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flightgear/src/Network/atc610x.cxx

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// atc610x.cxx -- FGFS interface to ATC 610x hardware
//
// 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., 675 Mass Ave, Cambridge, MA 02139, USA.
//
// $Id$
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include <simgear/compiler.h>
#include <stdlib.h> // atoi() atof() abs()
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
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#include <stdio.h> //snprintf
#if defined( _MSC_VER ) || defined(__MINGW32__)
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# include <io.h> //lseek, read, write
#endif
#include STL_STRING
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#include <plib/ul.h>
#include <simgear/debug/logstream.hxx>
#include <simgear/io/iochannel.hxx>
#include <simgear/math/sg_types.hxx>
#include <simgear/misc/sg_path.hxx>
#include <simgear/props/props.hxx>
#include <Scripting/NasalSys.hxx>
#include <Main/fg_props.hxx>
#include <Main/globals.hxx>
#include "atc610x.hxx"
SG_USING_STD(string);
// Lock the ATC 610 hardware
static int ATC610xLock( int fd ) {
// rewind
lseek( fd, 0, SEEK_SET );
char tmp[2];
int result = read( fd, tmp, 1 );
if ( result != 1 ) {
SG_LOG( SG_IO, SG_DEBUG, "Lock failed" );
}
return result;
}
// Write a radios command
static int ATC610xRelease( int fd ) {
// rewind
lseek( fd, 0, SEEK_SET );
char tmp[2];
tmp[0] = tmp[1] = 0;
int result = write( fd, tmp, 1 );
if ( result != 1 ) {
SG_LOG( SG_IO, SG_DEBUG, "Release failed" );
}
return result;
}
// Write a radios command
static int ATC610xSetRadios( int fd,
unsigned char data[ATC_RADIO_DISPLAY_BYTES] )
{
// rewind
lseek( fd, 0, SEEK_SET );
int result = write( fd, data, ATC_RADIO_DISPLAY_BYTES );
if ( result != ATC_RADIO_DISPLAY_BYTES ) {
SG_LOG( SG_IO, SG_DEBUG, "Write failed" );
}
return result;
}
// Write a stepper command
static int ATC610xSetStepper( int fd, unsigned char channel,
unsigned char value )
{
// rewind
lseek( fd, 0, SEEK_SET );
// Write the value
unsigned char buf[3];
buf[0] = channel;
buf[1] = value;
buf[2] = 0;
int result = write( fd, buf, 2 );
if ( result != 2 ) {
SG_LOG( SG_IO, SG_INFO, "Write failed" );
}
SG_LOG( SG_IO, SG_DEBUG,
"Sent cmd = " << (int)channel << " value = " << (int)value );
return result;
}
// Read status of last stepper written to
static unsigned char ATC610xReadStepper( int fd ) {
int result;
// rewind
lseek( fd, 0, SEEK_SET );
// Write the value
unsigned char buf[2];
result = read( fd, buf, 1 );
if ( result != 1 ) {
SG_LOG( SG_IO, SG_ALERT, "Read failed" );
exit( -1 );
}
SG_LOG( SG_IO, SG_DEBUG, "Read result = " << (int)buf[0] );
return buf[0];
}
// Turn a lamp on or off
void ATC610xSetLamp( int fd, int channel, bool value ) {
// lamp channels 0-63 are written to LampPort0, channels 64-127
// are written to LampPort1
// bits 0-6 are the lamp address
// bit 7 is the value (on/off)
int result;
// Write the value
unsigned char buf[3];
buf[0] = channel;
buf[1] = value;
buf[2] = 0;
result = write( fd, buf, 2 );
if ( result != 2 ) {
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SG_LOG( SG_IO, SG_ALERT, "Write failed" );
exit( -1 );
}
}
void FGATC610x::init_config() {
#if defined( unix ) || defined( __CYGWIN__ )
// Next check home directory for .fgfsrc.hostname file
char *envp = ::getenv( "HOME" );
if ( envp != NULL ) {
SGPath atc610x_config( envp );
atc610x_config.append( ".fgfs-atc610x.xml" );
