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flightgear/src/Main/bfi.cxx

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// bfi.cxx - Big Friendly Interface implementation
//
// Written by David Megginson, started February, 2000.
//
// Copyright (C) 2000 David Megginson - david@megginson.com
//
// 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., 675 Mass Ave, Cambridge, MA 02139, USA.
//
// $Id$
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#if defined( FG_HAVE_NATIVE_SGI_COMPILERS )
# include <iostream.h>
#else
# include <iostream>
#endif
#include <simgear/constants.h>
#include <simgear/debug/logstream.hxx>
#include <simgear/ephemeris/ephemeris.hxx>
#include <simgear/math/sg_types.hxx>
#include <simgear/misc/props.hxx>
#include <simgear/timing/sg_time.hxx>
#include <Aircraft/aircraft.hxx>
#include <FDM/UIUCModel/uiuc_aircraftdir.h>
#include <Controls/controls.hxx>
#include <Autopilot/newauto.hxx>
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#include <Scenery/scenery.hxx>
#include <Time/light.hxx>
#include <Time/event.hxx>
#include <Time/sunpos.hxx>
#include <Time/tmp.hxx>
#include <Cockpit/radiostack.hxx>
#ifndef FG_OLD_WEATHER
# include <WeatherCM/FGLocalWeatherDatabase.h>
#else
# include <Weather/weather.hxx>
#endif
#include "globals.hxx"
#include "options.hxx"
#include "save.hxx"
#include "fg_init.hxx"
#include <simgear/misc/props.hxx>
FG_USING_NAMESPACE(std);
#include "bfi.hxx"
////////////////////////////////////////////////////////////////////////
// Static variables.
////////////////////////////////////////////////////////////////////////
bool FGBFI::_needReinit = false;
////////////////////////////////////////////////////////////////////////
// Local functions
////////////////////////////////////////////////////////////////////////
/**
* Initialize the BFI by binding its functions to properties.
*
* TODO: perhaps these should migrate into the individual modules
* (i.e. they should register themselves).
*/
void
FGBFI::init ()
{
FG_LOG(FG_GENERAL, FG_INFO, "Starting BFI init");
// Simulation
current_properties.tieInt("/sim/flight-model",
getFlightModel, setFlightModel);
// current_properties.tieString("/sim/aircraft",
// getAircraft, setAircraft);
// TODO: timeGMT
current_properties.tieString("/sim/time/gmt-string",
getGMTString, 0);
current_properties.tieBool("/sim/hud/visibility",
getHUDVisible, setHUDVisible);
current_properties.tieBool("/sim/panel/visibility",
getPanelVisible, setPanelVisible);
// Position
current_properties.tieString("/position/airport-id",
getTargetAirport, setTargetAirport);
current_properties.tieDouble("/position/latitude",
getLatitude, setLatitude);
current_properties.tieDouble("/position/longitude",
getLongitude, setLongitude);
current_properties.tieDouble("/position/altitude",
// getAltitude, setAltitude);
getAltitude, setAltitude, false);
current_properties.tieDouble("/position/altitude-agl",
getAGL, 0);
// Orientation
current_properties.tieDouble("/orientation/heading",
getHeading, setHeading);
current_properties.tieDouble("/orientation/heading-magnetic",
getHeadingMag, 0);
current_properties.tieDouble("/orientation/pitch",
getPitch, setPitch);
current_properties.tieDouble("/orientation/roll",
getRoll, setRoll);
// Engine
current_properties.tieDouble("/engines/engine0/rpm",
getRPM, 0);
current_properties.tieDouble("/engines/engine0/egt",
getEGT, 0);
// Velocities
current_properties.tieDouble("/velocities/airspeed",
getAirspeed, 0);
current_properties.tieDouble("/velocities/side-slip",
getSideSlip, 0);
current_properties.tieDouble("/velocities/vertical-speed",
getVerticalSpeed, 0);
current_properties.tieDouble("/velocities/speed-north",
getSpeedNorth, setSpeedNorth);
current_properties.tieDouble("/velocities/speed-east",
getSpeedEast, setSpeedEast);
current_properties.tieDouble("/velocities/speed-down",
getSpeedDown, setSpeedDown);
