // MSL
            public double heading;   // degrees
            public double speedN, speedE; // m/s
            public double xAccel, yAccel, zAccel;       // m/s/s in body frame
            public double rollRate, pitchRate, yawRate; // degrees/s/s in earth frame
            public double rollDeg, pitchDeg, yawDeg;    // euler angles, degrees
            public double airspeed; // m/s
            public UInt32 magic; // 0x4c56414e
        };

        const int AEROSIMRC_MAX_CHANNELS = 39;

        //-----------------------------------------------------------------------------
        // Two main data structures are used. This is the first one:
        //
        // This data struct is filled by AeroSIM RC with the simulation data, and sent to the plugin
        //-----------------------------------------------------------------------------
        [StructLayout(LayoutKind.Sequential, Pack = 1)]
        public struct TDataFromAeroSimRC
        {
            public ushort nStructSize;  // size in bytes of TDataFromAeroSimRC

            //---------------------
            // Integration Time
            //---------------------
            public float Simulation_fIntegrationTimeStep;  // integration time step in seconds. This is the simulated time since last call to AeroSIMRC_Plugin_Run()

            //---------------------
            // Channels
            //---------------------

            [MarshalAs(
                UnmanagedType.ByValArray,
                SizeConst = AEROSIMRC_MAX_CHANNELS)]
            public float[] Channel_afValue_TX;  // [-1, 1] channel positions at TX sticks (i.e. raw stick positions)
            [MarshalAs(
          UnmanagedType.ByValArray,
          SizeConst = AEROSIMRC_MAX_CHANNELS)]
            public float[] Channel_afValue_RX;   // [-1, 1] channel positions at RX (i.e. after TX mixes)

            // Use the following constants as indexes for the channel arrays
            // The simulator uses internally the channel numbers for Transmitter Mode 2 (regardless of mode selected by user)
            const int CH_AILERON = 0;
            const int CH_ELEVATOR = 1;
            const int CH_THROTTLE = 2;
            const int CH_RUDDER = 3;
            const int CH_5 = 4;
            const int CH_6 = 5;
            const int CH_7 = 6;
            const int CH_PLUGIN_1 = 22; // This channel is mapped by user to any real channel number
            const int CH_PLUGIN_2 = 23; // This channel is mapped by user to any real channel number

            //---------------------
            // OSD
            //---------------------
            // Video buffer for OSD is a bitmap, 4 bytes per pixel: R G B A; The first 4 bytes are the Top-Left corner pixel
            // The size of the OSD Video Buffer is defined in plugin.txt
            // .OSD_BUFFER_SIZE, in plugin.txt, can be set to one of the following sizes: 512x512, 1024x512 or 1024x1024
            // Set OSD_nWindow_DX and OSD_nWindow_DY in struct TDataToAeroSimRC to the actual size to be displayed
            public IntPtr OSD_pVideoBuffer;

            //---------------------
            // Menu
            //---------------------
            // This variable represent the custom menu status. E.g. 0x000001 means that first menu item is ticked
            // Command  menu item bits are set to 1 when selected, but cleared in the next cycle.
            // Checkbox menu item bits remain 1 until unchecked by user, or cleared in TDataToAeroSimRC::Menu_nFlags_MenuItem_New_CheckBox_Status
            public uint Menu_nFlags_MenuItem_Status;

            //---------------------
            // Model Initial Position in current scenario
            //---------------------
            public float Scenario_fInitialModelPosX; public float Scenario_fInitialModelPosY; public float Scenario_fInitialModelPosZ; // (m) Model Initial Position on runway
            public float Scenario_fInitialModelHeading; public float Scenario_fInitialModelPitch; public float Scenario_fInitialModelRoll; // (m) Model Initial Attitude on runway

            //---------------------
            // WayPoints
            // The Description string can be freely used to add more information to the waypoint such as Altitude, WP Type (Overfly, Landing, CAP), Bearing, etc.
            //---------------------
            public float Scenario_fWPHome_X; public float Scenario_fWPHome_Y; public float Scenario_fWPHome_Lat; public float Scenario_fWPHome_Long; IntPtr Scenario_strWPHome_Description; // (m, deg, string)
            public float Scenario_fWPA_X; public float Scenario_fWPA_Y; public float Scenario_fWPA_Lat; public float Scenario_fWPA_Long; IntPtr Scenario_strWPA_Description;    // (m, deg, string)
            public float Scenario_fWPB_X; public float Scenario_fWPB_Y; public float Scenario_fWPB_Lat; public float Scenario_fWPB_Long; IntPtr Scenario_strWPB_Description;    // (m, deg, string)
            public float Scenario_fWPC_X; public float Scenario_fWPC_Y; public float Scenario_fWPC_Lat; public float Scenario_fWPC_Long; IntPtr Scenario_strWPC_Description;    // (m, deg, string)
            public float Scenario_fWPD_X; public float Scenario_fWPD_Y; public float Scenario_fWPD_Lat; public float Scenario_fWPD_Long; IntPtr Scenario_strWPD_Description;    // (m, deg, string)

            //---------------------
            // Model data
            //---------------------
            public float Model_fPosX; public float Model_fPosY; public float Model_fPosZ;    // m      Model absolute position in scenario (X=Right, Y=Front, Z=Up)
            public float Model_fVelX; public float Model_fVelY; public float Model_fVelZ;    // m/s    Model velocity
            public float Model_fAngVelX; public float Model_fAngVelY; public float Model_fAngVelZ; // rad/s  Model angular velocity (useful to implement gyroscopes)
            public float Model_fAccelX; public float Model_fAccelY; public float Model_fAccelZ;  // m/s/s  Model acceleration (useful to implement accelerometers)

            public double Model_fLatitude; public double Model_fLongitude;   // deg    Model Position in Lat/Long coordinates

            public float Model_fHeightAboveTerrain;            // m

            public float Model_fHeading;                       // rad [-PI,   PI  ] 0 = North, PI/2 = East, PI = South, - PI/2 = West
            public float Model_fPitch;                         // rad [-PI/2, PI/2] Positive pitch when nose up
            public float Model_fRoll;                          // rad [-PI,   PI  ] Positive roll when right wing Up

            // Wind
            public float Model_fWindVelX; public float Model_fWindVelY; public float Model_fWindVelZ;    // m/s   Velocity of the wind (with gusts) at model position (useful to compute air vel)

            // Engine/Motor Revs per minute
            public float Model_fEngine1_RPM;
            public float Model_fEngine2_RPM;
            public float Model_fEngine3_RPM;
            public float Model_fEngine4_RPM;

            // Battery (electric models)
            public float Model_fBatteryVoltage;          // V
            public float Model_fBatteryCurrent;          // A
            public float Model_fBatteryConsumedCharge;   // Ah
            public float Model_fBatteryCapacity;         // Ah

            // Fuel (gas & jet models)
            public float Model_fFuelConsumed;            // l
            public float Model_fFuelTankCapacity;        // l

            // Ver > 3.81
            // Screen size
            public short Win_nScreenSizeDX; public short Win_nScreenSizeDY; // Screen Size, used to resize and reposition simulator window

            // Model Orientation Matrix
            public float Model_fAxisRight_x; public float Model_fAxisRight_y; public float Model_fAxisRight_z;
            public float Model_fAxisFront_x; public float Model_fAxisFront_y; public float Model_fAxisFront_z;
            public float Model_fAxisUp_x; public float Model_fAxisUp_y; public float Model_fAxisUp_z;

            // Model data in body frame coordinates (X=Right, Y=Front, Z=Up)
            public float Model_fVel_Body_X; public float Model_fVel_Body_Y; public float Model_fVel_Body_Z;    // m/s    Model velocity in body coordinates
            public float Model_fAngVel_Body_X; public float Model_fAngVel_Body_Y; public float Model_fAngVel_Body_Z; // rad/s  Model angular velocity in body coordinates
            public float Model_fAccel_Body_X; public float Model_fAccel_Body_Y; public float Model_fAccel_Body_Z;  // m/s/s  Model acceleration in body coordinates

            // Size in bytes of the allocated OSD buffer (size is defined in plugin.txt in .OSD_BUFFER_SIZE)
            // The buffer size is 4 x .OSD_VIDEO_BUFFER_SIZE (e.g. 4x512x512 = 1048576 bytes), so you should not write outside that memory.
            public uint OSD_nSizeOfVideoBuffer;
        }


        ~Simulation()
        {
            if (threadrun == 1)
                ConnectComPort_Click(new object(), new EventArgs());

            MavLink = null;
            XplanesSEND = null;
            SimulatorRECV = null;
        }

        public Simulation()
        {
            InitializeComponent();
        }

        private void Simulation_Load(object sender, EventArgs e)
        {
            timer_servo_graph.Stop();

            GPSrate.SelectedIndex = 2;

            xmlconfig(false);

            CreateChart(zg1);

            zg1.Visible = displayfull;

            CHKgraphpitch.Visible = displayfull;
            CHKgraphroll.Visible = displayfull;
            CHKgraphrudder.Visible = displayfull;
            CHKgraphthrottle.Visible = displayfull;
        }

        private void ConnectComPort_Click(object sender, EventArgs e)
        {
            if (threadrun == 0)
            {
                OutputLog.Clear();

                if (MainV2.comPort.BaseStream.IsOpen == false)
                {
                    CustomMessageBox.Show("Please connect first");
                    return;
                }


                try
                {
                    quad = new HIL.QuadCopter();

                    if (RAD_JSBSim.Checked)
                    {
                        simPort = 5124;
                        recvPort = 5123;
                    }