readProperties( atc610x_config.str(), globals->get_props() );
}
#endif
}
// Open and initialize ATC 610x hardware
bool FGATC610x::open() {
if ( is_enabled() ) {
SG_LOG( SG_IO, SG_ALERT, "This shouldn't happen, but the channel "
<< "is already in use, ignoring" );
return false;
}
SG_LOG( SG_IO, SG_ALERT,
"Initializing ATC 610x hardware, please wait ..." );
// This loads the config parameters generated by "simcal"
init_config();
if ( input0_path.str().length() ) {
input0 = new FGATCInput( 0, input0_path );
input0->open();
}
if ( input1_path.str().length() ) {
input1 = new FGATCInput( 1, input1_path );
input1->open();
}
set_hz( 30 ); // default to processing requests @ 30Hz
set_enabled( true );
board = 0; // 610x uses a single board number = 0
snprintf( lock_file, 256, "/proc/atc610x/board%d/lock", board );
snprintf( lamps_file, 256, "/proc/atc610x/board%d/lamps", board );
snprintf( radios_file, 256, "/proc/atc610x/board%d/radios", board );
snprintf( stepper_file, 256, "/proc/atc610x/board%d/steppers", board );
/////////////////////////////////////////////////////////////////////
// Open the /proc files
/////////////////////////////////////////////////////////////////////
lock_fd = ::open( lock_file, O_RDWR );
if ( lock_fd == -1 ) {
SG_LOG( SG_IO, SG_ALERT, "errno = " << errno );
char msg[256];
snprintf( msg, 256, "Error opening %s", lock_file );
perror( msg );
exit( -1 );
}
lamps_fd = ::open( lamps_file, O_WRONLY );
if ( lamps_fd == -1 ) {
SG_LOG( SG_IO, SG_ALERT, "errno = " << errno );
char msg[256];
snprintf( msg, 256, "Error opening %s", lamps_file );
perror( msg );
exit( -1 );
}
radios_fd = ::open( radios_file, O_RDWR );
if ( radios_fd == -1 ) {
SG_LOG( SG_IO, SG_ALERT, "errno = " << errno );
char msg[256];
snprintf( msg, 256, "Error opening %s", radios_file );
perror( msg );
exit( -1 );
}
stepper_fd = ::open( stepper_file, O_RDWR );
if ( stepper_fd == -1 ) {
SG_LOG( SG_IO, SG_ALERT, "errno = " << errno );
char msg[256];
snprintf( msg, 256, "Error opening %s", stepper_file );
perror( msg );
exit( -1 );
}
/////////////////////////////////////////////////////////////////////
// Home the compass stepper motor
/////////////////////////////////////////////////////////////////////
SG_LOG( SG_IO, SG_ALERT,
" - Homing the compass stepper motor" );
// Lock the hardware, keep trying until we succeed
while ( ATC610xLock( lock_fd ) <= 0 );
// Send the stepper home command
ATC610xSetStepper( stepper_fd, ATC_COMPASS_CH, ATC_STEPPER_HOME );
// Release the hardware
ATC610xRelease( lock_fd );
SG_LOG( SG_IO, SG_ALERT,
" - Waiting for compass to come home." );
bool home = false;
int timeout = 900; // about 30 seconds
timeout = 0;
while ( ! home && timeout > 0 ) {
if ( timeout % 150 == 0 ) {
SG_LOG( SG_IO, SG_INFO, "waiting for compass = " << timeout );
} else {
SG_LOG( SG_IO, SG_DEBUG, "Checking if compass home ..." );
}
while ( ATC610xLock( lock_fd ) <= 0 );
unsigned char result = ATC610xReadStepper( stepper_fd );
if ( result == 0 ) {
home = true;
}
ATC610xRelease( lock_fd );
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#if defined( _MSC_VER )
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ulMilliSecondSleep(33);
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#elif defined (WIN32) && !defined(__CYGWIN__)
Sleep (33);
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#else
usleep(33);
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#endif
--timeout;
}
compass_position = 0.0;
/////////////////////////////////////////////////////////////////////