// Controls
current_properties.tieDouble("/controls/throttle",
getThrottle, setThrottle);
current_properties.tieDouble("/controls/mixture",
getMixture, setMixture);
current_properties.tieDouble("/controls/propellor-pitch",
getPropAdvance, setPropAdvance);
current_properties.tieDouble("/controls/flaps",
getFlaps, setFlaps);
current_properties.tieDouble("/controls/aileron",
getAileron, setAileron);
current_properties.tieDouble("/controls/rudder",
getRudder, setRudder);
current_properties.tieDouble("/controls/elevator",
getElevator, setElevator);
current_properties.tieDouble("/controls/elevator-trim",
getElevatorTrim, setElevatorTrim);
current_properties.tieDouble("/controls/brakes/all",
getBrakes, setBrakes);
current_properties.tieDouble("/controls/brakes/left",
getLeftBrake, setLeftBrake);
current_properties.tieDouble("/controls/brakes/right",
getRightBrake, setRightBrake);
current_properties.tieDouble("/controls/brakes/center",
getRightBrake, setCenterBrake);
// Autopilot
current_properties.tieBool("/autopilot/locks/altitude",
getAPAltitudeLock, setAPAltitudeLock);
current_properties.tieDouble("/autopilot/settings/altitude",
getAPAltitude, setAPAltitude);
current_properties.tieBool("/autopilot/locks/heading",
getAPHeadingLock, setAPHeadingLock);
current_properties.tieDouble("/autopilot/settings/heading",
getAPHeading, setAPHeading);
current_properties.tieDouble("/autopilot/settings/heading-magnetic",
getAPHeadingMag, setAPHeadingMag);
current_properties.tieBool("/autopilot/locks/nav1",
getAPNAV1Lock, setAPNAV1Lock);
// Radio navigation
current_properties.tieDouble("/radios/nav1/frequencies/selected",
getNAV1Freq, setNAV1Freq);
current_properties.tieDouble("/radios/nav1/frequencies/standby",
getNAV1AltFreq, setNAV1AltFreq);
current_properties.tieDouble("/radios/nav1/radials/actual",
getNAV1Radial, 0);
current_properties.tieDouble("/radios/nav1/radials/selected",
getNAV1SelRadial, setNAV1SelRadial);
current_properties.tieDouble("/radios/nav1/dme/distance",
getNAV1DistDME, 0);
current_properties.tieBool("/radios/nav1/to-flag",
getNAV1TO, 0);
current_properties.tieBool("/radios/nav1/from-flag",
getNAV1FROM, 0);
current_properties.tieBool("/radios/nav1/in-range",
getNAV1InRange, 0);
current_properties.tieBool("/radios/nav1/dme/in-range",
getNAV1DMEInRange, 0);
current_properties.tieDouble("/radios/nav2/frequencies/selected",
getNAV2Freq, setNAV2Freq);
current_properties.tieDouble("/radios/nav2/frequencies/standby",
getNAV2AltFreq, setNAV2AltFreq);
current_properties.tieDouble("/radios/nav2/radials/actual",
getNAV2Radial, 0);
current_properties.tieDouble("/radios/nav2/radials/selected",
getNAV2SelRadial, setNAV2SelRadial);
current_properties.tieDouble("/radios/nav2/dme/distance",
getNAV2DistDME, 0);
current_properties.tieBool("/radios/nav2/to-flag",
getNAV2TO, 0);
current_properties.tieBool("/radios/nav2/from-flag",
getNAV2FROM, 0);
current_properties.tieBool("/radios/nav2/in-range",
getNAV2InRange, 0);
current_properties.tieBool("/radios/nav2/dme/in-range",
getNAV2DMEInRange, 0);
current_properties.tieDouble("/radios/adf/frequencies/selected",
getADFFreq, setADFFreq);
current_properties.tieDouble("/radios/adf/frequencies/standby",
getADFAltFreq, setADFAltFreq);
current_properties.tieDouble("/radios/adf/rotation",
getADFRotation, setADFRotation);
current_properties.tieDouble("/environment/visibility",
getVisibility, setVisibility);
_needReinit = false;
FG_LOG(FG_GENERAL, FG_INFO, "Ending BFI init");
}
/**
* Reinitialize FGFS if required.
*
* Some changes (especially those in aircraft position) require that
* FGFS be reinitialized afterwards. Rather than reinitialize after
* every change, the setter methods simply set a flag so that there
* can be a single reinit at the end of the frame.
*/
void
FGBFI::update ()
{
if (_needReinit) {
reinit();
}
}
/**
* Reinitialize FGFS to use the new BFI settings.