                    SetupUDPRecv();

                    if (chkSensor.Checked)
                    {
                        SITLSEND = new UdpClient(simIP, 5501);
                    }

                    if (RAD_softXplanes.Checked)
                    {
                        SetupUDPXplanes();
                        SetupUDPMavLink();
                    }
                    else
                    {
                        if (RAD_JSBSim.Checked)
                        {
                            System.Diagnostics.ProcessStartInfo _procstartinfo = new System.Diagnostics.ProcessStartInfo();
                            _procstartinfo.WorkingDirectory = Path.GetDirectoryName(Application.ExecutablePath);
                            _procstartinfo.Arguments = "--realtime --suspend --nice --simulation-rate=1000 --logdirectivefile=jsbsim/fgout.xml --script=jsbsim/rascal_test.xml";
                            _procstartinfo.FileName = "JSBSim.exe";
                            // Path.GetDirectoryName(Application.ExecutablePath) + Path.DirectorySeparatorChar +

                            _procstartinfo.UseShellExecute = true;
                            //_procstartinfo.RedirectStandardOutput = true;


                            System.Diagnostics.Process.Start(_procstartinfo);

                            System.Threading.Thread.Sleep(2000);

                            SetupTcpJSBSim(); // old style
                        }

                        SetupUDPXplanes(); // fg udp style
                        SetupUDPMavLink(); // pass traffic - raw
                    }

                    OutputLog.AppendText("Sim Link Started\n");
                }
                catch (Exception ex) { OutputLog.AppendText("Socket setup problem. Do you have this open already? " + ex.ToString()); }

                System.Threading.Thread t11 = new System.Threading.Thread(new System.Threading.ThreadStart(mainloop))
                {
                    Name = "Main simu Serial/UDP listener",
                    IsBackground = true
                };
                t11.Start();
                timer_servo_graph.Start();
            }
            else
            {

                timer_servo_graph.Stop();
                threadrun = 0;
                if (SimulatorRECV != null)
                    SimulatorRECV.Close();
                if (SimulatorRECV != null && SimulatorRECV.Connected)
                    SimulatorRECV.Disconnect(true);
                if (MavLink != null)
                    MavLink.Close();
                position.Clear();

                if (XplanesSEND != null)
                    XplanesSEND.Close();

                //                if (comPort.BaseStream.IsOpen)
                //                    comPort.stopall(true);

                OutputLog.AppendText("Sim Link Stopped\n");

                System.Threading.Thread.Sleep(1000);
                Application.DoEvents();
            }
        }

        /// <summary>
        /// Sets config hash for write on application exit
        /// </summary>
        /// <param name="write">true/false</param>
        private void xmlconfig(bool write)
        {
            if (write)
            {
                ArdupilotMega.MainV2.config["REV_roll"] = CHKREV_roll.Checked.ToString();
                ArdupilotMega.MainV2.config["REV_pitch"] = CHKREV_pitch.Checked.ToString();
                ArdupilotMega.MainV2.config["REV_rudder"] = CHKREV_rudder.Checked.ToString();
                ArdupilotMega.MainV2.config["GPSrate"] = GPSrate.Text;

                ArdupilotMega.MainV2.config["MAVrollgain"] = TXT_rollgain.Text;
                ArdupilotMega.MainV2.config["MAVpitchgain"] = TXT_pitchgain.Text;
                ArdupilotMega.MainV2.config["MAVruddergain"] = TXT_ruddergain.Text;
                ArdupilotMega.MainV2.config["MAVthrottlegain"] = TXT_throttlegain.Text;

                ArdupilotMega.MainV2.config["CHKdisplayall"] = CHKdisplayall.Checked.ToString();

                ArdupilotMega.MainV2.config["simIP"] = simIP;
                ArdupilotMega.MainV2.config["recvPort"] = recvPort;

                ArdupilotMega.MainV2.config["simPort"] = simPort.ToString();
            }
            else
            {
                foreach (string key in ArdupilotMega.MainV2.config.Keys)
                {
                    switch (key)
                    {
                        case "simIP":
                            simIP = ArdupilotMega.MainV2.config[key].ToString();
                            break;
                        case "simPort":
                            simPort = int.Parse(ArdupilotMega.MainV2.config[key].ToString());
                            break;
                        case "recvPort":
                            recvPort = int.Parse(ArdupilotMega.MainV2.config[key].ToString());
                            break;
                        case "REV_roll":
                            CHKREV_roll.Checked = bool.Parse(ArdupilotMega.MainV2.config[key].ToString());
                            break;
                        case "REV_pitch":
                            CHKREV_pitch.Checked = bool.Parse(ArdupilotMega.MainV2.config[key].ToString());
                            break;
                        case "REV_rudder":
                            CHKREV_rudder.Checked = bool.Parse(ArdupilotMega.MainV2.config[key].ToString());
                            break;
                        case "GPSrate":
                            GPSrate.Text = ArdupilotMega.MainV2.config[key].ToString();
                            break;
                        case "MAVrollgain":
                            TXT_rollgain.Text = ArdupilotMega.MainV2.config[key].ToString();
                            break;
                        case "MAVpitchgain":
                            TXT_pitchgain.Text = ArdupilotMega.MainV2.config[key].ToString();
                            break;
                        case "MAVruddergain":
                            TXT_ruddergain.Text = ArdupilotMega.MainV2.config[key].ToString();
                            break;
                        case "MAVthrottlegain":
                            TXT_throttlegain.Text = ArdupilotMega.MainV2.config[key].ToString();
                            break;
                        case "CHKdisplayall":
                            CHKdisplayall.Checked = bool.Parse(ArdupilotMega.MainV2.config[key].ToString());
                            displayfull = CHKdisplayall.Checked;
                            break;
                        default:
                            break;
                    }
                }
            }
        }

        FGNetFDM lastfdmdata = new FGNetFDM();

        const int FG_MAX_ENGINES = 4;
        const int FG_MAX_WHEELS = 3;
        const int FG_MAX_TANKS = 4;
        [StructLayout(LayoutKind.Sequential, Pack = 1)]
        public struct FGNetFDM
        {
            public uint version;		// increment when data values change
            public uint padding;		// padding

            // Positions
            public double longitude;		// geodetic (radians)
            public double latitude;		// geodetic (radians)
            public double altitude;		// above sea level (meters)
            public float agl;			// above ground level (meters)
            public float phi;			// roll (radians)
            public float theta;		// pitch (radians)
            public float psi;			// yaw or true heading (radians)
            public float alpha;                // angle of attack (radians)
            public float beta;                 // side slip angle (radians)

            // Velocities
            public float phidot;		// roll rate (radians/sec)
            public float thetadot;		// pitch rate (radians/sec)
            public float psidot;		// yaw rate (radians/sec)
            public float vcas;		        // calibrated airspeed
            public float climb_rate;		// feet per second
            public float v_north;              // north velocity in local/body frame, fps
            public float v_east;               // east velocity in local/body frame, fps
            public float v_down;               // down/vertical velocity in local/body frame, fps
            public float v_wind_body_north;    // north velocity in local/body frame
            // relative to local airmass, fps
            public float v_wind_body_east;     // east velocity in local/body frame
            // relative to local airmass, fps
            public float v_wind_body_down;     // down/vertical velocity in local/body
            // frame relative to local airmass, fps

            // Accelerations
            public float A_X_pilot;		// X accel in body frame ft/sec^2
            public float A_Y_pilot;		// Y accel in body frame ft/sec^2
            public float A_Z_pilot;		// Z accel in body frame ft/sec^2

            // Stall
            public float stall_warning;        // 0.0 - 1.0 indicating the amount of stall
            public float slip_deg;		// slip ball deflection


            // Pressure

            // Engine status
            uint num_engines;          // Number of valid engines
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            uint[] eng_state;// Engine state (off, cranking, running)
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] rpm;           // Engine RPM rev/min
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] fuel_flow; // Fuel flow gallons/hr
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] fuel_px;   // Fuel pressure psi
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] egt;           // Exhuast gas temp deg F
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] cht;           // Cylinder head temp deg F
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] mp_osi;    // Manifold pressure
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] tit;           // Turbine Inlet Temperature
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] oil_temp;  // Oil temp deg F
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_ENGINES)]
            float[] oil_px;    // Oil pressure psi

            // Consumables
            uint num_tanks;       // Max number of fuel tanks
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_TANKS)]
            float[] fuel_quantity;

            // Gear status
            uint num_wheels;
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_WHEELS)]
            uint[] wow;
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_WHEELS)]
            float[] gear_pos;
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_WHEELS)]
            float[] gear_steer;
            [MarshalAs(UnmanagedType.ByValArray, SizeConst = FG_MAX_WHEELS)]
            float[] gear_compression;

            // Environment
            uint cur_time;           // current unix time
            // FIXME: make this uint64_t before 2038
            int warp;                // offset in seconds to unix time
            float visibility;            // visibility in meters (for env. effects)