// Blank the radio display
/////////////////////////////////////////////////////////////////////
SG_LOG( SG_IO, SG_ALERT,
" - Clearing the radios displays." );
// Prepair the data
unsigned char value = 0xff;
for ( int channel = 0; channel < ATC_RADIO_DISPLAY_BYTES; ++channel ) {
radio_display_data[channel] = value;
}
// Lock the hardware, keep trying until we succeed
while ( ATC610xLock( lock_fd ) <= 0 );
// Set radio display
ATC610xSetRadios( radios_fd, radio_display_data );
ATC610xRelease( lock_fd );
/////////////////////////////////////////////////////////////////////
// Blank the lamps
/////////////////////////////////////////////////////////////////////
for ( int i = 0; i < 128; ++i ) {
ATC610xSetLamp( lamps_fd, i, false );
}
/////////////////////////////////////////////////////////////////////
// Finished initing hardware
/////////////////////////////////////////////////////////////////////
SG_LOG( SG_IO, SG_ALERT,
"Done initializing ATC 610x hardware." );
/////////////////////////////////////////////////////////////////////
// Connect up to property values
/////////////////////////////////////////////////////////////////////
mag_compass
= fgGetNode( "/instrumentation/magnetic-compass/indicated-heading-deg",
true );
dme_min = fgGetNode( "/instrumentation/dme/indicated-time-min", true );
dme_kt = fgGetNode( "/instrumentation/dme/indicated-ground-speed-kt",
true );
dme_nm = fgGetNode( "/instrumentation/dme/indicated-distance-nm", true );
dme_in_range = fgGetNode( "/instrumentation/dme/in-range", true );
adf_bus_power = fgGetNode( "/systems/electrical/outputs/adf", true );
dme_bus_power = fgGetNode( "/systems/electrical/outputs/dme", true );
navcom1_bus_power = fgGetNode( "/systems/electrical/outputs/nav[0]",
true );
navcom2_bus_power = fgGetNode( "/systems/electrical/outputs/nav[1]",
true );
xpdr_bus_power = fgGetNode( "/systems/electrical/outputs/transponder",
true );
navcom1_power_btn = fgGetNode( "/instrumentation/comm[0]/inputs/power-btn", true );
navcom2_power_btn = fgGetNode( "/instrumentation/comm[1]/inputs/power-btn", true );
com1_freq = fgGetNode( "/instrumentation/comm[0]/frequencies/selected-mhz", true );
com1_stby_freq
= fgGetNode( "/instrumentation/comm[0]/frequencies/standby-mhz", true );
com2_freq = fgGetNode( "/instrumentation/comm[1]/frequencies/selected-mhz", true );
com2_stby_freq
= fgGetNode( "/instrumentation/comm[1]/frequencies/standby-mhz", true );
nav1_freq = fgGetNode( "/instrumentation/nav[0]/frequencies/selected-mhz", true );
nav1_stby_freq
= fgGetNode( "/instrumentation/nav[0]/frequencies/standby-mhz", true );
nav1_obs = fgGetNode( "/instrumentation/nav[0]/radials/selected-deg", true );
nav2_freq = fgGetNode( "/instrumentation/nav[1]/frequencies/selected-mhz", true );
nav2_stby_freq
= fgGetNode( "/instrumentation/nav[1]/frequencies/standby-mhz", true );
nav2_obs = fgGetNode( "/instrumentation/nav[1]/radials/selected-deg", true );
adf_power_btn
= fgGetNode( "/instrumentation/kr-87/inputs/power-btn", true );
adf_vol = fgGetNode( "/instrumentation/kr-87/inputs/volume", true );
adf_adf_btn = fgGetNode( "/instrumentation/kr-87/inputs/adf-btn", true );
adf_bfo_btn = fgGetNode( "/instrumentation/kr-87/inputs/bfo-btn", true );
adf_freq = fgGetNode( "/instrumentation/kr-87/outputs/selected-khz", true );
adf_stby_freq
= fgGetNode( "/instrumentation/kr-87/outputs/standby-khz", true );
adf_stby_mode = fgGetNode( "/instrumentation/kr-87/modes/stby", true );