*/
void
FGBFI::reinit ()
{
// Save the state of everything
// that's going to get clobbered
// when we reinit the subsystems.
cout << "BFI: start reinit\n";
// TODO: add more AP stuff
double elevator = getElevator();
double aileron = getAileron();
double rudder = getRudder();
double throttle = getThrottle();
double elevator_trim = getElevatorTrim();
double flaps = getFlaps();
double brake = getBrakes();
bool apHeadingLock = getAPHeadingLock();
double apHeadingMag = getAPHeadingMag();
bool apAltitudeLock = getAPAltitudeLock();
double apAltitude = getAPAltitude();
const string &targetAirport = getTargetAirport();
bool gpsLock = getGPSLock();
double gpsLatitude = getGPSTargetLatitude();
double gpsLongitude = getGPSTargetLongitude();
setTargetAirport("");
cout << "Target airport is " << current_options.get_airport_id() << endl;
fgReInitSubsystems();
// FIXME: this is wrong.
// All of these are scheduled events,
// and it should be possible to force
// them all to run once.
fgUpdateSunPos();
fgUpdateMoonPos();
cur_light_params.Update();
fgUpdateLocalTime();
fgUpdateWeatherDatabase();
fgRadioSearch();
// Restore all of the old states.
setElevator(elevator);
setAileron(aileron);
setRudder(rudder);
setThrottle(throttle);
setElevatorTrim(elevator_trim);
setFlaps(flaps);
setBrakes(brake);
setAPHeadingLock(apHeadingLock);
setAPHeadingMag(apHeadingMag);
setAPAltitudeLock(apAltitudeLock);
setAPAltitude(apAltitude);
setTargetAirport(targetAirport);
setGPSLock(gpsLock);
_needReinit = false;
cout << "BFI: end reinit\n";
}
////////////////////////////////////////////////////////////////////////
// Simulation.
////////////////////////////////////////////////////////////////////////
/**
* Return the flight model as an integer.
*
* TODO: use a string instead.
*/
int
FGBFI::getFlightModel ()
{
return current_options.get_flight_model();
}
/**
* Return the current aircraft as a string.
*/
const string
FGBFI::getAircraft ()
{
return current_options.get_aircraft();
}
/**
* Return the current aircraft directory (UIUC) as a string.
*/
const string
FGBFI::getAircraftDir ()
{
return aircraft_dir;
}
/**
* Set the flight model as an integer.
*
* TODO: use a string instead.
*/
void
FGBFI::setFlightModel (int model)
{
if (getFlightModel() != model) {
current_options.set_flight_model(model);
needReinit();
}
}
/**
* Set the current aircraft.
*/
void
FGBFI::setAircraft (const string &aircraft)
{
if (getAircraft() != aircraft) {
current_options.set_aircraft(aircraft);
needReinit();
}
}
/**
* Set the current aircraft directory (UIUC).
*/
void
FGBFI::setAircraftDir (const string &dir)
{
if (getAircraftDir() != dir) {
aircraft_dir = dir;
needReinit();
}
}
/**
* Return the current Zulu time.
*/
time_t
FGBFI::getTimeGMT ()
{
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return globals->get_time_params()->get_cur_time();
}
/**
* Set the current Zulu time.
*/
void
FGBFI::setTimeGMT (time_t time)
{
if (getTimeGMT() != time) {
// FIXME: need to update lighting
// and solar system
current_options.set_time_offset(time);
current_options.set_time_offset_type(fgOPTIONS::FG_TIME_GMT_ABSOLUTE);
globals->get_time_params()->update( cur_fdm_state->get_Longitude(),
cur_fdm_state->get_Latitude(),
globals->get_warp() );
needReinit();
}
}
/**
* Return the GMT as a string.
*/
const string &
FGBFI::getGMTString ()
{
static string out; // FIXME: not thread-safe
char buf[16];
struct tm * t = globals->get_time_params()->getGmt();
sprintf(buf, " %.2d:%.2d:%.2d",
t->tm_hour, t->tm_min, t->tm_sec);
out = buf;
return out;
}
/**
* Return true if the HUD is visible.
*/
bool
FGBFI::getHUDVisible ()
{
return current_options.get_hud_status();
}
/**
* Ensure that the HUD is visible or hidden.
*/
void
FGBFI::setHUDVisible (bool visible)
{
current_options.set_hud_status(visible);
}
/**
* Return true if the 2D panel is visible.
*/
bool
FGBFI::getPanelVisible ()
{
return current_options.get_panel_status();
}
/**
* Ensure that the 2D panel is visible or hidden.
*/
void
FGBFI::setPanelVisible (bool visible)
{
if (current_options.get_panel_status() != visible) {
current_options.toggle_panel();
}
}
////////////////////////////////////////////////////////////////////////
// Position
////////////////////////////////////////////////////////////////////////
/**
* Return the current latitude in degrees (negative for south).
*/
double
FGBFI::getLatitude ()
{
return current_aircraft.fdm_state->get_Latitude() * RAD_TO_DEG;
}
/**
* Set the current latitude in degrees (negative for south).