            // Control surface positions (normalized values)
            float elevator;
            float elevator_trim_tab;
            float left_flap;
            float right_flap;
            float left_aileron;
            float right_aileron;
            float rudder;
            float nose_wheel;
            float speedbrake;
            float spoilers;
        }

        const float ft2m = (float)(1.0 / 3.2808399);
        const float rad2deg = (float)(180 / Math.PI);
        const float deg2rad = (float)(1.0 / rad2deg);
        const float kts2fps = (float)1.68780986;

        private void mainloop()
        {
            //System.Threading.Thread.CurrentThread.CurrentUICulture = new System.Globalization.CultureInfo("en-US");
            //System.Threading.Thread.CurrentThread.CurrentCulture = new System.Globalization.CultureInfo("en-US"); 
            threadrun = 1;
            Remote = (EndPoint)(new IPEndPoint(IPAddress.Any, 0));

            DateTime lastdata = DateTime.MinValue;

            // set enable hil status flag - sends base_mode = 0
            MainV2.comPort.setMode(new MAVLink.mavlink_set_mode_t() { target_system = MainV2.comPort.sysid }, MAVLink.MAV_MODE_FLAG.HIL_ENABLED);

            while (threadrun == 1)
            {
                if (comPort.BaseStream.IsOpen == false) { break; }
                // re-request servo data
                if (!(lastdata.AddSeconds(8) > DateTime.Now))
                {
                    try
                    {

                        if (CHK_quad.Checked && !RAD_aerosimrc.Checked)// || chkSensor.Checked && RAD_JSBSim.Checked)
                        {
                            comPort.requestDatastream((byte)ArdupilotMega.MAVLink.MAV_DATA_STREAM.RAW_CONTROLLER, 0); // request servoout
                        }
                        else
                        {
                            comPort.requestDatastream((byte)ArdupilotMega.MAVLink.MAV_DATA_STREAM.RAW_CONTROLLER, 50); // request servoout
                        }
                    }
                    catch { }
                    lastdata = DateTime.Now; // prevent flooding
                }
                if (SimulatorRECV.Available > 0)
                {
                    udpdata = new byte[udpdata.Length];
                    try
                    {
                        while (SimulatorRECV.Available > 0)
                        {
                            int recv = SimulatorRECV.ReceiveFrom(udpdata, ref Remote);

                            RECVprocess(udpdata, recv, comPort);

                            hzcount++;
                        }
                    }
                    catch
                    { //OutputLog.AppendText("Xplanes Data Problem - You need DATA IN/OUT 3, 4, 17, 18, 19, 20\n" + ex.Message + "\n");
                    }
                }
                if (MavLink != null && MavLink.Client != null && MavLink.Client.Connected && MavLink.Available > 0)
                {
                    IPEndPoint RemoteIpEndPoint = new IPEndPoint(IPAddress.Any, 0);
                    try
                    {
                        Byte[] receiveBytes = MavLink.Receive(ref RemoteIpEndPoint);


                        comPort.BaseStream.Write(receiveBytes, 0, receiveBytes.Length);
                    }
                    catch { }
                }
                if (comPort.BaseStream.IsOpen == false) { break; }
                try
                {

                    MainV2.cs.UpdateCurrentSettings(null); // when true this uses alot more cpu time

                    if ((DateTime.Now - simsendtime).TotalMilliseconds > 19)
                    {
                        //hzcount++;
                        simsendtime = DateTime.Now;
                        processArduPilot();
                    }
                }
                catch (Exception ex) { log.Info("SIM Main loop exception " + ex.ToString()); }

                if (hzcounttime.Second != DateTime.Now.Second)
                {
                   // Console.WriteLine("SIM hz {0}", hzcount);
                    hzcount = 0;
                    hzcounttime = DateTime.Now;
                }



                System.Threading.Thread.Sleep(1); // this controls send speed  to sim                
            }

        }

        int hzcount = 0;
        DateTime hzcounttime = DateTime.Now;

        DateTime simsendtime = DateTime.Now;

        private void SetupUDPRecv()
        {
            // setup receiver
            IPEndPoint ipep = new IPEndPoint(IPAddress.Any, recvPort);

            SimulatorRECV = new Socket(AddressFamily.InterNetwork,
                            SocketType.Dgram, ProtocolType.Udp);

            SimulatorRECV.Bind(ipep);

            OutputLog.AppendText("Listerning on port UDP " + recvPort + " (sim->planner)\n");
        }

        private void SetupTcpJSBSim()
        {
            try
            {
                JSBSimSEND = new TcpClient();
                JSBSimSEND.Client.NoDelay = true;
                JSBSimSEND.Connect("127.0.0.1", simPort);
                OutputLog.AppendText("Sending to port TCP " + simPort + " (planner->sim)\n");

                //JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("set position/h-agl-ft 0\r\n"));

                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("set position/lat-gc-deg " + MainV2.cs.HomeLocation.Lat + "\r\n"));
                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("set position/long-gc-deg " + MainV2.cs.HomeLocation.Lng + "\r\n"));

                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("set attitude/phi-rad 0\r\n"));
                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("set attitude/theta-rad 0\r\n"));
                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("set attitude/psi-rad 0\r\n"));

                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("info\r\n"));

                JSBSimSEND.Client.Send(System.Text.Encoding.ASCII.GetBytes("resume\r\n"));
            }
            catch { log.Info("JSB console fail"); }
        }

        private void SetupUDPXplanes()
        {
            // setup sender
            XplanesSEND = new UdpClient(simIP, simPort);

            OutputLog.AppendText("Sending to port UDP " + simPort + " (planner->sim)\n");

            setupXplane();

            OutputLog.AppendText("Sent xplane settings\n");
        }

        private void SetupUDPMavLink()
        {
            // setup sender
            MavLink = new UdpClient("127.0.0.1", 14550);
        }

        DateTime oldtime = DateTime.Now;

        sitl_fdm oldgps = new sitl_fdm();

        /// <summary>
        /// Recevied UDP packet, process and send required data to serial port.
        /// </summary>
        /// <param name="data">Packet</param>
        /// <param name="receviedbytes">Length</param>
        /// <param name="comPort">Com Port</param>
        private void RECVprocess(byte[] data, int receviedbytes, ArdupilotMega.MAVLink comPort)
        {
            sitl_fdm sitldata = new sitl_fdm();

            if (data[0] == 'D' && data[1] == 'A')
            {
                // Xplanes sends
                // 5 byte header
                // 1 int for the index - numbers on left of output
                // 8 floats - might be useful. or 0 if not
                int count = 5;
                while (count < receviedbytes)
                {
                    int index = BitConverter.ToInt32(data, count);

                    DATA[index] = new float[8];

                    DATA[index][0] = BitConverter.ToSingle(data, count + 1 * 4); ;
                    DATA[index][1] = BitConverter.ToSingle(data, count + 2 * 4); ;
                    DATA[index][2] = BitConverter.ToSingle(data, count + 3 * 4); ;
                    DATA[index][3] = BitConverter.ToSingle(data, count + 4 * 4); ;
                    DATA[index][4] = BitConverter.ToSingle(data, count + 5 * 4); ;
                    DATA[index][5] = BitConverter.ToSingle(data, count + 6 * 4); ;
                    DATA[index][6] = BitConverter.ToSingle(data, count + 7 * 4); ;
                    DATA[index][7] = BitConverter.ToSingle(data, count + 8 * 4); ;

                    count += 36; // 8 * float
                }

                bool xplane9 = !CHK_xplane10.Checked;

                if (xplane9)
                {
                    sitldata.pitchDeg = (DATA[18][0]);
                    sitldata.rollDeg = (DATA[18][1]);
                    sitldata.yawDeg = (DATA[18][2]);
                    sitldata.pitchRate = (DATA[17][0] * rad2deg);
                    sitldata.rollRate = (DATA[17][1] * rad2deg);
                    sitldata.yawRate = (DATA[17][2] * rad2deg);

                    sitldata.heading = ((float)DATA[19][2]);
                }
                else
                {
                    sitldata.pitchDeg = (DATA[17][0]);
                    sitldata.rollDeg = (DATA[17][1]);
                    sitldata.yawDeg = (DATA[17][2]);
                    sitldata.pitchRate = (DATA[16][0] * rad2deg);
                    sitldata.rollRate = (DATA[16][1] * rad2deg);
                    sitldata.yawRate = (DATA[16][2] * rad2deg);

                    sitldata.heading = (DATA[18][2]);
                }

                sitldata.airspeed = ((DATA[3][5] * .44704));

                sitldata.latitude = (DATA[20][0]);
                sitldata.longitude = (DATA[20][1]);
                sitldata.altitude = (DATA[20][2] * ft2m);

                sitldata.speedN = DATA[21][3];// (DATA[3][7] * 0.44704 * Math.Sin(sitldata.heading * deg2rad));
                sitldata.speedE = -DATA[21][5];// (DATA[3][7] * 0.44704 * Math.Cos(sitldata.heading * deg2rad));

                Matrix3 dcm = new Matrix3();
                dcm.from_euler(sitldata.rollDeg * deg2rad, sitldata.pitchDeg * deg2rad, sitldata.yawDeg * deg2rad);

                // rad = tas^2 / (tan(angle) * G)
                float turnrad = (float)(((DATA[3][7] * 0.44704) * (DATA[3][7] * 0.44704)) / (float)(9.8f * Math.Tan(sitldata.rollDeg * deg2rad)));

                float gload = (float)(1 / Math.Cos(sitldata.rollDeg * deg2rad)); // calculated Gs

