// native_gui.cxx -- FGFS external gui data export class
//
// Written by Curtis Olson, started January 2002.
//
// Copyright (C) 2002 Curtis L. Olson - http://www.flightgear.org/~curt
//
// This program 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 2 of the
// License, or (at your option) any later version.
//
// This program 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 this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
//
// $Id$
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include <simgear/debug/logstream.hxx>
#include <simgear/io/lowlevel.hxx> // endian tests
#include <simgear/io/iochannel.hxx>
#include <simgear/timing/sg_time.hxx>
#include <FDM/flight.hxx>
#include <Time/tmp.hxx>
#include <Main/fg_props.hxx>
#include <Main/globals.hxx>
#include <Scenery/scenery.hxx>
#include "native_gui.hxx"
// FreeBSD works better with this included last ... (?)
#if defined(WIN32) && !defined(__CYGWIN__)
# include <windows.h>
#else
# include <netinet/in.h> // htonl() ntohl()
#endif
// #define FG_USE_NETWORK_BYTE_ORDER
#if defined( FG_USE_NETWORK_BYTE_ORDER )
// The function htond is defined this way due to the way some
// processors and OSes treat floating point values. Some will raise
// an exception whenever a "bad" floating point value is loaded into a
// floating point register. Solaris is notorious for this, but then
// so is LynxOS on the PowerPC. By translating the data in place,
// there is no need to load a FP register with the "corruped" floating
// point value. By doing the BIG_ENDIAN test, I can optimize the
// routine for big-endian processors so it can be as efficient as
// possible
static void htond (double &x)
{
if ( sgIsLittleEndian() ) {
int *Double_Overlay;
int Holding_Buffer;
Double_Overlay = (int *) &x;
Holding_Buffer = Double_Overlay [0];
Double_Overlay [0] = htonl (Double_Overlay [1]);
Double_Overlay [1] = htonl (Holding_Buffer);
} else {
return;
}
}
static void htonf (float &x)
{
if ( sgIsLittleEndian() ) {
int *Float_Overlay;
int Holding_Buffer;
Float_Overlay = (int *) &x;
Holding_Buffer = Float_Overlay [0];
Float_Overlay [0] = htonl (Holding_Buffer);
} else {
return;
}
}
#endif
FGNativeGUI::FGNativeGUI() {
}
FGNativeGUI::~FGNativeGUI() {
}
// open hailing frequencies
bool FGNativeGUI::open() {
if ( is_enabled() ) {
SG_LOG( SG_IO, SG_ALERT, "This shouldn't happen, but the channel "
<< "is already in use, ignoring" );
return false;
}
SGIOChannel *io = get_io_channel();
if ( ! io->open( get_direction() ) ) {
SG_LOG( SG_IO, SG_ALERT, "Error opening channel communication layer." );
return false;
}
set_enabled( true );
cur_fdm_state->_set_Sea_level_radius( SG_EQUATORIAL_RADIUS_FT );
return true;
}
void FGProps2NetGUI( FGNetGUI *net ) {
static SGPropertyNode *nav_freq
= fgGetNode("/instrumentation/nav/frequencies/selected-mhz", true);
static SGPropertyNode *nav_target_radial
= fgGetNode("/instrumentation/nav/radials/target-radial-deg", true);
static SGPropertyNode *nav_inrange
= fgGetNode("/instrumentation/nav/in-range", true);
static SGPropertyNode *nav_loc
= fgGetNode("/instrumentation/nav/nav-loc", true);
static SGPropertyNode *nav_gs_dist_signed
= fgGetNode("/instrumentation/nav/gs-distance", true);
static SGPropertyNode *nav_loc_dist
= fgGetNode("/instrumentation/nav/nav-distance", true);
static SGPropertyNode *nav_reciprocal_radial
= fgGetNode("/instrumentation/nav/radials/reciprocal-radial-deg", true);
static SGPropertyNode *nav_gs_deflection
= fgGetNode("/instrumentation/nav/gs-needle-deflection", true);
unsigned int i;
// Version sanity checking
net->version = FG_NET_GUI_VERSION;
// Aero parameters
net->longitude = cur_fdm_state->get_Longitude();
net->latitude = cur_fdm_state->get_Latitude();
net->altitude = cur_fdm_state->get_Altitude() * SG_FEET_TO_METER;
net->phi = cur_fdm_state->get_Phi();
net->theta = cur_fdm_state->get_Theta();
net->psi = cur_fdm_state->get_Psi();
// Velocities
net->vcas = cur_fdm_state->get_V_calibrated_kts();
net->climb_rate = cur_fdm_state->get_Climb_Rate();
// Consumables
net->num_tanks = FGNetGUI::FG_MAX_TANKS;
for ( i = 0; i < net->num_tanks; ++i ) {
SGPropertyNode *node = fgGetNode("/consumables/fuel/tank", i, true);
net->fuel_quantity[i] = node->getDoubleValue("level-gal_us");
}
// Environment
net->cur_time = globals->get_time_params()->get_cur_time();
net->warp = globals->get_warp();
net->ground_elev = cur_fdm_state->get_Runway_altitude_m();
// Approach
net->tuned_freq = nav_freq->getDoubleValue();
net->nav_radial = nav_target_radial->getDoubleValue();
net->in_range = nav_inrange->getBoolValue();
if ( nav_loc->getBoolValue() ) {
// is an ILS
net->dist_nm
= nav_gs_dist_signed->getDoubleValue()
* SG_METER_TO_NM;
} else {
// is a VOR
net->dist_nm = nav_loc_dist->getDoubleValue()
* SG_METER_TO_NM;
}
net->course_deviation_deg
= nav_reciprocal_radial->getDoubleValue()
- nav_target_radial->getDoubleValue();
if ( net->course_deviation_deg < -1000.0
|| net->course_deviation_deg > 1000.0 )
{
// Sanity check ...