*/
void
FGBFI::setLatitude (double latitude)
{
if (getLatitude() != latitude) {
current_options.set_lat(latitude);
current_aircraft.fdm_state->set_Latitude(latitude * DEG_TO_RAD);
needReinit();
}
}
/**
* Return the current longitude in degrees (negative for west).
*/
double
FGBFI::getLongitude ()
{
return current_aircraft.fdm_state->get_Longitude() * RAD_TO_DEG;
}
/**
* Set the current longitude in degrees (negative for west).
*/
void
FGBFI::setLongitude (double longitude)
{
if (getLongitude() != longitude) {
current_options.set_lon(longitude);
current_aircraft.fdm_state->set_Longitude(longitude * DEG_TO_RAD);
needReinit();
}
}
/**
* Return the current altitude in feet.
*/
double
FGBFI::getAltitude ()
{
return current_aircraft.fdm_state->get_Altitude();
}
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/**
* Return the current altitude in above the terrain.
*/
double
FGBFI::getAGL ()
{
return current_aircraft.fdm_state->get_Altitude()
- (scenery.cur_elev * METER_TO_FEET);
2000-04-28 20:08:22 +00:00
}
/**
* Set the current altitude in feet.
*/
void
FGBFI::setAltitude (double altitude)
{
if (getAltitude() != altitude) {
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fgFDMForceAltitude(getFlightModel(), altitude);
current_options.set_altitude(altitude);
current_aircraft.fdm_state->set_Altitude(altitude);
}
}
////////////////////////////////////////////////////////////////////////
// Attitude
////////////////////////////////////////////////////////////////////////
/**
* Return the current heading in degrees.
*/
double
FGBFI::getHeading ()
{
return current_aircraft.fdm_state->get_Psi() * RAD_TO_DEG;
}
/**
* Return the current heading in degrees.
*/
double
FGBFI::getHeadingMag ()
{
return current_aircraft.fdm_state->get_Psi() * RAD_TO_DEG - getMagVar();
}
/**
* Set the current heading in degrees.
*/
void
FGBFI::setHeading (double heading)
{
if (getHeading() != heading) {
current_options.set_heading(heading);
current_aircraft.fdm_state->set_Euler_Angles(getRoll() * DEG_TO_RAD,
getPitch() * DEG_TO_RAD,
heading * DEG_TO_RAD);
needReinit();
}
}
/**
* Return the current pitch in degrees.
*/
double
FGBFI::getPitch ()
{
return current_aircraft.fdm_state->get_Theta() * RAD_TO_DEG;
}
/**
* Set the current pitch in degrees.
*/
void
FGBFI::setPitch (double pitch)
{
if (getPitch() != pitch) {
current_options.set_pitch(pitch);
current_aircraft.fdm_state->set_Euler_Angles(getRoll() * DEG_TO_RAD,
pitch * DEG_TO_RAD,
getHeading() * DEG_TO_RAD);
needReinit();
}
}
/**
* Return the current roll in degrees.
*/
double
FGBFI::getRoll ()
{
return current_aircraft.fdm_state->get_Phi() * RAD_TO_DEG;
}
/**
* Set the current roll in degrees.
*/
void
FGBFI::setRoll (double roll)
{
if (getRoll() != roll) {
current_options.set_roll(roll);
current_aircraft.fdm_state->set_Euler_Angles(roll * DEG_TO_RAD,
getPitch() * DEG_TO_RAD,
getHeading() * DEG_TO_RAD);
needReinit();
}
}
/**
* Return the current engine0 rpm
*/
double
FGBFI::getRPM ()
{
2000-10-02 23:07:30 +00:00
if ( current_aircraft.fdm_state->get_engine(0) != NULL ) {
return current_aircraft.fdm_state->get_engine(0)->get_RPM();
} else {
return 0.0;
}
}
/**
* Set the current engine0 rpm
*/
void
FGBFI::setRPM (double rpm)
{
if ( current_aircraft.fdm_state->get_engine(0) != NULL ) {
if (getRPM() != rpm) {
current_aircraft.fdm_state->get_engine(0)->set_RPM( rpm );
}
}
}
/**
* Return the current engine0 EGT.
*/
double
FGBFI::getEGT ()
{
if ( current_aircraft.fdm_state->get_engine(0) != NULL ) {
return current_aircraft.fdm_state->get_engine(0)->get_EGT();
}
}
////////////////////////////////////////////////////////////////////////
// Velocities
////////////////////////////////////////////////////////////////////////
/**
* Return the current airspeed in knots.