                // a = v^2/r
                float centripaccel = (float)((DATA[3][7] * 0.44704) * (DATA[3][7] * 0.44704)) / turnrad;

                Vector3 accel_body = dcm.transposed() * (new Vector3(0, 0, -9.8));

                Vector3 centrip_accel = new Vector3(0, centripaccel * Math.Cos(sitldata.rollDeg * deg2rad), centripaccel * Math.Sin(sitldata.rollDeg * deg2rad));

                accel_body -= centrip_accel;

                sitldata.xAccel = DATA[4][5] * 9.8;
                sitldata.yAccel = DATA[4][6] * 9.8;
                sitldata.zAccel = (0 - DATA[4][4]) * 9.8;

          //      Console.WriteLine(accel_body.ToString());
          //      Console.WriteLine("        {0} {1} {2}",sitldata.xAccel, sitldata.yAccel, sitldata.zAccel);

            }
            else if (receviedbytes == 0x64) // FG binary udp
            {
                //FlightGear
                /*

                fgIMUData imudata2 = data.ByteArrayToStructureBigEndian<fgIMUData>(0);

                if (imudata2.magic != 0x4c56414d)
                    return;

                if (imudata2.latitude == 0)
                    return;

                chkSensor.Checked = true;

#if MAVLINK10
                imu.time_usec = ((ulong)DateTime.Now.ToBinary());
#else
                imu.usec = ((ulong)DateTime.Now.ToBinary());
#endif

                imu.xacc = ((Int16)(imudata2.accelX * 9808 / 32.2));
                imu.xgyro = ((Int16)(imudata2.rateRoll * 17.453293));
                imu.xmag = 0;
                imu.yacc = ((Int16)(imudata2.accelY * 9808 / 32.2));
                imu.ygyro = ((Int16)(imudata2.ratePitch * 17.453293));
                imu.ymag = 0;
                imu.zacc = ((Int16)(imudata2.accelZ * 9808 / 32.2)); // + 1000
                imu.zgyro = ((Int16)(imudata2.rateYaw * 17.453293));
                imu.zmag = 0;

#if MAVLINK10
                gps.alt = ((int)(imudata2.altitude * ft2m * 1000));
                gps.fix_type = 3;
                gps.cog = (ushort)(Math.Atan2(imudata2.velocityE, imudata2.velocityN) * rad2deg * 100);
                gps.lat = (int)(imudata2.latitude * 1.0e7);
                gps.lon = (int)(imudata2.longitude * 1.0e7);
                gps.time_usec = ((ulong)DateTime.Now.Ticks);
                gps.vel = (ushort)(Math.Sqrt((imudata2.velocityN * imudata2.velocityN) + (imudata2.velocityE * imudata2.velocityE)) * ft2m * 100);
#else
                gps.alt = ((float)(imudata2.altitude * ft2m));
                gps.fix_type = 3;
                gps.hdg = ((float)Math.Atan2(imudata2.velocityE, imudata2.velocityN) * rad2deg);
                gps.lat = ((float)imudata2.latitude);
                gps.lon = ((float)imudata2.longitude);
                gps.usec = ((ulong)DateTime.Now.Ticks);
                gps.v = ((float)Math.Sqrt((imudata2.velocityN * imudata2.velocityN) + (imudata2.velocityE * imudata2.velocityE)) * ft2m);

#endif
                //FileStream stream = File.OpenWrite("fgdata.txt");
                //stream.Write(data, 0, receviedbytes);
                //stream.Close();
                 */
            }
            else if (receviedbytes == 662 || receviedbytes == 658) // 658 = 3.83   662 = 3.91
            {
                
                aeroin = data.ByteArrayToStructure<TDataFromAeroSimRC>(0);

                sitldata.pitchDeg = (aeroin.Model_fPitch * rad2deg);
                sitldata.rollDeg = (aeroin.Model_fRoll * -1 * rad2deg);
                sitldata.yawDeg = ((aeroin.Model_fHeading * rad2deg));

                sitldata.pitchRate = aeroin.Model_fAngVel_Body_X * rad2deg;
                sitldata.rollRate = aeroin.Model_fAngVel_Body_Y * rad2deg;
                sitldata.yawRate = -aeroin.Model_fAngVel_Body_Z * rad2deg;

                sitldata.xAccel = aeroin.Model_fAccel_Body_X; // pitch
                sitldata.yAccel = aeroin.Model_fAccel_Body_Y; // roll
                sitldata.zAccel = aeroin.Model_fAccel_Body_Z;

           //     YLScsDrawing.Drawing3d.Vector3d accel3D = HIL.QuadCopter.RPY_to_XYZ(att.roll, att.pitch, 0, -9.8); //DATA[18][2]


                sitldata.altitude = aeroin.Model_fPosZ;
                sitldata.latitude = aeroin.Model_fLatitude;
                sitldata.longitude = aeroin.Model_fLongitude;

                sitldata.speedN = aeroin.Model_fVelX;
                sitldata.speedE = aeroin.Model_fVelY;

                float xvec = aeroin.Model_fVelY - aeroin.Model_fWindVelY;
                float yvec = aeroin.Model_fVelX - aeroin.Model_fWindVelX;

                sitldata.airspeed = ((float)Math.Sqrt((yvec * yvec) + (xvec * xvec)));
            }
            else if (receviedbytes == 408)
            {
                
                FGNetFDM fdm = data.ByteArrayToStructureBigEndian<FGNetFDM>(0);

                lastfdmdata = fdm;


                sitldata.rollDeg = fdm.phi * rad2deg;
                sitldata.pitchDeg = fdm.theta * rad2deg;
                sitldata.yawDeg = fdm.psi * rad2deg;


                sitldata.rollRate = fdm.phidot * rad2deg;
                sitldata.pitchRate = fdm.thetadot * rad2deg;
                sitldata.yawRate = fdm.psidot * rad2deg;

                sitldata.xAccel = (fdm.A_X_pilot * 9.808 / 32.2); // pitch
                sitldata.yAccel =  (fdm.A_Y_pilot * 9.808 / 32.2); // roll
                sitldata.zAccel =  (fdm.A_Z_pilot / 32.2 * 9.808);

                sitldata.altitude = (fdm.altitude);
                sitldata.latitude = (fdm.latitude * rad2deg);
                sitldata.longitude = (fdm.longitude * rad2deg);

                sitldata.speedN = fdm.v_east * ft2m;
                sitldata.speedE = fdm.v_north * ft2m;

                sitldata.airspeed = fdm.vcas * 0.5144444f;//  knots to m/s

                if (RAD_JSBSim.Checked)
                    sitldata.airspeed = fdm.vcas * 0.3048f;//  fps to m/s
                 
            }
            else
            {
                log.Info("Bad Udp Packet " + receviedbytes);
                return;
            }

            // write arduimu to ardupilot
            if (CHK_quad.Checked && !RAD_aerosimrc.Checked) // quad does its own
            {
                return;
            }

            if (RAD_JSBSim.Checked && chkSensor.Checked)
            {
                byte[] buffer = new byte[1500];
                while (JSBSimSEND.Client.Available > 5)
                {
                    int read = JSBSimSEND.Client.Receive(buffer);
                }

                byte[] sitlout = new byte[16 * 8 + 1 * 4]; // 16 * double + 1 * int
                int a = 0;

                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.latitude * rad2deg), a, sitlout, a, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.longitude * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.altitude), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.psi * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.v_north * ft2m), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.v_east * ft2m), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.A_X_pilot * ft2m), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.A_Y_pilot * ft2m), 0, sitlout, a += 8, 8);

                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.A_Z_pilot * ft2m), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.phidot * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.thetadot * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.psidot * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.phi * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.theta * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.psi * rad2deg), 0, sitlout, a += 8, 8);
                Array.Copy(BitConverter.GetBytes((double)lastfdmdata.vcas * ft2m), 0, sitlout, a += 8, 8);

                //                Console.WriteLine(lastfdmdata.theta);

                Array.Copy(BitConverter.GetBytes((int)0x4c56414e), 0, sitlout, a += 8, 4);

                SITLSEND.Send(sitlout, sitlout.Length);

                return;
            }

            if (RAD_softXplanes.Checked && chkSensor.Checked)
            {
                sitldata.magic = (int)0x4c56414e;

                byte[] sendme = StructureToByteArray(sitldata);

                SITLSEND.Send(sendme, sendme.Length);
                
                return;
            }

            TimeSpan gpsspan = DateTime.Now - lastgpsupdate;

            // add gps delay
            if (gpsspan.TotalMilliseconds >= GPS_rate)
            {
                lastgpsupdate = DateTime.Now;

                // save current fix = 3
                sitl_fdmbuffer[gpsbufferindex % sitl_fdmbuffer.Length] = sitldata;

                //                Console.WriteLine((gpsbufferindex % gpsbuffer.Length) + " " + ((gpsbufferindex + (gpsbuffer.Length - 1)) % gpsbuffer.Length));

                // return buffer index + 5 = (3 + 5) = 8 % 6 = 2
                oldgps = sitl_fdmbuffer[(gpsbufferindex + (sitl_fdmbuffer.Length - 1)) % sitl_fdmbuffer.Length];