net->course_deviation_deg = 0.0;
}
while ( net->course_deviation_deg > 180.0 ) {
net->course_deviation_deg -= 360.0;
}
while ( net->course_deviation_deg < -180.0 ) {
net->course_deviation_deg += 360.0;
}
if ( fabs(net->course_deviation_deg) > 90.0 )
net->course_deviation_deg
= ( net->course_deviation_deg<0.0
? -net->course_deviation_deg - 180.0
: -net->course_deviation_deg + 180.0 );
if ( nav_loc->getBoolValue() ) {
// is an ILS
net->gs_deviation_deg
= nav_gs_deflection->getDoubleValue()
/ 5.0;
} else {
// is an ILS
net->gs_deviation_deg = -9999.0;
}
#if defined( FG_USE_NETWORK_BYTE_ORDER )
// Convert the net buffer to network format
net->version = htonl(net->version);
htond(net->longitude);
htond(net->latitude);
htonf(net->altitude);
htonf(net->phi);
htonf(net->theta);
htonf(net->psi);
htonf(net->vcas);
htonf(net->climb_rate);
for ( i = 0; i < net->num_tanks; ++i ) {
htonf(net->fuel_quantity[i]);
}
net->num_tanks = htonl(net->num_tanks);
net->cur_time = htonl( net->cur_time );
net->warp = htonl( net->warp );
net->ground_elev = htonl( net->ground_elev );
htonf(net->tuned_freq);
htonf(net->nav_radial);
net->in_range = htonl( net->in_range );
htonf(net->dist_nm);
htonf(net->course_deviation_deg);
htonf(net->gs_deviation_deg);
#endif
}
void FGNetGUI2Props( FGNetGUI *net ) {
unsigned int i;
#if defined( FG_USE_NETWORK_BYTE_ORDER )
// Convert to the net buffer from network format
net->version = ntohl(net->version);
htond(net->longitude);
htond(net->latitude);
htonf(net->altitude);
htonf(net->phi);
htonf(net->theta);
htonf(net->psi);
htonf(net->vcas);
htonf(net->climb_rate);
net->num_tanks = htonl(net->num_tanks);
for ( i = 0; i < net->num_tanks; ++i ) {
htonf(net->fuel_quantity[i]);
}
net->cur_time = ntohl(net->cur_time);
net->warp = ntohl(net->warp);
net->ground_elev = htonl( net->ground_elev );
htonf(net->tuned_freq);
htonf(net->nav_radial);
net->in_range = htonl( net->in_range );
htonf(net->dist_nm);
htonf(net->course_deviation_deg);
htonf(net->gs_deviation_deg);
#endif
if ( net->version == FG_NET_GUI_VERSION ) {
// cout << "pos = " << net->longitude << " " << net->latitude << endl;
// cout << "sea level rad = " << cur_fdm_state->get_Sea_level_radius()
// << endl;
cur_fdm_state->_updateGeodeticPosition( net->latitude,
net->longitude,
net->altitude
* SG_METER_TO_FEET );
cur_fdm_state->_set_Euler_Angles( net->phi,
net->theta,
net->psi );
cur_fdm_state->_set_V_calibrated_kts( net->vcas );
cur_fdm_state->_set_Climb_Rate( net->climb_rate );
for (i = 0; i < net->num_tanks; ++i ) {
SGPropertyNode * node
= fgGetNode("/consumables/fuel/tank", i, true);
node->setDoubleValue("level-gal_us", net->fuel_quantity[i] );
}
if ( net->cur_time ) {
fgSetLong("/sim/time/cur-time-override", net->cur_time);
}
globals->set_warp( net->warp );
// Approach
fgSetDouble( "/instrumentation/nav[0]/frequencies/selected-mhz",
net->tuned_freq );
fgSetBool( "/instrumentation/nav[0]/in-range", net->in_range );
fgSetDouble( "/instrumentation/dme/indicated-distance-nm", net->dist_nm );
fgSetDouble( "/instrumentation/nav[0]/heading-needle-deflection",
net->course_deviation_deg );
fgSetDouble( "/instrumentation/nav[0]/gs-needle-deflection",
net->gs_deviation_deg );
} else {
SG_LOG( SG_IO, SG_ALERT,
"Error: version mismatch in FGNetNativeGUI2Props()" );
SG_LOG( SG_IO, SG_ALERT,
"\tread " << net->version << " need " << FG_NET_GUI_VERSION );
SG_LOG( SG_IO, SG_ALERT,
"\tNeed to upgrade net_fdm.hxx and recompile." );
}
}
// process work for this port
bool FGNativeGUI::process() {
SGIOChannel *io = get_io_channel();
int length = sizeof(buf);
if ( get_direction() == SG_IO_OUT ) {
// cout << "size of cur_fdm_state = " << length << endl;
FGProps2NetGUI( &buf );
if ( ! io->write( (char *)(& buf), length ) ) {
SG_LOG( SG_IO, SG_ALERT, "Error writing data." );
return false;
}
} else if ( get_direction() == SG_IO_IN ) {
if ( io->get_type() == sgFileType ) {
if ( io->read( (char *)(& buf), length ) == length ) {
SG_LOG( SG_IO, SG_DEBUG, "Success reading data." );
FGNetGUI2Props( &buf );
}
} else {
while ( io->read( (char *)(& buf), length ) == length ) {
SG_LOG( SG_IO, SG_DEBUG, "Success reading data." );
FGNetGUI2Props( &buf );
}
}
}
return true;
}
// close the channel
bool FGNativeGUI::close() {
SGIOChannel *io = get_io_channel();
set_enabled( false );
if ( ! io->close() ) {
return false;
}
return true;
}