*/
double
FGBFI::getAirspeed ()
{
// FIXME: should we add speed-up?
return current_aircraft.fdm_state->get_V_calibrated_kts();
}
/**
* Return the current sideslip (FIXME: units unknown).
*/
double
FGBFI::getSideSlip ()
{
return current_aircraft.fdm_state->get_Beta();
}
/**
* Return the current climb rate in feet/minute
*/
double
FGBFI::getVerticalSpeed ()
{
// What about meters?
return current_aircraft.fdm_state->get_Climb_Rate() * 60.0;
}
/**
* Get the current north velocity (units??).
*/
double
FGBFI::getSpeedNorth ()
{
return current_aircraft.fdm_state->get_V_north();
}
/**
* Set the current north velocity (units??).
*/
void
FGBFI::setSpeedNorth (double speed)
{
if (getSpeedNorth() != speed) {
current_options.set_uBody(speed);
current_aircraft.fdm_state->set_Velocities_Local(speed,
getSpeedEast(),
getSpeedDown());
needReinit();
}
}
/**
* Get the current east velocity (units??).
*/
double
FGBFI::getSpeedEast ()
{
return current_aircraft.fdm_state->get_V_east();
}
/**
* Set the current east velocity (units??).
*/
void
FGBFI::setSpeedEast (double speed)
{
if (getSpeedEast() != speed) {
current_options.set_vBody(speed);
current_aircraft.fdm_state->set_Velocities_Local(getSpeedNorth(),
speed,
getSpeedDown());
needReinit();
}
}
/**
* Get the current down velocity (units??).
*/
double
FGBFI::getSpeedDown ()
{
return current_aircraft.fdm_state->get_V_down();
}
/**
* Set the current down velocity (units??).
*/
void
FGBFI::setSpeedDown (double speed)
{
if (getSpeedDown() != speed) {
current_options.set_wBody(speed);
current_aircraft.fdm_state->set_Velocities_Local(getSpeedNorth(),
getSpeedEast(),
speed);
needReinit();
}
}
////////////////////////////////////////////////////////////////////////
// Controls
////////////////////////////////////////////////////////////////////////
/**
* Get the throttle setting, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getThrottle ()
{
// FIXME: add engine selector
return controls.get_throttle(0);
}
/**
* Set the throttle, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setThrottle (double throttle)
{
// FIXME: allow engine selection
controls.set_throttle(0, throttle);
}
/**
* Get the fuel mixture setting, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getMixture ()
{
// FIXME: add engine selector
return controls.get_mixture(0);
}
/**
* Set the fuel mixture, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setMixture (double mixture)
{
// FIXME: allow engine selection
controls.set_mixture(0, mixture);
}
/**
* Get the propellor pitch setting, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getPropAdvance ()
{
// FIXME: add engine selector
return controls.get_prop_advance(0);
}
/**
* Set the propellor pitch, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setPropAdvance (double pitch)
{
// FIXME: allow engine selection
controls.set_prop_advance(0, pitch);
}
/**
* Get the flaps setting, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getFlaps ()
{
return controls.get_flaps();
}
/**
* Set the flaps, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setFlaps (double flaps)
{
// FIXME: clamp?
controls.set_flaps(flaps);
}
/**
* Get the aileron, from -1.0 (left) to 1.0 (right).
*/
double
FGBFI::getAileron ()
{
return controls.get_aileron();
}
/**
* Set the aileron, from -1.0 (left) to 1.0 (right).
*/
void
FGBFI::setAileron (double aileron)
{
// FIXME: clamp?
controls.set_aileron(aileron);
}
/**
* Get the rudder setting, from -1.0 (left) to 1.0 (right).
*/
double
FGBFI::getRudder ()
{
return controls.get_rudder();
}
/**
* Set the rudder, from -1.0 (left) to 1.0 (right).
*/
void
FGBFI::setRudder (double rudder)
{
// FIXME: clamp?
controls.set_rudder(rudder);
}
/**
* Get the elevator setting, from -1.0 (down) to 1.0 (up).
*/
double
FGBFI::getElevator ()
{
return controls.get_elevator();
}
/**
* Set the elevator, from -1.0 (down) to 1.0 (up).
*/
void
FGBFI::setElevator (double elevator)
{
// FIXME: clamp?
controls.set_elevator(elevator);
}
/**
* Get the elevator trim, from -1.0 (down) to 1.0 (up).
*/
double
FGBFI::getElevatorTrim ()
{
return controls.get_elevator_trim();
}
/**
* Set the elevator trim, from -1.0 (down) to 1.0 (up).