                //comPort.sendPacket(oldgps);

                gpsbufferindex++;
            }


            MAVLink.mavlink_hil_state_t hilstate = new MAVLink.mavlink_hil_state_t();

            hilstate.time_usec = (UInt64)DateTime.Now.Ticks; // microsec
            
            hilstate.lat = (int)(oldgps.latitude * 1e7); // * 1E7
            hilstate.lon = (int)(oldgps.longitude * 1e7); // * 1E7
            hilstate.alt = (int)(oldgps.altitude * 1000); // mm

         //   Console.WriteLine(hilstate.alt);

            hilstate.pitch = (float)sitldata.pitchDeg * deg2rad; // (rad)
            hilstate.pitchspeed = (float)sitldata.pitchRate * deg2rad; // (rad/s)
            hilstate.roll = (float)sitldata.rollDeg * deg2rad; // (rad)
            hilstate.rollspeed = (float)sitldata.rollRate * deg2rad; // (rad/s)
            hilstate.yaw = (float)sitldata.yawDeg * deg2rad; // (rad)
            hilstate.yawspeed = (float)sitldata.yawRate * deg2rad; // (rad/s)
            
            hilstate.vx = (short)(sitldata.speedN * 100); // m/s * 100
            hilstate.vy = (short)(sitldata.speedE * 100); // m/s * 100
            hilstate.vz = 0; // m/s * 100

            hilstate.xacc = (short)(sitldata.xAccel * 1000); // (mg)
            hilstate.yacc = (short)(sitldata.yAccel * 1000); // (mg)
            hilstate.zacc = (short)(sitldata.zAccel * 1000); // (mg)

            comPort.sendPacket(hilstate);

            //            comPort.sendPacket(oldgps);

            comPort.sendPacket(new MAVLink.mavlink_vfr_hud_t() { airspeed = (float)sitldata.airspeed } );

            MAVLink.mavlink_raw_pressure_t pres = new MAVLink.mavlink_raw_pressure_t();
            double calc = (101325 * Math.Pow(1 - 2.25577 * Math.Pow(10, -5) * sitldata.altitude, 5.25588)); // updated from valid gps
            pres.press_diff1 = (short)(int)(calc - 101325); // 0 alt is 0 pa

           // comPort.sendPacket(pres);
        }

        HIL.QuadCopter quad = new HIL.QuadCopter();

        /// <summary>
        /// 
        /// </summary>
        /// <param name="lat">rads </param>
        /// <param name="lng">rads </param>
        /// <param name="alt">m</param>
        /// <param name="roll">rads</param>
        /// <param name="pitch">rads</param>
        /// <param name="heading">rads</param>
        /// <param name="yaw">rads</param>
        /// <param name="roll_out">-1 to 1</param>
        /// <param name="pitch_out">-1 to 1</param>
        /// <param name="rudder_out">-1 to 1</param>
        /// <param name="throttle_out">0 to 1</param>
        private void updateScreenDisplay(double lat, double lng, double alt, double roll, double pitch, double heading, double yaw, double roll_out, double pitch_out, double rudder_out, double throttle_out)
        {
            try
            {
                // Update Sim stuff
                this.Invoke((MethodInvoker)delegate
                {
                    TXT_servoroll.Text = roll_out.ToString("0.000");
                    TXT_servopitch.Text = pitch_out.ToString("0.000");
                    TXT_servorudder.Text = rudder_out.ToString("0.000");
                    TXT_servothrottle.Text = throttle_out.ToString("0.000");

                    TXT_lat.Text = (lat * rad2deg).ToString("0.00000");
                    TXT_long.Text = (lng * rad2deg).ToString("0.00000");
                    TXT_alt.Text = (alt).ToString("0.00");

                    TXT_roll.Text = (roll * rad2deg).ToString("0.000");
                    TXT_pitch.Text = (pitch * rad2deg).ToString("0.000");
                    TXT_heading.Text = (heading * rad2deg).ToString("0.000");
                    TXT_yaw.Text = (yaw * rad2deg).ToString("0.000");

                    TXT_wpdist.Text = MainV2.cs.wp_dist.ToString();
                    TXT_bererror.Text = MainV2.cs.ber_error.ToString();
                    TXT_alterror.Text = MainV2.cs.alt_error.ToString();
                    TXT_WP.Text = MainV2.cs.wpno.ToString();
                    TXT_control_mode.Text = MainV2.cs.mode;
                });
            }
            catch { this.Invoke((MethodInvoker)delegate { OutputLog.AppendText("NO SIM data - exep\n"); }); }
        }

        private void processArduPilot()
        {

            bool heli = CHK_heli.Checked;

            if (CHK_quad.Checked && !RAD_aerosimrc.Checked)
            {

                double[] m = new double[4];

                m[0] = (ushort)MainV2.cs.ch1out;
                m[1] = (ushort)MainV2.cs.ch2out;
                m[2] = (ushort)MainV2.cs.ch3out;
                m[3] = (ushort)MainV2.cs.ch4out;

                if (!RAD_softFlightGear.Checked)
                {
                    lastfdmdata.latitude = DATA[20][0] * deg2rad;
                    lastfdmdata.longitude = DATA[20][1] * deg2rad;
                    lastfdmdata.altitude = (DATA[20][2]);
                    lastfdmdata.version = 999;
                }

                try
                {

                    if (lastfdmdata.version == 0)
                        return;

                    quad.update(ref m, lastfdmdata);
                }
                catch (Exception e) { log.Info("Quad hill error " + e.ToString()); }

                byte[] FlightGear = new byte[8 * 11];// StructureToByteArray(fg);

                Array.Copy(BitConverter.GetBytes((double)(m[0])), 0, FlightGear, 0, 8);
                Array.Copy(BitConverter.GetBytes((double)(m[1])), 0, FlightGear, 8, 8);
                Array.Copy(BitConverter.GetBytes((double)(m[2])), 0, FlightGear, 16, 8);
                Array.Copy(BitConverter.GetBytes((double)(m[3])), 0, FlightGear, 24, 8);
                Array.Copy(BitConverter.GetBytes((double)(quad.latitude)), 0, FlightGear, 32, 8);
                Array.Copy(BitConverter.GetBytes((double)(quad.longitude)), 0, FlightGear, 40, 8);
                Array.Copy(BitConverter.GetBytes((double)(quad.altitude * 1 / ft2m)), 0, FlightGear, 48, 8);
                Array.Copy(BitConverter.GetBytes((double)((quad.altitude - quad.ground_level) * 1 / ft2m)), 0, FlightGear, 56, 8);
                Array.Copy(BitConverter.GetBytes((double)(quad.roll * rad2deg)), 0, FlightGear, 64, 8);
                Array.Copy(BitConverter.GetBytes((double)(quad.pitch * rad2deg)), 0, FlightGear, 72, 8);
                Array.Copy(BitConverter.GetBytes((double)(quad.yaw * rad2deg)), 0, FlightGear, 80, 8);

                if (RAD_softFlightGear.Checked || RAD_softXplanes.Checked)
                {

                    Array.Reverse(FlightGear, 0, 8);
                    Array.Reverse(FlightGear, 8, 8);
                    Array.Reverse(FlightGear, 16, 8);
                    Array.Reverse(FlightGear, 24, 8);
                    Array.Reverse(FlightGear, 32, 8);
                    Array.Reverse(FlightGear, 40, 8);
                    Array.Reverse(FlightGear, 48, 8);
                    Array.Reverse(FlightGear, 56, 8);
                    Array.Reverse(FlightGear, 64, 8);
                    Array.Reverse(FlightGear, 72, 8);
                    Array.Reverse(FlightGear, 80, 8);

                }

                try
                {
                    XplanesSEND.Send(FlightGear, FlightGear.Length);
                }
                catch (Exception) { log.Info("Socket Write failed, FG closed?"); }

                updateScreenDisplay(lastfdmdata.latitude, lastfdmdata.longitude, lastfdmdata.altitude * .3048, lastfdmdata.phi, lastfdmdata.theta, lastfdmdata.psi, lastfdmdata.psi, m[0], m[1], m[2], m[3]);

                return;

            }

            float roll_out, pitch_out, throttle_out, rudder_out, collective_out;

            collective_out = 0;

            if (heli)
            {
                roll_out = (float)MainV2.cs.hilch1 / rollgain;
                pitch_out = (float)MainV2.cs.hilch2 / pitchgain;
                throttle_out = 1;
                rudder_out = (float)MainV2.cs.hilch4 / -ruddergain;

                collective_out = (float)(MainV2.cs.hilch3 - 1500) / throttlegain;
            }
            else
            {
                roll_out = (float)MainV2.cs.hilch1 / rollgain;
                pitch_out = (float)MainV2.cs.hilch2 / pitchgain;
                throttle_out = ((float)MainV2.cs.hilch3) / throttlegain;
                rudder_out = (float)MainV2.cs.hilch4 / ruddergain;

                if (RAD_aerosimrc.Checked && CHK_quad.Checked)
                {
                    throttle_out = ((float)MainV2.cs.hilch7 / 2 + 5000) / throttlegain;
                    //throttle_out = (float)(MainV2.cs.hilch7 - 1100) / throttlegain;
                }
            }