adf_timer_mode = fgGetNode( "/instrumentation/kr-87/modes/timer", true );
adf_count_mode = fgGetNode( "/instrumentation/kr-87/modes/count", true );
adf_flight_timer
= fgGetNode( "/instrumentation/kr-87/outputs/flight-timer", true );
adf_elapsed_timer
= fgGetNode( "/instrumentation/kr-87/outputs/elapsed-timer",
true );
adf_ant_ann = fgGetNode( "/instrumentation/kr-87/annunciators/ant", true );
adf_adf_ann = fgGetNode( "/instrumentation/kr-87/annunciators/adf", true );
adf_bfo_ann = fgGetNode( "/instrumentation/kr-87/annunciators/bfo", true );
adf_frq_ann = fgGetNode( "/instrumentation/kr-87/annunciators/frq", true );
adf_flt_ann = fgGetNode( "/instrumentation/kr-87/annunciators/flt", true );
adf_et_ann = fgGetNode( "/instrumentation/kr-87/annunciators/et", true );
inner = fgGetNode( "/instrumentation/marker-beacon/inner", true );
middle = fgGetNode( "/instrumentation/marker-beacon/middle", true );
outer = fgGetNode( "/instrumentation/marker-beacon/outer", true );
xpdr_ident_btn
= fgGetNode( "/instrumentation/kt-70/inputs/ident-btn", true );
xpdr_digit1 = fgGetNode( "/instrumentation/kt-70/inputs/digit1", true );
xpdr_digit2 = fgGetNode( "/instrumentation/kt-70/inputs/digit2", true );
xpdr_digit3 = fgGetNode( "/instrumentation/kt-70/inputs/digit3", true );
xpdr_digit4 = fgGetNode( "/instrumentation/kt-70/inputs/digit4", true );
xpdr_func_knob
= fgGetNode( "/instrumentation/kt-70/inputs/func-knob", true );
xpdr_id_code = fgGetNode( "/instrumentation/kt-70/outputs/id-code", true );
xpdr_flight_level
= fgGetNode( "/instrumentation/kt-70/outputs/flight-level", true );
xpdr_fl_ann = fgGetNode( "/instrumentation/kt-70/annunciators/fl", true );
xpdr_alt_ann = fgGetNode( "/instrumentation/kt-70/annunciators/alt", true );
xpdr_gnd_ann = fgGetNode( "/instrumentation/kt-70/annunciators/gnd", true );
xpdr_on_ann = fgGetNode( "/instrumentation/kt-70/annunciators/on", true );
xpdr_sby_ann = fgGetNode( "/instrumentation/kt-70/annunciators/sby", true );
xpdr_reply_ann
= fgGetNode( "/instrumentation/kt-70/annunciators/reply", true );
ati_bird
= fgGetNode( "/instrumentation/attitude-indicator/horizon-offset-deg",
true );
alt_press = fgGetNode( "/instrumentation/altimeter/setting-inhg", true );
adf_hdg = fgGetNode( "/instrumentation/kr-87/inputs/rotation-deg", true );
hdg_bug = fgGetNode( "/autopilot/settings/heading-bug-deg", true );
elevator_center = fgGetNode( "/input/atc610x/elevator/center", true );
elevator_min = fgGetNode( "/input/atc610x/elevator/min", true );
elevator_max = fgGetNode( "/input/atc610x/elevator/max", true );
ailerons_center = fgGetNode( "/input/atc610x/ailerons/center", true );
ailerons_min = fgGetNode( "/input/atc610x/ailerons/min", true );
ailerons_max = fgGetNode( "/input/atc610x/ailerons/max", true );
rudder_center = fgGetNode( "/input/atc610x/rudder/center", true );
rudder_min = fgGetNode( "/input/atc610x/rudder/min", true );
rudder_max = fgGetNode( "/input/atc610x/rudder/max", true );
brake_left_min = fgGetNode( "/input/atc610x/brake-left/min", true );
brake_left_max = fgGetNode( "/input/atc610x/brake-left/max", true );
brake_right_min = fgGetNode( "/input/atc610x/brake-right/min", true );
brake_right_max = fgGetNode( "/input/atc610x/brake-right/max", true );
throttle_min = fgGetNode( "/input/atc610x/throttle/min", true );
throttle_max = fgGetNode( "/input/atc610x/throttle/max", true );
mixture_min = fgGetNode( "/input/atc610x/mixture/min", true );
mixture_max = fgGetNode( "/input/atc610x/mixture/max", true );
trim_center = fgGetNode( "/input/atc610x/trim/center", true );