*/
void
FGBFI::setElevatorTrim (double trim)
{
// FIXME: clamp?
controls.set_elevator_trim(trim);
}
/**
* Get the highest brake setting, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getBrakes ()
{
double b1 = getCenterBrake();
double b2 = getLeftBrake();
double b3 = getRightBrake();
return (b1 > b2 ? (b1 > b3 ? b1 : b3) : (b2 > b3 ? b2 : b3));
}
/**
* Set all brakes, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setBrakes (double brake)
{
setCenterBrake(brake);
setLeftBrake(brake);
setRightBrake(brake);
}
/**
* Get the center brake, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getCenterBrake ()
{
return controls.get_brake(2);
}
/**
* Set the center brake, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setCenterBrake (double brake)
{
controls.set_brake(2, brake);
}
/**
* Get the left brake, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getLeftBrake ()
{
return controls.get_brake(0);
}
/**
* Set the left brake, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setLeftBrake (double brake)
{
controls.set_brake(0, brake);
}
/**
* Get the right brake, from 0.0 (none) to 1.0 (full).
*/
double
FGBFI::getRightBrake ()
{
return controls.get_brake(1);
}
/**
* Set the right brake, from 0.0 (none) to 1.0 (full).
*/
void
FGBFI::setRightBrake (double brake)
{
controls.set_brake(1, brake);
}
////////////////////////////////////////////////////////////////////////
// Autopilot
////////////////////////////////////////////////////////////////////////
/**
* Get the autopilot altitude lock (true=on).
*/
bool
FGBFI::getAPAltitudeLock ()
{
return current_autopilot->get_AltitudeEnabled();
}
/**
* Set the autopilot altitude lock (true=on).
*/
void
FGBFI::setAPAltitudeLock (bool lock)
{
current_autopilot->set_AltitudeMode(FGAutopilot::FG_ALTITUDE_LOCK);
current_autopilot->set_AltitudeEnabled(lock);
}
/**
* Get the autopilot target altitude in feet.
*/
double
FGBFI::getAPAltitude ()
{
return current_autopilot->get_TargetAltitude() * METER_TO_FEET;
}
/**
* Set the autopilot target altitude in feet.
*/
void
FGBFI::setAPAltitude (double altitude)
{
current_autopilot->set_TargetAltitude( altitude );
}
/**
* Get the autopilot heading lock (true=on).
*/
bool
FGBFI::getAPHeadingLock ()
{
return
(current_autopilot->get_HeadingEnabled() &&
current_autopilot->get_HeadingMode() == FGAutopilot::FG_HEADING_LOCK);
}
/**
* Set the autopilot heading lock (true=on).
*/
void
FGBFI::setAPHeadingLock (bool lock)
{
if (lock) {
// We need to do this so that
// it's possible to lock onto a
// heading other than the current
// heading.
double heading = getAPHeadingMag();
current_autopilot->set_HeadingMode(FGAutopilot::FG_HEADING_LOCK);
current_autopilot->set_HeadingEnabled(true);
setAPHeadingMag(heading);
} else if (current_autopilot->get_HeadingMode() ==
FGAutopilot::FG_HEADING_LOCK) {
current_autopilot->set_HeadingEnabled(false);
}
}
/**
* Get the autopilot target heading in degrees.
*/
double
FGBFI::getAPHeading ()
{
return current_autopilot->get_TargetHeading();
}
/**
* Set the autopilot target heading in degrees.
*/
void
FGBFI::setAPHeading (double heading)
{
current_autopilot->set_TargetHeading( heading );
}
/**
* Get the autopilot target heading in degrees.
*/
double
FGBFI::getAPHeadingMag ()
{
return current_autopilot->get_TargetHeading() - getMagVar();
}
/**
* Set the autopilot target heading in degrees.
*/
void
FGBFI::setAPHeadingMag (double heading)
{
current_autopilot->set_TargetHeading( heading + getMagVar() );
}
/**
* Return true if the autopilot is locked to NAV1.
*/
bool
FGBFI::getAPNAV1Lock ()
{
return
(current_autopilot->get_HeadingEnabled() &&
current_autopilot->get_HeadingMode() == FGAutopilot::FG_HEADING_NAV1);
}
/**
* Set the autopilot NAV1 lock.
*/
void
FGBFI::setAPNAV1Lock (bool lock)
{
if (lock) {
current_autopilot->set_HeadingMode(FGAutopilot::FG_HEADING_NAV1);
current_autopilot->set_HeadingEnabled(true);
} else if (current_autopilot->get_HeadingMode() ==
FGAutopilot::FG_HEADING_NAV1) {
current_autopilot->set_HeadingEnabled(false);
}
}
////////////////////////////////////////////////////////////////////////
// Radio navigation.