            // Limit min and max
            roll_out = Constrain(roll_out, -1, 1);
            pitch_out = Constrain(pitch_out, -1, 1);
            rudder_out = Constrain(rudder_out, -1, 1);
            throttle_out = Constrain(throttle_out, 0, 1);

            try
            {
                if (displayfull)
                {
                    // This updates the servo graphs
                    double time = (Environment.TickCount - tickStart) / 1000.0;

                    if (CHKgraphroll.Checked)
                    {
                        list.Add(time, roll_out);
                    }
                    else { list.Clear(); }
                    if (CHKgraphpitch.Checked)
                    {
                        list2.Add(time, pitch_out);
                    }
                    else { list2.Clear(); }
                    if (CHKgraphrudder.Checked)
                    {
                        list3.Add(time, rudder_out);
                    }
                    else { list3.Clear(); }
                    if (CHKgraphthrottle.Checked)
                    {
                        if (heli)
                        {
                            list4.Add(time, collective_out);
                        }
                        else
                        {
                            list4.Add(time, throttle_out);
                        }
                    }
                    else { list4.Clear(); }
                }

                if (packetssent % 10 == 0) // reduce cpu usage
                {
                    if (RAD_softXplanes.Checked)
                    {

                        bool xplane9 = !CHK_xplane10.Checked;
                        if (xplane9)
                        {
                            updateScreenDisplay(DATA[20][0] * deg2rad, DATA[20][1] * deg2rad, DATA[20][2] * .3048, DATA[18][1] * deg2rad, DATA[18][0] * deg2rad, DATA[19][2] * deg2rad, DATA[18][2] * deg2rad, roll_out, pitch_out, rudder_out, throttle_out);
                        }
                        else
                        {

                            updateScreenDisplay(DATA[20][0] * deg2rad, DATA[20][1] * deg2rad, DATA[20][2] * .3048, DATA[17][1] * deg2rad, DATA[17][0] * deg2rad, DATA[18][2] * deg2rad, DATA[17][2] * deg2rad, roll_out, pitch_out, rudder_out, throttle_out);
                        }
                    }

                    if (RAD_softFlightGear.Checked || RAD_JSBSim.Checked)
                    {
                        updateScreenDisplay(lastfdmdata.latitude, lastfdmdata.longitude, lastfdmdata.altitude * .3048, lastfdmdata.phi, lastfdmdata.theta, lastfdmdata.psi, lastfdmdata.psi, roll_out, pitch_out, rudder_out, throttle_out);
                    }

                    if (RAD_aerosimrc.Checked)
                    {
                        if (heli)
                            updateScreenDisplay(aeroin.Model_fLatitude * deg2rad, aeroin.Model_fLongitude * deg2rad, aeroin.Model_fPosZ, aeroin.Model_fRoll, aeroin.Model_fPitch, aeroin.Model_fHeading, aeroin.Model_fHeading, roll_out, pitch_out, rudder_out, collective_out);
                        else 
                            updateScreenDisplay(aeroin.Model_fLatitude * deg2rad, aeroin.Model_fLongitude * deg2rad, aeroin.Model_fPosZ, aeroin.Model_fRoll, aeroin.Model_fPitch, aeroin.Model_fHeading, aeroin.Model_fHeading, roll_out, pitch_out, rudder_out, throttle_out);
                    }
                }
            }
            catch (Exception e) { log.Info("Error updateing screen stuff " + e.ToString()); }

            packetssent++;

            if (RAD_aerosimrc.Checked)
            {
                //AeroSimRC
                byte[] AeroSimRC = new byte[4 * 8];// StructureToByteArray(fg);

                Array.Copy(BitConverter.GetBytes((double)(roll_out * REV_roll)), 0, AeroSimRC, 0, 8);
                Array.Copy(BitConverter.GetBytes((double)(pitch_out * REV_pitch * -1)), 0, AeroSimRC, 8, 8);
                Array.Copy(BitConverter.GetBytes((double)(rudder_out * REV_rudder)), 0, AeroSimRC, 16, 8);
                Array.Copy(BitConverter.GetBytes((double)((throttle_out * 2) - 1)), 0, AeroSimRC, 24, 8);

                if (heli)
                {
                    Array.Copy(BitConverter.GetBytes((double)(collective_out)), 0, AeroSimRC, 24, 8);
                }

                if (CHK_quad.Checked)
                {
                    //MainV2.cs.ch1out = 1100; 
                    //MainV2.cs.ch2out = 1100;
                    //MainV2.cs.ch3out = 1100;
                    //MainV2.cs.ch4out = 1100;

                    //ac
                    // 3 front
                    // 1 left
                    // 4 back
                    // 2 left

                    Array.Copy(BitConverter.GetBytes((double)((MainV2.cs.ch3out - 1100) / 800 * 2 - 1)), 0, AeroSimRC, 0, 8); // motor 1 = front
                    Array.Copy(BitConverter.GetBytes((double)((MainV2.cs.ch1out - 1100) / 800 * 2 - 1)), 0, AeroSimRC, 8, 8); // motor 2 = right
                    Array.Copy(BitConverter.GetBytes((double)((MainV2.cs.ch4out - 1100) / 800 * 2 - 1)), 0, AeroSimRC, 16, 8);// motor 3 = back
                    Array.Copy(BitConverter.GetBytes((double)((MainV2.cs.ch2out - 1100) / 800 * 2 - 1)), 0, AeroSimRC, 24, 8);// motor 4 = left

                }
                else
                {

                }

                try
                {
                    SimulatorRECV.SendTo(AeroSimRC, Remote);
                }
                catch { }
            }

            //JSBSim

            if (RAD_JSBSim.Checked)
            {
                roll_out = Constrain(roll_out * REV_roll, -1f, 1f);
                pitch_out = Constrain(-pitch_out * REV_pitch, -1f, 1f);
                rudder_out = Constrain(rudder_out * REV_rudder, -1f, 1f);

                throttle_out = Constrain(throttle_out, -0.0f, 1f);

                string cmd = string.Format("set fcs/aileron-cmd-norm {0}\r\nset fcs/elevator-cmd-norm {1}\r\nset fcs/rudder-cmd-norm {2}\r\nset fcs/throttle-cmd-norm {3}\r\n", roll_out, pitch_out, rudder_out, throttle_out);

                //Console.Write(cmd);
                byte[] data = System.Text.Encoding.ASCII.GetBytes(cmd);
                JSBSimSEND.Client.Send(data);
            }

            // Flightgear

            if (RAD_softFlightGear.Checked)
            {
                //if (packetssent % 2 == 0) { return; } // short supply buffer.. seems to reduce lag

                byte[] FlightGear = new byte[4 * 8];// StructureToByteArray(fg);

                Array.Copy(BitConverter.GetBytes((double)(roll_out * REV_roll)), 0, FlightGear, 0, 8);
                Array.Copy(BitConverter.GetBytes((double)(pitch_out * REV_pitch * -1)), 0, FlightGear, 8, 8);
                Array.Copy(BitConverter.GetBytes((double)(rudder_out * REV_rudder)), 0, FlightGear, 16, 8);
                Array.Copy(BitConverter.GetBytes((double)(throttle_out)), 0, FlightGear, 24, 8);

                Array.Reverse(FlightGear, 0, 8);
                Array.Reverse(FlightGear, 8, 8);
                Array.Reverse(FlightGear, 16, 8);
                Array.Reverse(FlightGear, 24, 8);

                try
                {
                    XplanesSEND.Send(FlightGear, FlightGear.Length);
                }
                catch (Exception) { log.Info("Socket Write failed, FG closed?"); }

            }

            // Xplanes

            if (RAD_softXplanes.Checked)
            {


                // sending only 1 packet instead of many.

                byte[] Xplane = new byte[5 + 36 + 36];

                if (heli)
                {
                    Xplane = new byte[5 + 36 + 36 + 36];
                }

                Xplane[0] = (byte)'D';
                Xplane[1] = (byte)'A';
                Xplane[2] = (byte)'T';
                Xplane[3] = (byte)'A';
                Xplane[4] = 0;

                Array.Copy(BitConverter.GetBytes((int)25), 0, Xplane, 5, 4); // packet index

                Array.Copy(BitConverter.GetBytes((float)throttle_out), 0, Xplane, 9, 4); // start data
                Array.Copy(BitConverter.GetBytes((float)throttle_out), 0, Xplane, 13, 4);
                Array.Copy(BitConverter.GetBytes((float)throttle_out), 0, Xplane, 17, 4);
                Array.Copy(BitConverter.GetBytes((float)throttle_out), 0, Xplane, 21, 4);

                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 25, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 29, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 33, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 37, 4);

                // NEXT ONE - control surfaces

                Array.Copy(BitConverter.GetBytes((int)11), 0, Xplane, 41, 4); // packet index

                Array.Copy(BitConverter.GetBytes((float)(pitch_out * REV_pitch)), 0, Xplane, 45, 4); // start data
                Array.Copy(BitConverter.GetBytes((float)(roll_out * REV_roll)), 0, Xplane, 49, 4);
                Array.Copy(BitConverter.GetBytes((float)(rudder_out * REV_rudder)), 0, Xplane, 53, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 57, 4);

                Array.Copy(BitConverter.GetBytes((float)(roll_out * REV_roll * 0.5)), 0, Xplane, 61, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 65, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 69, 4);
                Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, 73, 4);

                if (heli)
                {
                    Array.Copy(BitConverter.GetBytes((float)(0)), 0, Xplane, 53, 4);


                    int a = 73 + 4;
                    Array.Copy(BitConverter.GetBytes((int)39), 0, Xplane, a, 4); // packet index
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((float)(12 * collective_out)), 0, Xplane, a, 4); // main rotor 0 - 12
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((float)(12 * rudder_out)), 0, Xplane, a, 4); // tail rotor -12 - 12
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, a, 4);
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, a, 4);
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, a, 4);
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, a, 4);
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, a, 4);
                    a += 4;
                    Array.Copy(BitConverter.GetBytes((int)-999), 0, Xplane, a, 4);
                }

                try
                {
                    XplanesSEND.Send(Xplane, Xplane.Length);