trim_min = fgGetNode( "/input/atc610x/trim/min", true );
trim_max = fgGetNode( "/input/atc610x/trim/max", true );
nav1vol_min = fgGetNode( "/input/atc610x/nav1vol/min", true );
nav1vol_max = fgGetNode( "/input/atc610x/nav1vol/max", true );
nav2vol_min = fgGetNode( "/input/atc610x/nav2vol/min", true );
nav2vol_max = fgGetNode( "/input/atc610x/nav2vol/max", true );
ignore_flight_controls
= fgGetNode( "/input/atc610x/ignore-flight-controls", true );
comm1_serviceable
= fgGetNode( "/instrumentation/comm[0]/serviceable", true );
comm2_serviceable
= fgGetNode( "/instrumentation/comm[1]/serviceable", true );
nav1_serviceable = fgGetNode( "/instrumentation/nav[0]/serviceable", true );
nav2_serviceable = fgGetNode( "/instrumentation/nav[1]/serviceable", true );
adf_serviceable = fgGetNode( "/instrumentation/adf/serviceable", true );
xpdr_serviceable
= fgGetNode( "/instrumentation/kt-70/inputs/serviceable", true );
dme_serviceable = fgGetNode( "/instrumentation/dme/serviceable", true );
dme_selector
= fgGetNode( "/input/atc-board/radio-switches/raw/dme-switch-position");
// default to having everything serviceable
comm1_serviceable->setBoolValue( true );
comm2_serviceable->setBoolValue( true );
nav1_serviceable->setBoolValue( true );
nav2_serviceable->setBoolValue( true );
adf_serviceable->setBoolValue( true );
xpdr_serviceable->setBoolValue( true );
dme_serviceable->setBoolValue( true );
return true;
}
/////////////////////////////////////////////////////////////////////
// Write the lights
/////////////////////////////////////////////////////////////////////
bool FGATC610x::do_lights() {
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// Marker beacons
ATC610xSetLamp( lamps_fd, 4, inner->getBoolValue() );
ATC610xSetLamp( lamps_fd, 5, middle->getBoolValue() );
ATC610xSetLamp( lamps_fd, 3, outer->getBoolValue() );
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// ADF annunciators
ATC610xSetLamp( lamps_fd, 11, adf_ant_ann->getBoolValue() ); // ANT
ATC610xSetLamp( lamps_fd, 12, adf_adf_ann->getBoolValue() ); // ADF
ATC610xSetLamp( lamps_fd, 13, adf_bfo_ann->getBoolValue() ); // BFO
ATC610xSetLamp( lamps_fd, 14, adf_frq_ann->getBoolValue() ); // FRQ
ATC610xSetLamp( lamps_fd, 15, adf_flt_ann->getBoolValue() ); // FLT
ATC610xSetLamp( lamps_fd, 16, adf_et_ann->getBoolValue() ); // ET
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// Transponder annunciators
ATC610xSetLamp( lamps_fd, 17, xpdr_fl_ann->getBoolValue() ); // FL
ATC610xSetLamp( lamps_fd, 18, xpdr_alt_ann->getBoolValue() ); // ALT
ATC610xSetLamp( lamps_fd, 19, xpdr_gnd_ann->getBoolValue() ); // GND
ATC610xSetLamp( lamps_fd, 20, xpdr_on_ann->getBoolValue() ); // ON
ATC610xSetLamp( lamps_fd, 21, xpdr_sby_ann->getBoolValue() ); // SBY
ATC610xSetLamp( lamps_fd, 22, xpdr_reply_ann->getBoolValue() ); // R
return true;
}
/////////////////////////////////////////////////////////////////////
// Update the radio display
/////////////////////////////////////////////////////////////////////
bool FGATC610x::do_radio_display() {
char digits[10];
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int i;
if ( dme_has_power() && dme_serviceable->getBoolValue() ) {
if ( dme_in_range->getBoolValue() ) {
// DME minutes
float minutes = dme_min->getFloatValue();
if ( minutes > 999 ) {
minutes = 999.0;
}
snprintf(digits, 7, "%03.0f", minutes);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[0] = digits[1] << 4 | digits[2];
radio_display_data[1] = 0xf0 | digits[0];