////////////////////////////////////////////////////////////////////////
double
FGBFI::getNAV1Freq ()
{
return current_radiostack->get_nav1_freq();
}
double
FGBFI::getNAV1AltFreq ()
{
return current_radiostack->get_nav1_alt_freq();
}
double
FGBFI::getNAV1Radial ()
{
return current_radiostack->get_nav1_radial();
}
double
FGBFI::getNAV1SelRadial ()
{
return current_radiostack->get_nav1_sel_radial();
}
double
FGBFI::getNAV1DistDME ()
{
return current_radiostack->get_nav1_dme_dist();
}
bool
FGBFI::getNAV1TO ()
{
if (current_radiostack->get_nav1_inrange()) {
double heading = current_radiostack->get_nav1_heading();
double radial = current_radiostack->get_nav1_radial();
double var = FGBFI::getMagVar();
if (current_radiostack->get_nav1_loc()) {
double offset = fabs(heading - radial);
return (offset<= 8.0 || offset >= 352.0);
} else {
double offset =
fabs(heading - var - radial);
return (offset <= 20.0 || offset >= 340.0);
}
} else {
return false;
}
}
bool
FGBFI::getNAV1FROM ()
{
if (current_radiostack->get_nav1_inrange()) {
double heading = current_radiostack->get_nav1_heading();
double radial = current_radiostack->get_nav1_radial();
double var = FGBFI::getMagVar();
if (current_radiostack->get_nav1_loc()) {
double offset = fabs(heading - radial);
return (offset >= 172.0 && offset<= 188.0);
} else {
double offset =
fabs(heading - var - radial);
return (offset >= 160.0 && offset <= 200.0);
}
} else {
return false;
}
}
bool
FGBFI::getNAV1InRange ()
{
return current_radiostack->get_nav1_inrange();
}
bool
FGBFI::getNAV1DMEInRange ()
{
return (current_radiostack->get_nav1_inrange() &&
current_radiostack->get_nav1_has_dme());
}
double
FGBFI::getNAV2Freq ()
{
return current_radiostack->get_nav2_freq();
}
double
FGBFI::getNAV2AltFreq ()
{
return current_radiostack->get_nav2_alt_freq();
}
double
FGBFI::getNAV2Radial ()
{
return current_radiostack->get_nav2_radial();
}
double
FGBFI::getNAV2SelRadial ()
{
return current_radiostack->get_nav2_sel_radial();
}
double
FGBFI::getNAV2DistDME ()
{
return current_radiostack->get_nav2_dme_dist();
}
bool
FGBFI::getNAV2TO ()
{
if (current_radiostack->get_nav2_inrange()) {
double heading = current_radiostack->get_nav2_heading();
double radial = current_radiostack->get_nav2_radial();
double var = FGBFI::getMagVar();
if (current_radiostack->get_nav2_loc()) {
double offset = fabs(heading - radial);
return (offset<= 8.0 || offset >= 352.0);
} else {
double offset =
fabs(heading - var - radial);
return (offset <= 20.0 || offset >= 340.0);
}
} else {
return false;
}
}
bool
FGBFI::getNAV2FROM ()
{
if (current_radiostack->get_nav2_inrange()) {
double heading = current_radiostack->get_nav2_heading();
double radial = current_radiostack->get_nav2_radial();
double var = FGBFI::getMagVar();
if (current_radiostack->get_nav2_loc()) {
double offset = fabs(heading - radial);
return (offset >= 172.0 && offset<= 188.0);
} else {
double offset =
fabs(heading - var - radial);
return (offset >= 160.0 && offset <= 200.0);
}
} else {
return false;
}
}
bool
FGBFI::getNAV2InRange ()
{
return current_radiostack->get_nav2_inrange();
}
bool
FGBFI::getNAV2DMEInRange ()
{
return (current_radiostack->get_nav2_inrange() &&
current_radiostack->get_nav2_has_dme());
}
double
FGBFI::getADFFreq ()
{
return current_radiostack->get_adf_freq();
}
double
FGBFI::getADFAltFreq ()
{
return current_radiostack->get_adf_alt_freq();
}
double
FGBFI::getADFRotation ()
{
return current_radiostack->get_adf_rotation();
}
void
FGBFI::setNAV1Freq (double freq)
{
current_radiostack->set_nav1_freq(freq);
}
void
FGBFI::setNAV1AltFreq (double freq)
{
current_radiostack->set_nav1_alt_freq(freq);
}
void
FGBFI::setNAV1SelRadial (double radial)
{
current_radiostack->set_nav1_sel_radial(radial);
}
void
FGBFI::setNAV2Freq (double freq)
{
current_radiostack->set_nav2_freq(freq);
}
void
FGBFI::setNAV2AltFreq (double freq)
{
current_radiostack->set_nav2_alt_freq(freq);
}
void
FGBFI::setNAV2SelRadial (double radial)
{
current_radiostack->set_nav2_sel_radial(radial);
}
void
FGBFI::setADFFreq (double freq)
{
current_radiostack->set_adf_freq(freq);
}
void
FGBFI::setADFAltFreq (double freq)
{
current_radiostack->set_adf_alt_freq(freq);
}
void
FGBFI::setADFRotation (double rot)
{
current_radiostack->set_adf_rotation(rot);
}
////////////////////////////////////////////////////////////////////////
// GPS
////////////////////////////////////////////////////////////////////////
/**
* Get the autopilot GPS lock (true=on).