                }
                catch (Exception e) { log.Info("Xplanes udp send error " + e.Message); }
            }
        }

        void setupXplane()
        {
            if (RAD_softXplanes.Checked)
            {


                // sending only 1 packet instead of many.

                byte[] Xplane = new byte[5 + 4 * 8];

                Xplane[0] = (byte)'D';
                Xplane[1] = (byte)'S';
                Xplane[2] = (byte)'E';
                Xplane[3] = (byte)'L';
                Xplane[4] = 0;

                if (CHK_xplane10.Checked)
                {
                    int pos = 5;
                    Xplane[pos] = 0x3;
                    pos += 4;
                    Xplane[pos] = 0x4;
                    pos += 4;
                    Xplane[pos] = 0x6;
                    pos += 4;
                    Xplane[pos] = 0x10;
                    pos += 4;
                    Xplane[pos] = 0x11;
                    pos += 4;
                    Xplane[pos] = 0x12;
                    pos += 4;
                    Xplane[pos] = 0x14;
                    pos += 4;
                    Xplane[pos] = 0x15;
                    pos += 4;
                }
                else
                {
                    int pos = 5;
                    Xplane[pos] = 0x3;
                    pos += 4;
                    Xplane[pos] = 0x4;
                    pos += 4;
                    Xplane[pos] = 0x6;
                    pos += 4;
                    Xplane[pos] = 0x11;
                    pos += 4;
                    Xplane[pos] = 0x12;
                    pos += 4;
                    Xplane[pos] = 0x13;
                    pos += 4;
                    Xplane[pos] = 0x14;
                    pos += 4;
                    Xplane[pos] = 0x15;
                    pos += 4;
                }

                try
                {
                    XplanesSEND.Send(Xplane, Xplane.Length);

                }
                catch (Exception e) { log.Info("Xplanes udp send error " + e.Message); }
            }
        }

        byte[] StructureToByteArray(object obj)
        {

            int len = Marshal.SizeOf(obj);

            byte[] arr = new byte[len];

            IntPtr ptr = Marshal.AllocHGlobal(len);

            Marshal.StructureToPtr(obj, ptr, true);

            Marshal.Copy(ptr, arr, 0, len);

            Marshal.FreeHGlobal(ptr);

            return arr;

        }

        private void RAD_softXplanes_CheckedChanged(object sender, EventArgs e)
        {

        }

        private void RAD_softFlightGear_CheckedChanged(object sender, EventArgs e)
        {

        }

        private void CHKREV_roll_CheckedChanged(object sender, EventArgs e)
        {
            if (CHKREV_roll.Checked)
            {
                REV_roll = -1;
            }
            else
            {
                REV_roll = 1;
            }
        }

        private void CHKREV_pitch_CheckedChanged(object sender, EventArgs e)
        {
            if (CHKREV_pitch.Checked)
            {
                REV_pitch = -1;
            }
            else
            {
                REV_pitch = 1;
            }
        }

        private void CHKREV_rudder_CheckedChanged(object sender, EventArgs e)
        {
            if (CHKREV_rudder.Checked)
            {
                REV_rudder = -1;
            }
            else
            {
                REV_rudder = 1;
            }
        }

        private void GPSrate_SelectedIndexChanged(object sender, EventArgs e)
        {
            try
            {
                GPS_rate = int.Parse(GPSrate.Text); //GPSrate.SelectedItem.ToString());
            }
            catch { }
        }

        private void OutputLog_TextChanged(object sender, EventArgs e)
        {
            if (OutputLog.TextLength >= 10000)
            {
                OutputLog.Text = OutputLog.Text.Substring(OutputLog.TextLength / 2);
            }

            // auto scroll
            OutputLog.SelectionStart = OutputLog.Text.Length;

            OutputLog.ScrollToCaret();

            OutputLog.Refresh();

        }

        private float Constrain(float value, float min, float max)
        {
            if (value > max) { value = max; }
            if (value < min) { value = min; }
            return value;
        }

        private short Constrain(double value, double min, double max)
        {
            if (value > max) { value = max; }
            if (value < min) { value = min; }
            return (short)value;
        }


        public void CreateChart(ZedGraphControl zgc)
        {
            GraphPane myPane = zgc.GraphPane;

            // Set the titles and axis labels
            myPane.Title.Text = "Servo Output";
            myPane.XAxis.Title.Text = "Time";
            myPane.YAxis.Title.Text = "Output";

            LineItem myCurve;

            myCurve = myPane.AddCurve("Roll", list, Color.Red, SymbolType.None);

            myCurve = myPane.AddCurve("Pitch", list2, Color.Blue, SymbolType.None);

            myCurve = myPane.AddCurve("Rudder", list3, Color.Green, SymbolType.None);

            myCurve = myPane.AddCurve("Throttle", list4, Color.Orange, SymbolType.None);


            // Show the x axis grid
            myPane.XAxis.MajorGrid.IsVisible = true;

            myPane.XAxis.Scale.Min = 0;
            myPane.XAxis.Scale.Max = 5;

            // Make the Y axis scale red
            //myPane.YAxis.Scale.FontSpec.FontColor = Color.Red;
            //myPane.YAxis.Title.FontSpec.FontColor = Color.Red;
            // turn off the opposite tics so the Y tics don't show up on the Y2 axis
            myPane.YAxis.MajorTic.IsOpposite = false;
            myPane.YAxis.MinorTic.IsOpposite = false;
            // Don't display the Y zero line
            myPane.YAxis.MajorGrid.IsZeroLine = true;
            // Align the Y axis labels so they are flush to the axis
            myPane.YAxis.Scale.Align = AlignP.Inside;
            // Manually set the axis range
            //myPane.YAxis.Scale.Min = -1;
            //myPane.YAxis.Scale.Max = 1;

            // Fill the axis background with a gradient
            //myPane.Chart.Fill = new Fill(Color.White, Color.LightGray, 45.0f);

            // Sample at 50ms intervals
            timer_servo_graph.Interval = 50;
            timer_servo_graph.Enabled = true;
            timer_servo_graph.Start();


            // Calculate the Axis Scale Ranges
            zgc.AxisChange();

            tickStart = Environment.TickCount;


        }

        private void timer1_Tick(object sender, EventArgs e)
        {
            // Make sure that the curvelist has at least one curve
            if (zg1.GraphPane.CurveList.Count <= 0)
                return;

            // Get the first CurveItem in the graph
            LineItem curve = zg1.GraphPane.CurveList[0] as LineItem;
            if (curve == null)
                return;

            // Get the PointPairList
            IPointListEdit list = curve.Points as IPointListEdit;
            // If this is null, it means the reference at curve.Points does not
            // support IPointListEdit, so we won't be able to modify it
            if (list == null)
                return;

            // Time is measured in seconds
            double time = (Environment.TickCount - tickStart) / 1000.0;

            // Keep the X scale at a rolling 30 second interval, with one
            // major step between the max X value and the end of the axis
            Scale xScale = zg1.GraphPane.XAxis.Scale;
            if (time > xScale.Max - xScale.MajorStep)
            {
                xScale.Max = time + xScale.MajorStep;
                xScale.Min = xScale.Max - 30.0;
            }
            // Make sure the Y axis is rescaled to accommodate actual data
            try
            {
                zg1.AxisChange();
            }
            catch { }
            // Force a redraw
            zg1.Invalidate();
        }

        private void SaveSettings_Click(object sender, EventArgs e)
        {
            xmlconfig(true);
        }

        private void GPSrate_Leave(object sender, EventArgs e)
        {
            // user entered values
            GPSrate_SelectedIndexChanged(sender, e);
        }

        private void GPSrate_KeyDown(object sender, KeyEventArgs e)
        {
            // user entered values
            GPSrate_SelectedIndexChanged(sender, e);
        }

        private void but_advsettings_Click(object sender, EventArgs e)
        {
            InputBox("IP", "Enter Sim pc IP (def 127.0.0.1)", ref simIP);

            string temp = simPort.ToString();
            InputBox("Port", "Enter Sim pc Port (def 49000)", ref temp);
            simPort = int.Parse(temp);

            temp = recvPort.ToString();
            InputBox("Port", "Enter Planner pc Port (def 49005)", ref temp);
            recvPort = int.Parse(temp);

            xmlconfig(true);

            //Microsoft.VisualBasic.Interaction.InputBox("Enter Xplane pc IP", "IP", "127.0.0.1", -1, -1);
            //Microsoft.VisualBasic.Interaction.InputBox("Enter Xplane pc IP", "IP", "127.0.0.1", -1, -1);
        }