// DME knots
float knots = dme_kt->getFloatValue();
if ( knots > 999 ) {
knots = 999.0;
}
snprintf(digits, 7, "%03.0f", knots);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[2] = digits[1] << 4 | digits[2];
radio_display_data[3] = 0xf0 | digits[0];
// DME distance (nm)
float nm = dme_nm->getFloatValue();
if ( nm > 99 ) {
nm = 99.0;
}
snprintf(digits, 7, "%04.1f", nm);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[4] = digits[1] << 4 | digits[3];
radio_display_data[5] = 0x00 | digits[0];
// the 0x00 in the upper nibble of the 6th byte of each
// display turns on the decimal point
} else {
// out of range
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radio_display_data[0] = 0xbb;
radio_display_data[1] = 0xfb;
radio_display_data[2] = 0xbb;
radio_display_data[3] = 0xfb;
radio_display_data[4] = 0xbb;
radio_display_data[5] = 0x0b;
}
} else {
// blank dem display
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for ( i = 0; i < 6; ++i ) {
radio_display_data[i] = 0xff;
}
}
if ( navcom1_has_power() && comm1_serviceable->getBoolValue() ) {
// Com1 standby frequency
float com1_stby = com1_stby_freq->getFloatValue();
if ( fabs(com1_stby) > 999.99 ) {
com1_stby = 0.0;
}
snprintf(digits, 7, "%06.3f", com1_stby);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[6] = digits[4] << 4 | digits[5];
radio_display_data[7] = digits[1] << 4 | digits[2];
radio_display_data[8] = 0xf0 | digits[0];
// Com1 in use frequency
float com1 = com1_freq->getFloatValue();
if ( fabs(com1) > 999.99 ) {
com1 = 0.0;
}
snprintf(digits, 7, "%06.3f", com1);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[9] = digits[4] << 4 | digits[5];
radio_display_data[10] = digits[1] << 4 | digits[2];
radio_display_data[11] = 0x00 | digits[0];
// the 0x00 in the upper nibble of the 6th byte of each display
// turns on the decimal point
} else {
radio_display_data[6] = 0xff;
radio_display_data[7] = 0xff;
radio_display_data[8] = 0xff;
radio_display_data[9] = 0xff;
radio_display_data[10] = 0xff;
radio_display_data[11] = 0xff;
}
if ( navcom2_has_power() && comm2_serviceable->getBoolValue() ) {
// Com2 standby frequency
float com2_stby = com2_stby_freq->getFloatValue();
if ( fabs(com2_stby) > 999.99 ) {
com2_stby = 0.0;
}
snprintf(digits, 7, "%06.3f", com2_stby);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[18] = digits[4] << 4 | digits[5];
radio_display_data[19] = digits[1] << 4 | digits[2];
radio_display_data[20] = 0xf0 | digits[0];
// Com2 in use frequency
float com2 = com2_freq->getFloatValue();
if ( fabs(com2) > 999.99 ) {
com2 = 0.0;
}
snprintf(digits, 7, "%06.3f", com2);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[21] = digits[4] << 4 | digits[5];
radio_display_data[22] = digits[1] << 4 | digits[2];
radio_display_data[23] = 0x00 | digits[0];
// the 0x00 in the upper nibble of the 6th byte of each display
// turns on the decimal point
} else {
radio_display_data[18] = 0xff;
radio_display_data[19] = 0xff;
radio_display_data[20] = 0xff;
radio_display_data[21] = 0xff;
radio_display_data[22] = 0xff;
radio_display_data[23] = 0xff;
}
if ( navcom1_has_power() && nav1_serviceable->getBoolValue() ) {
// Nav1 standby frequency
float nav1_stby = nav1_stby_freq->getFloatValue();
if ( fabs(nav1_stby) > 999.99 ) {
nav1_stby = 0.0;
}
snprintf(digits, 7, "%06.2f", nav1_stby);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[12] = digits[4] << 4 | digits[5];
radio_display_data[13] = digits[1] << 4 | digits[2];
radio_display_data[14] = 0xf0 | digits[0];