*/
bool
FGBFI::getGPSLock ()
{
return (current_autopilot->get_HeadingEnabled() &&
(current_autopilot->get_HeadingMode() ==
FGAutopilot::FG_HEADING_WAYPOINT ));
}
/**
* Set the autopilot GPS lock (true=on).
*/
void
FGBFI::setGPSLock (bool lock)
{
if (lock) {
current_autopilot->set_HeadingMode(FGAutopilot::FG_HEADING_WAYPOINT);
current_autopilot->set_HeadingEnabled(true);
} else if (current_autopilot->get_HeadingMode() ==
FGAutopilot::FG_HEADING_WAYPOINT) {
current_autopilot->set_HeadingEnabled(false);
}
}
/**
* Get the GPS target airport code.
*/
const string &
FGBFI::getTargetAirport ()
{
// FIXME: not thread-safe
static string out;
out = current_options.get_airport_id();
return out;
}
/**
* Set the GPS target airport code.
*/
void
FGBFI::setTargetAirport (const string &airportId)
{
// cout << "setting target airport id = " << airportId << endl;
current_options.set_airport_id(airportId);
}
/**
* Get the GPS target latitude in degrees (negative for south).
*/
double
FGBFI::getGPSTargetLatitude ()
{
return current_autopilot->get_TargetLatitude();
}
/**
* Get the GPS target longitude in degrees (negative for west).
*/
double
FGBFI::getGPSTargetLongitude ()
{
return current_autopilot->get_TargetLongitude();
}
#if 0
/**
* Set the GPS target longitude in degrees (negative for west).
*/
void
FGBFI::setGPSTargetLongitude (double longitude)
{
current_autopilot->set_TargetLongitude( longitude );
}
#endif
////////////////////////////////////////////////////////////////////////
// Weather
////////////////////////////////////////////////////////////////////////
/**
* Get the current visible (units??).
*/
double
FGBFI::getVisibility ()
{
#ifndef FG_OLD_WEATHER
return WeatherDatabase->getWeatherVisibility();
#else
return current_weather.get_visibility();
#endif
}
/**
* Check whether clouds are enabled.
*/
bool
FGBFI::getClouds ()
{
return current_options.get_clouds();
}
/**
* Check the height of the clouds ASL (units?).
*/
double
FGBFI::getCloudsASL ()
{
return current_options.get_clouds_asl();
}
/**
* Set the current visibility (units??).
*/
void
FGBFI::setVisibility (double visibility)
{
#ifndef FG_OLD_WEATHER
WeatherDatabase->setWeatherVisibility(visibility);
#else
current_weather.set_visibility(visibility);
#endif
}
/**
* Switch clouds on or off.
*/
void
FGBFI::setClouds (bool clouds)
{
if (getClouds() != clouds) {
cout << "Set clouds to " << clouds << endl;
current_options.set_clouds(clouds);
needReinit();
}
}
/**
* Set the cloud height.
*/
void
FGBFI::setCloudsASL (double cloudsASL)
{
if (getCloudsASL() != cloudsASL) {
current_options.set_clouds_asl(cloudsASL);
needReinit();
}
}
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////////////////////////////////////////////////////////////////////////
// Time
////////////////////////////////////////////////////////////////////////
/**
* Return the magnetic variation
*/
double
FGBFI::getMagVar ()
{
return globals->get_mag()->get_magvar() * RAD_TO_DEG;
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}
/**
* Return the magnetic variation
*/
double
FGBFI::getMagDip ()
{
return globals->get_mag()->get_magdip() * RAD_TO_DEG;
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}
// end of bfi.cxx
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