        //from http://www.csharp-examples.net/inputbox/
        public static DialogResult InputBox(string title, string promptText, ref string value)
        {
            Form form = new Form();
            System.Windows.Forms.Label label = new System.Windows.Forms.Label();
            TextBox textBox = new TextBox();
            Button buttonOk = new Button();
            Button buttonCancel = new Button();

            form.Text = title;
            label.Text = promptText;
            textBox.Text = value;

            buttonOk.Text = "OK";
            buttonCancel.Text = "Cancel";
            buttonOk.DialogResult = DialogResult.OK;
            buttonCancel.DialogResult = DialogResult.Cancel;

            label.SetBounds(9, 20, 372, 13);
            textBox.SetBounds(12, 36, 372, 20);
            buttonOk.SetBounds(228, 72, 75, 23);
            buttonCancel.SetBounds(309, 72, 75, 23);

            label.AutoSize = true;
            textBox.Anchor = textBox.Anchor | AnchorStyles.Right;
            buttonOk.Anchor = AnchorStyles.Bottom | AnchorStyles.Right;
            buttonCancel.Anchor = AnchorStyles.Bottom | AnchorStyles.Right;

            form.ClientSize = new Size(396, 107);
            form.Controls.AddRange(new Control[] { label, textBox, buttonOk, buttonCancel });
            form.ClientSize = new Size(Math.Max(300, label.Right + 10), form.ClientSize.Height);
            form.FormBorderStyle = FormBorderStyle.FixedDialog;
            form.StartPosition = FormStartPosition.CenterScreen;
            form.MinimizeBox = false;
            form.MaximizeBox = false;
            form.AcceptButton = buttonOk;
            form.CancelButton = buttonCancel;

            DialogResult dialogResult = form.ShowDialog();
            if (dialogResult == DialogResult.OK)
            {
                value = textBox.Text;
            }
            return dialogResult;
        }

        private void CHK_quad_CheckedChanged(object sender, EventArgs e)
        {

        }

        private void BUT_startfgquad_Click(object sender, EventArgs e)
        {
            string extra = "";
            OpenFileDialog ofd = new OpenFileDialog()
            {
                Filter = "fgfs|*fgfs*"
            };
            if (File.Exists(@"C:\Program Files (x86)\FlightGear\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files (x86)\FlightGear\bin\Win32\";
                extra = " --fg-root=\"C:\\Program Files (x86)\\FlightGear\\data\"";
            }
            else if (File.Exists(@"C:\Program Files\FlightGear\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files\FlightGear\bin\Win32\";
                extra = " --fg-root=\"C:\\Program Files\\FlightGear\\data\"";
            }
            else if (File.Exists(@"C:\Program Files\FlightGear 2.4.0\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files\FlightGear 2.4.0\bin\Win32\";
                extra = " --fg-root=\"C:\\Program Files\\FlightGear 2.4.0\\data\"";
            }
            else if (File.Exists(@"C:\Program Files (x86)\FlightGear 2.4.0\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files (x86)\FlightGear 2.4.0\bin\Win32\";
                extra = " --fg-root=\"C:\\Program Files (x86)\\FlightGear 2.4.0\\data\"";
            }
            else if (File.Exists(@"/usr/games/fgfs"))
            {
                ofd.InitialDirectory = @"/usr/games";
            }

            if (File.Exists(MainV2.getConfig("fgexe")) || ofd.ShowDialog() == DialogResult.OK)
            {
                if (ofd.FileName != "")
                {
                    MainV2.config["fgexe"] = ofd.FileName;
                }
                else
                {
                    ofd.FileName = MainV2.config["fgexe"].ToString();
                }

                System.Diagnostics.Process P = new System.Diagnostics.Process();
                P.StartInfo.FileName = ofd.FileName;
                P.StartInfo.Arguments = extra + @" --geometry=400x300      --aircraft=arducopter      --native-fdm=socket,out,50,127.0.0.1,49005,udp 	 --generic=socket,in,50,127.0.0.1,49000,udp,quadhil 	 --fdm=external 	   --roll=0       --pitch=0       --wind=0@0       --turbulence=0.0       --prop:/sim/frame-rate-throttle-hz111111=30       --timeofday=noon       --shading-flat       --fog-disable       --disable-specular-highlight       --disable-skyblend       --disable-random-objects       --disable-panel       --disable-horizon-effect       --disable-clouds       --disable-anti-alias-hud ";
                try
                {
                    P.Start();
                }
                catch { CustomMessageBox.Show("Failed to start FlightGear"); }
            }
        }

        private void BUT_startfgplane_Click(object sender, EventArgs e)
        {
            string extra = "";
            OpenFileDialog ofd = new OpenFileDialog()
            {
                Filter = "fgfs|*fgfs*"
            };
            if (File.Exists(@"C:\Program Files (x86)\FlightGear\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files (x86)\FlightGear\bin\Win32\";
            }
            else if (File.Exists(@"C:\Program Files\FlightGear\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files\FlightGear\bin\Win32\";
            }
            else if (File.Exists(@"C:\Program Files\FlightGear 2.4.0\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files\FlightGear 2.4.0\bin\Win32\";
            }
            else if (File.Exists(@"C:\Program Files (x86)\FlightGear 2.4.0\bin\Win32\fgfs.exe"))
            {
                ofd.InitialDirectory = @"C:\Program Files (x86)\FlightGear 2.4.0\bin\Win32\";
            }
            else if (File.Exists(@"/usr/games/fgfs"))
            {
                ofd.InitialDirectory = @"/usr/games";
            }

            if (File.Exists(MainV2.getConfig("fgexe")) || ofd.ShowDialog() == DialogResult.OK)
            {
                if (ofd.FileName != "")
                {
                    MainV2.config["fgexe"] = ofd.FileName;
                }
                else
                {
                    ofd.FileName = MainV2.config["fgexe"].ToString();
                }

                if (!MainV2.MONO)
                {
                    extra = " --fg-root=\"" + Path.GetDirectoryName(ofd.FileName.ToLower().Replace("bin\\win32\\", "")) + "\\data\"";
                }

                System.Diagnostics.Process P = new System.Diagnostics.Process();
                P.StartInfo.FileName = ofd.FileName;
                P.StartInfo.Arguments = extra + @" --geometry=400x300         --native-fdm=socket,out,50,127.0.0.1,49005,udp 	--generic=socket,in,50,127.0.0.1,49000,udp,MAVLink		   --roll=0       --pitch=0       --wind=0@0       --turbulence=0.0       --prop:/sim/frame-rate-throttle-hz=30       --timeofday=noon       --shading-flat       --fog-disable       --disable-specular-highlight       --disable-skyblend       --disable-random-objects       --disable-panel       --disable-horizon-effect       --disable-clouds       --disable-anti-alias-hud ";
                try
                {
                    P.Start();
                }
                catch { CustomMessageBox.Show("Failed to start FlightGear"); }
            }
        }

        private void BUT_startxplane_Click(object sender, EventArgs e)
        {
            OpenFileDialog ofd = new OpenFileDialog()
            {
                Filter = "X-Plane|*X-Plane*"
            };
            try
            {
                ofd.InitialDirectory = Path.GetDirectoryName(MainV2.config["xplaneexe"].ToString());
            }
            catch { }

            if (File.Exists(MainV2.getConfig("xplaneexe")) || ofd.ShowDialog() == DialogResult.OK)
            {
                if (ofd.FileName != "")
                {
                    MainV2.config["xplaneexe"] = ofd.FileName;
                }
                else
                {
                    ofd.FileName = MainV2.config["xplaneexe"].ToString();
                }

                System.Diagnostics.Process P = new System.Diagnostics.Process();
                P.StartInfo.FileName = ofd.FileName;
                P.StartInfo.Arguments = "";
                try
                {
                    P.Start();
                }
                catch { CustomMessageBox.Show("Failed to start XPlanes"); }

            }
        }

        private void TXT_rollgain_TextChanged(object sender, EventArgs e)
        {
            updateGains();
        }

        private void TXT_pitchgain_TextChanged(object sender, EventArgs e)
        {
            updateGains();
        }

        private void TXT_ruddergain_TextChanged(object sender, EventArgs e)
        {
            updateGains();
        }

        private void TXT_throttlegain_TextChanged(object sender, EventArgs e)
        {
            updateGains();
        }

        void updateGains()
        {
            try
            {
                rollgain = int.Parse(TXT_rollgain.Text);
                pitchgain = int.Parse(TXT_pitchgain.Text);
                ruddergain = int.Parse(TXT_ruddergain.Text);
                throttlegain = int.Parse(TXT_throttlegain.Text);
            }
            catch (Exception) { this.Invoke((MethodInvoker)delegate { OutputLog.AppendText("Bad Gains!!!\n"); }); }
        }

        private void CHKdisplayall_CheckedChanged(object sender, EventArgs e)
        {
            displayfull = CHKdisplayall.Checked;

            if (displayfull)
            {
                //this.Width = 651;
                timer_servo_graph.Start();
                zg1.Visible = true;


                CHKgraphpitch.Visible = true;
                CHKgraphroll.Visible = true;
                CHKgraphrudder.Visible = true;
                CHKgraphthrottle.Visible = true;
            }
            else
            {
                //651, 457
                //this.Width = 651;
                //this.Height = 457;

                timer_servo_graph.Stop();
                zg1.Visible = false;

                CHKgraphpitch.Visible = false;
                CHKgraphroll.Visible = false;
                CHKgraphrudder.Visible = false;
                CHKgraphthrottle.Visible = false;
            }
        }

        private void Simulation_FormClosing(object sender, FormClosingEventArgs e)
        {
            timer_servo_graph.Stop();
        }
    }
}