// Nav1 in use frequency
float nav1 = nav1_freq->getFloatValue();
if ( fabs(nav1) > 999.99 ) {
nav1 = 0.0;
}
snprintf(digits, 7, "%06.2f", nav1);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[15] = digits[4] << 4 | digits[5];
radio_display_data[16] = digits[1] << 4 | digits[2];
radio_display_data[17] = 0x00 | digits[0];
// the 0x00 in the upper nibble of the 6th byte of each display
// turns on the decimal point
} else {
radio_display_data[12] = 0xff;
radio_display_data[13] = 0xff;
radio_display_data[14] = 0xff;
radio_display_data[15] = 0xff;
radio_display_data[16] = 0xff;
radio_display_data[17] = 0xff;
}
if ( navcom2_has_power() && nav2_serviceable->getBoolValue() ) {
// Nav2 standby frequency
float nav2_stby = nav2_stby_freq->getFloatValue();
if ( fabs(nav2_stby) > 999.99 ) {
nav2_stby = 0.0;
}
snprintf(digits, 7, "%06.2f", nav2_stby);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[24] = digits[4] << 4 | digits[5];
radio_display_data[25] = digits[1] << 4 | digits[2];
radio_display_data[26] = 0xf0 | digits[0];
// Nav2 in use frequency
float nav2 = nav2_freq->getFloatValue();
if ( fabs(nav2) > 999.99 ) {
nav2 = 0.0;
}
snprintf(digits, 7, "%06.2f", nav2);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[27] = digits[4] << 4 | digits[5];
radio_display_data[28] = digits[1] << 4 | digits[2];
radio_display_data[29] = 0x00 | digits[0];
// the 0x00 in the upper nibble of the 6th byte of each display
// turns on the decimal point
} else {
radio_display_data[24] = 0xff;
radio_display_data[25] = 0xff;
radio_display_data[26] = 0xff;
radio_display_data[27] = 0xff;
radio_display_data[28] = 0xff;
radio_display_data[29] = 0xff;
}
// ADF standby frequency / timer
if ( adf_has_power() && adf_serviceable->getBoolValue() ) {
if ( adf_stby_mode->getIntValue() == 0 ) {
// frequency
float adf_stby = adf_stby_freq->getFloatValue();
if ( fabs(adf_stby) > 1799 ) {
adf_stby = 1799;
}
2002-07-05 13:56:46 +00:00
snprintf(digits, 7, "%04.0f", adf_stby);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[30] = digits[3] << 4 | 0x0f;
radio_display_data[31] = digits[1] << 4 | digits[2];
if ( digits[0] == 0 ) {
radio_display_data[32] = 0xff;
} else {
radio_display_data[32] = 0xf0 | digits[0];
}
} else {
// timer
double time;
int hours, min, sec;
if ( adf_timer_mode->getIntValue() == 0 ) {
time = adf_flight_timer->getDoubleValue();
} else {
time = adf_elapsed_timer->getDoubleValue();
}
// cout << time << endl;
hours = (int)(time / 3600.0);
time -= hours * 3600.00;
min = (int)(time / 60.0);
time -= min * 60.0;
sec = (int)time;
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int big, little;
if ( hours > 0 ) {
big = hours;
if ( big > 99 ) {
big = 99;
}
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little = min;
} else {
big = min;
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little = sec;
}
if ( big > 99 ) {
big = 99;
}
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// cout << big << ":" << little << endl;
2002-07-05 13:56:46 +00:00
snprintf(digits, 7, "%02d%02d", big, little);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[30] = digits[2] << 4 | digits[3];
radio_display_data[31] = digits[0] << 4 | digits[1];
radio_display_data[32] = 0xff;
}
// ADF in use frequency
float adf = adf_freq->getFloatValue();
if ( fabs(adf) > 1799 ) {
adf = 1799;
}
2002-07-05 13:56:46 +00:00
snprintf(digits, 7, "%04.0f", adf);
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[33] = digits[2] << 4 | digits[3];
