// ATC-Outputs.hxx -- Translate FGFS properties to ATC hardware outputs. // // Written by Curtis Olson, started November 2004. // // Copyright (C) 2004 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 #endif #include #if defined( unix ) || defined( __CYGWIN__ ) # include # include # include #endif #include #include #include STL_STRING #include #include #include
#include "ATC-Outputs.hxx" SG_USING_STD(string); // Lock the ATC hardware static int ATCLock( int fd ) { #if defined( unix ) || defined( __CYGWIN__ ) // 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; #else return -1; #endif } // Release the ATC hardware static int ATCRelease( int fd ) { #if defined( unix ) || defined( __CYGWIN__ ) // 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; #else return -1; #endif } // Constructor: The _board parameter specifies which board to // reference. Possible values are 0 or 1. The _config_file parameter // specifies the location of the output config file (xml) FGATCOutput::FGATCOutput( const int _board, const SGPath &_config_file ) : is_open(false), lamps_out_node(NULL), radio_display_node(NULL), steppers_node(NULL) { board = _board; config = _config_file; } // Write a radios command static int ATCSetRadios( int fd, unsigned char data[ATC_RADIO_DISPLAY_BYTES] ) { #if defined( unix ) || defined( __CYGWIN__ ) // 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; #else return -1; #endif } // Write a stepper command static int ATCSetStepper( int fd, unsigned char channel, unsigned char value ) { #if defined( unix ) || defined( __CYGWIN__ ) // 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; #else return -1; #endif } // Read status of last stepper written to static unsigned char ATCReadStepper( int fd ) { #if defined( unix ) || defined( __CYGWIN__ ) 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]; #else return 0; #endif } // Turn a lamp on or off void ATCSetLamp( int fd, int channel, bool value ) { #if defined( unix ) || defined( __CYGWIN__ ) // 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 ) { SG_LOG( SG_IO, SG_ALERT, "Write failed" ); exit( -1 ); } #endif } void FGATCOutput::init_config() { #if defined( unix ) || defined( __CYGWIN__ ) if ( config.str()[0] != '/' ) { // not an absolute path, prepend the standard location SGPath tmp; char *envp = ::getenv( "HOME" ); if ( envp != NULL ) { tmp = envp; tmp.append( ".atcflightsim" ); tmp.append( config.str() ); config = tmp; } } readProperties( config.str(), globals->get_props() ); #endif } // Open and initialize the ATC hardware bool FGATCOutput::open( int lock_fd ) { if ( is_open ) { SG_LOG( SG_IO, SG_ALERT, "This board is already open for output! " << board ); return false; } // This loads the config parameters generated by "simcal" init_config(); SG_LOG( SG_IO, SG_ALERT, "Initializing ATC output hardware, please wait ..." ); snprintf( lamps_file, 256, "/proc/atcflightsim/board%d/lamps", board ); snprintf( radio_display_file, 256, "/proc/atcflightsim/board%d/radios", board ); snprintf( stepper_file, 256, "/proc/atcflightsim/board%d/steppers", board ); #if defined( unix ) || defined( __CYGWIN__ ) ///////////////////////////////////////////////////////////////////// // Open the /proc files ///////////////////////////////////////////////////////////////////// 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 ); } radio_display_fd = ::open( radio_display_file, O_RDWR ); if ( radio_display_fd == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error opening %s", radio_display_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 ); } #endif #ifdef ATCFLIGHTSIM_HAVE_COMPASS ///////////////////////////////////////////////////////////////////// // 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 ( ATCLock( lock_fd ) <= 0 ); // Send the stepper home command ATCSetStepper( stepper_fd, ATC_COMPASS_CH, ATC_STEPPER_HOME ); // Release the hardware ATCRelease( 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 ( ATCLock( lock_fd ) <= 0 ); unsigned char result = ATCReadStepper( stepper_fd ); if ( result == 0 ) { home = true; } ATCRelease( lock_fd ); #if defined( _MSC_VER ) ulMilliSecondSleep(33); #elif defined (WIN32) && !defined(__CYGWIN__) Sleep (33); #else usleep(33); #endif --timeout; } compass_position = 0.0; #endif ///////////////////////////////////////////////////////////////////// // 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 ( ATCLock( lock_fd ) <= 0 ); // Set radio display ATCSetRadios( radio_display_fd, radio_display_data ); ATCRelease( lock_fd ); ///////////////////////////////////////////////////////////////////// // Blank the lamps ///////////////////////////////////////////////////////////////////// for ( int i = 0; i < 128; ++i ) { ATCSetLamp( lamps_fd, i, false ); } ///////////////////////////////////////////////////////////////////// // Finished initing hardware ///////////////////////////////////////////////////////////////////// SG_LOG( SG_IO, SG_ALERT, "Done initializing ATC output hardware." ); is_open = true; ///////////////////////////////////////////////////////////////////// // Connect up to property values ///////////////////////////////////////////////////////////////////// char base_name[256]; snprintf( base_name, 256, "/output/atc-board[%d]/lamps", board ); lamps_out_node = fgGetNode( base_name ); snprintf( base_name, 256, "/output/atc-board[%d]/radio-display", board ); radio_display_node = fgGetNode( base_name ); snprintf( base_name, 256, "/output/atc-board[%d]/steppers", board ); steppers_node = fgGetNode( base_name ); return true; } ///////////////////////////////////////////////////////////////////// // Write the lights ///////////////////////////////////////////////////////////////////// bool FGATCOutput::do_lamps() { if ( lamps_out_node != NULL ) { for ( int i = 0; i < lamps_out_node->nChildren(); ++i ) { // read the next config entry from the property tree SGPropertyNode *child = lamps_out_node->getChild(i); string cname = child->getName(); int index = child->getIndex(); string name = ""; string type = ""; SGPropertyNode *src_prop = NULL; if ( cname == "lamp" ) { SGPropertyNode *prop; prop = child->getChild( "name" ); if ( prop != NULL ) { name = prop->getStringValue(); } prop = child->getChild( "type" ); if ( prop != NULL ) { type = prop->getStringValue(); } prop = child->getChild( "prop" ); if ( prop != NULL ) { src_prop = fgGetNode( prop->getStringValue(), true ); } ATCSetLamp( lamps_fd, index, src_prop->getBoolValue() ); } else { SG_LOG( SG_IO, SG_DEBUG, "Input config error, expecting 'lamp' but found " << cname ); } } } return true; } ///////////////////////////////////////////////////////////////////// // Update the radio display ///////////////////////////////////////////////////////////////////// static bool navcom1_has_power() { static SGPropertyNode *navcom1_bus_power = fgGetNode( "/systems/electrical/outputs/nav[0]", true ); static SGPropertyNode *navcom1_power_btn = fgGetNode( "/instrumentation/nav[0]/power-btn", true ); return (navcom1_bus_power->getDoubleValue() > 1.0) && navcom1_power_btn->getBoolValue(); } static bool navcom2_has_power() { static SGPropertyNode *navcom2_bus_power = fgGetNode( "/systems/electrical/outputs/nav[1]", true ); static SGPropertyNode *navcom2_power_btn = fgGetNode( "/instrumentation/nav[1]/power-btn", true ); return (navcom2_bus_power->getDoubleValue() > 1.0) && navcom2_power_btn->getBoolValue(); } static bool dme_has_power() { static SGPropertyNode *dme_bus_power = fgGetNode( "/systems/electrical/outputs/dme", true ); return (dme_bus_power->getDoubleValue() > 1.0); } static bool adf_has_power() { static SGPropertyNode *adf_bus_power = fgGetNode( "/systems/electrical/outputs/adf", true ); static SGPropertyNode *adf_power_btn = fgGetNode( "/instrumentation/kr-87/inputs/power-btn", true ); return (adf_bus_power->getDoubleValue() > 1.0) && adf_power_btn->getBoolValue(); } static bool xpdr_has_power() { static SGPropertyNode *xpdr_bus_power = fgGetNode( "/systems/electrical/outputs/transponder", true ); static SGPropertyNode *xpdr_func_knob = fgGetNode( "/instrumentation/transponder/inputs/func-knob", true ); return (xpdr_bus_power->getDoubleValue() > 1.0) && (xpdr_func_knob->getIntValue() > 0); } bool FGATCOutput::do_radio_display() { static SGPropertyNode *dme_serviceable = fgGetNode( "/instrumentation/dme/serviceable", true ); static SGPropertyNode *dme_in_range = fgGetNode( "/instrumentation/dme/in-range", true ); static SGPropertyNode *dme_min = fgGetNode( "/instrumentation/dme/indicated-time-min", true ); static SGPropertyNode *dme_kt = fgGetNode( "/instrumentation/dme/indicated-ground-speed-kt", true ); static SGPropertyNode *dme_nm = fgGetNode( "/instrumentation/dme/indicated-distance-nm", true ); static SGPropertyNode *comm1_serviceable = fgGetNode( "/instrumentation/comm[0]/serviceable", true ); static SGPropertyNode *com1_freq = fgGetNode( "/instrumentation/comm[0]/frequencies/selected-mhz", true); static SGPropertyNode *com1_stby_freq = fgGetNode( "/instrumentation/comm[0]/frequencies/standby-mhz", true ); static SGPropertyNode *comm2_serviceable = fgGetNode( "/instrumentation/comm[1]/serviceable", true ); static SGPropertyNode *com2_freq = fgGetNode( "/instrumentation/comm[1]/frequencies/selected-mhz", true); static SGPropertyNode *com2_stby_freq = fgGetNode( "/instrumentation/comm[1]/frequencies/standby-mhz", true ); static SGPropertyNode *nav1_serviceable = fgGetNode( "/instrumentation/nav[0]/serviceable", true ); static SGPropertyNode *nav1_freq = fgGetNode( "/instrumentation/nav[0]/frequencies/selected-mhz", true ); static SGPropertyNode *nav1_stby_freq = fgGetNode( "/instrumentation/nav[0]/frequencies/standby-mhz", true ); static SGPropertyNode *nav2_serviceable = fgGetNode( "/instrumentation/nav[1]/serviceable", true ); static SGPropertyNode *nav2_freq = fgGetNode( "/instrumentation/nav[1]/frequencies/selected-mhz", true ); static SGPropertyNode *nav2_stby_freq = fgGetNode( "/instrumentation/nav[1]/frequencies/standby-mhz", true ); static SGPropertyNode *adf_serviceable = fgGetNode( "/instrumentation/adf/serviceable", true ); static SGPropertyNode *adf_freq = fgGetNode( "/instrumentation/kr-87/outputs/selected-khz", true ); static SGPropertyNode *adf_stby_freq = fgGetNode( "/instrumentation/kr-87/outputs/standby-khz", true ); static SGPropertyNode *adf_stby_mode = fgGetNode( "/instrumentation/kr-87/modes/stby", true ); static SGPropertyNode *adf_timer_mode = fgGetNode( "/instrumentation/kr-87/modes/timer", true ); // static SGPropertyNode *adf_count_mode // = fgGetNode( "/instrumentation/kr-87/modes/count", true ); static SGPropertyNode *adf_flight_timer = fgGetNode( "/instrumentation/kr-87/outputs/flight-timer", true ); static SGPropertyNode *adf_elapsed_timer = fgGetNode( "/instrumentation/kr-87/outputs/elapsed-timer", true ); static SGPropertyNode *xpdr_serviceable = fgGetNode( "/instrumentation/transponder/inputs/serviceable", true ); static SGPropertyNode *xpdr_func_knob = fgGetNode( "/instrumentation/transponder/inputs/func-knob", true ); static SGPropertyNode *xpdr_flight_level = fgGetNode( "/instrumentation/transponder/outputs/flight-level", true ); static SGPropertyNode *xpdr_id_code = fgGetNode( "/instrumentation/transponder/outputs/id-code", true ); char digits[10]; 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 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 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; } 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; int big, little; if ( hours > 0 ) { big = hours; if ( big > 99 ) { big = 99; } little = min; } else { big = min; little = sec; } if ( big > 99 ) { big = 99; } // cout << big << ":" << little << endl; 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; } 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; } ATCSetRadios( radio_display_fd, radio_display_data ); return true; } ///////////////////////////////////////////////////////////////////// // Drive the stepper motors ///////////////////////////////////////////////////////////////////// bool FGATCOutput::do_steppers() { SGPropertyNode *mag_compass = fgGetNode( "/instrumentation/magnetic-compass/indicated-heading-deg", true ); 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; ATCSetStepper( stepper_fd, ATC_COMPASS_CH, cmd ); } return true; } // process the hardware outputs. This code assumes the calling layer // will lock the hardware. bool FGATCOutput::process() { if ( !is_open ) { SG_LOG( SG_IO, SG_ALERT, "This board has not been opened for output! " << board ); return false; } do_lamps(); do_radio_display(); #ifdef ATCFLIGHTSIM_HAVE_COMPASS do_steppers(); #endif return true; } bool FGATCOutput::close() { #if defined( unix ) || defined( __CYGWIN__ ) if ( !is_open ) { return true; } int result; result = ::close( lamps_fd ); if ( result == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error closing %s", lamps_file ); perror( msg ); exit( -1 ); } result = ::close( radio_display_fd ); if ( result == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error closing %s", radio_display_file ); perror( msg ); exit( -1 ); } result = ::close( stepper_fd ); if ( result == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error closing %s", stepper_file ); perror( msg ); exit( -1 ); } #endif return true; }