if ( digits[0] == 0 ) {
radio_display_data[34] = 0xf0 | digits[1];
} else {
radio_display_data[34] = digits[0] << 4 | digits[1];
}
if ( adf_stby_mode->getIntValue() == 0 ) {
radio_display_data[35] = 0xff;
} else {
radio_display_data[35] = 0x0f;
}
} else {
radio_display_data[30] = 0xff;
radio_display_data[31] = 0xff;
radio_display_data[32] = 0xff;
radio_display_data[33] = 0xff;
radio_display_data[34] = 0xff;
radio_display_data[35] = 0xff;
}
// Transponder code and flight level
if ( xpdr_has_power() && xpdr_serviceable->getBoolValue() ) {
if ( xpdr_func_knob->getIntValue() == 2 ) {
// test mode
radio_display_data[36] = 8 << 4 | 8;
radio_display_data[37] = 8 << 4 | 8;
radio_display_data[38] = 0xff;
radio_display_data[39] = 8 << 4 | 0x0f;
radio_display_data[40] = 8 << 4 | 8;
} else {
// other on modes
int id_code = xpdr_id_code->getIntValue();
int place = 1000;
for ( i = 0; i < 4; ++i ) {
digits[i] = id_code / place;
id_code -= digits[i] * place;
place /= 10;
}
radio_display_data[36] = digits[2] << 4 | digits[3];
radio_display_data[37] = digits[0] << 4 | digits[1];
radio_display_data[38] = 0xff;
if ( xpdr_func_knob->getIntValue() == 3 ||
xpdr_func_knob->getIntValue() == 5 )
{
// do flight level display
snprintf(digits, 7, "%03d", xpdr_flight_level->getIntValue() );
for ( i = 0; i < 6; ++i ) {
digits[i] -= '0';
}
radio_display_data[39] = digits[2] << 4 | 0x0f;
radio_display_data[40] = digits[0] << 4 | digits[1];
} else {
// blank flight level display
radio_display_data[39] = 0xff;
radio_display_data[40] = 0xff;
}
}
} else {
// off
radio_display_data[36] = 0xff;
radio_display_data[37] = 0xff;
radio_display_data[38] = 0xff;
radio_display_data[39] = 0xff;
radio_display_data[40] = 0xff;
}
ATC610xSetRadios( radios_fd, radio_display_data );
return true;
}
/////////////////////////////////////////////////////////////////////
// Drive the stepper motors
/////////////////////////////////////////////////////////////////////
bool FGATC610x::do_steppers() {
float diff = mag_compass->getFloatValue() - compass_position;
while ( diff < -180.0 ) { diff += 360.0; }
while ( diff > 180.0 ) { diff -= 360.0; }
int steps = (int)(diff * 4);
// cout << "steps = " << steps << endl;
if ( steps > 4 ) { steps = 4; }
if ( steps < -4 ) { steps = -4; }
if ( abs(steps) > 0 ) {
unsigned char cmd = 0x80; // stepper command
if ( steps > 0 ) {
cmd |= 0x20; // go up
} else {
cmd |= 0x00; // go down
}
cmd |= abs(steps);
// sync compass_position with hardware position
compass_position += (float)steps / 4.0;
ATC610xSetStepper( stepper_fd, ATC_COMPASS_CH, cmd );
}
return true;
}
bool FGATC610x::process() {
// Lock the hardware, skip if it's not ready yet
if ( ATC610xLock( lock_fd ) > 0 ) {
// process the ATC inputs
if ( input0 != NULL ) {
input0->process();
}
if ( input1 != NULL ) {
input1->process();
}
// run our custom nasal script. This is a layer above the raw
// hardware inputs. It handles situations where there isn't a
// direct 1-1 linear mapping between ATC functionality and FG
// functionality, and handles situations where FG expects more
// functionality from the interface than the ATC hardware can
// directly provide.
FGNasalSys *n = (FGNasalSys*)globals->get_subsystem("nasal");
bool result = n->parseAndRun( "atcsim.do_hardware()" );
if ( !result ) {
SG_LOG( SG_GENERAL, SG_ALERT,
"do_atcflightsim_hardware() failed!" );
}
do_lights();
do_radio_display();
do_steppers();
ATC610xRelease( lock_fd );
return true;
} else {
return false;
}
}
bool FGATC610x::close() {
return true;
}