// ATC-Inputs.hxx -- Translate ATC hardware inputs to FGFS properties // // 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 STL_STRING #include #include
#include "ATC-Inputs.hxx" SG_USING_STD(string); // Constructor: The _board parameter specifies which board to // reference. Possible values are 0 or 1. The _config_file parameter // specifies the location of the input config file (xml) FGATCInput::FGATCInput( const int _board, const SGPath &_config_file ) : is_open(false), ignore_flight_controls(NULL), ignore_pedal_controls(NULL), analog_in_node(NULL), radio_in_node(NULL), switches_node(NULL) { board = _board; config = _config_file; } // Read analog inputs static void ATCReadAnalogInputs( int fd, unsigned char *analog_in_bytes ) { #if defined( unix ) || defined( __CYGWIN__ ) // rewind lseek( fd, 0, SEEK_SET ); int result = read( fd, analog_in_bytes, ATC_ANAL_IN_BYTES ); if ( result != ATC_ANAL_IN_BYTES ) { SG_LOG( SG_IO, SG_ALERT, "Read failed" ); exit( -1 ); } #endif } // Read status of radio switches and knobs static void ATCReadRadios( int fd, unsigned char *switch_data ) { #if defined( unix ) || defined( __CYGWIN__ ) // rewind lseek( fd, 0, SEEK_SET ); int result = read( fd, switch_data, ATC_RADIO_SWITCH_BYTES ); if ( result != ATC_RADIO_SWITCH_BYTES ) { SG_LOG( SG_IO, SG_ALERT, "Read failed" ); exit( -1 ); } #endif } // Read switch inputs static void ATCReadSwitches( int fd, unsigned char *switch_bytes ) { #if defined( unix ) || defined( __CYGWIN__ ) // rewind lseek( fd, 0, SEEK_SET ); int result = read( fd, switch_bytes, ATC_SWITCH_BYTES ); if ( result != ATC_SWITCH_BYTES ) { SG_LOG( SG_IO, SG_ALERT, "Read failed" ); exit( -1 ); } #endif } void FGATCInput::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 FGATCInput::open() { if ( is_open ) { SG_LOG( SG_IO, SG_ALERT, "This board is already open for input! " << board ); return false; } // This loads the config parameters generated by "simcal" init_config(); SG_LOG( SG_IO, SG_ALERT, "Initializing ATC input hardware, please wait ..." ); snprintf( analog_in_file, 256, "/proc/atcflightsim/board%d/analog_in", board ); snprintf( radios_file, 256, "/proc/atcflightsim/board%d/radios", board ); snprintf( switches_file, 256, "/proc/atcflightsim/board%d/switches", board ); #if defined( unix ) || defined( __CYGWIN__ ) ///////////////////////////////////////////////////////////////////// // Open the /proc files ///////////////////////////////////////////////////////////////////// analog_in_fd = ::open( analog_in_file, O_RDONLY ); if ( analog_in_fd == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error opening %s", analog_in_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 ); } switches_fd = ::open( switches_file, O_RDONLY ); if ( switches_fd == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error opening %s", switches_file ); perror( msg ); exit( -1 ); } #endif ///////////////////////////////////////////////////////////////////// // Finished initing hardware ///////////////////////////////////////////////////////////////////// SG_LOG( SG_IO, SG_ALERT, "Done initializing ATC input hardware." ); is_open = true; ///////////////////////////////////////////////////////////////////// // Connect up to property values ///////////////////////////////////////////////////////////////////// ignore_flight_controls = fgGetNode( "/input/atcsim/ignore-flight-controls", true ); ignore_pedal_controls = fgGetNode( "/input/atcsim/ignore-pedal-controls", true ); char base_name[256]; snprintf( base_name, 256, "/input/atc-board[%d]/analog-in", board ); analog_in_node = fgGetNode( base_name ); snprintf( base_name, 256, "/input/atc-board[%d]/radio-switches", board ); radio_in_node = fgGetNode( base_name ); snprintf( base_name, 256, "/input/atc-board[%d]/switches", board ); switches_node = fgGetNode( base_name ); return true; } ///////////////////////////////////////////////////////////////////// // Read analog inputs ///////////////////////////////////////////////////////////////////// // scale a number between min and max (with center defined) to a scale // from -1.0 to 1.0 static double scale( int center, int min, int max, int value ) { // cout << center << " " << min << " " << max << " " << value << " "; double result; double range; if ( value <= center ) { range = center - min; result = (value - center) / range; } else { range = max - center; result = (value - center) / range; } if ( result < -1.0 ) result = -1.0; if ( result > 1.0 ) result = 1.0; // cout << result << endl; return result; } // scale a number between min and max to a scale from 0.0 to 1.0 static double scale( int min, int max, int value ) { // cout << center << " " << min << " " << max << " " << value << " "; double result; double range; range = max - min; result = (value - min) / range; if ( result < 0.0 ) result = 0.0; if ( result > 1.0 ) result = 1.0; // cout << result << endl; return result; } static int tony_magic( int raw, int obs[3] ) { int result = 0; obs[0] = raw; if ( obs[1] < 30 ) { if ( obs[2] >= 68 && obs[2] < 480 ) { result = -6; } else if ( obs[2] >= 480 ) { result = 6; } obs[2] = obs[1]; obs[1] = obs[0]; } else if ( obs[1] < 68 ) { // do nothing obs[1] = obs[0]; } else if ( obs[2] < 30 ) { if ( obs[1] >= 68 && obs[1] < 480 ) { result = 6; obs[2] = obs[1]; obs[1] = obs[0]; } else if ( obs[1] >= 480 ) { result = -6; if ( obs[0] < obs[1] ) { obs[2] = obs[1]; obs[1] = obs[0]; } else { obs[2] = obs[0]; obs[1] = obs[0]; } } } else if ( obs[1] > 980 ) { if ( obs[2] <= 956 && obs[2] > 480 ) { result = 6; } else if ( obs[2] <= 480 ) { result = -6; } obs[2] = obs[1]; obs[1] = obs[0]; } else if ( obs[1] > 956 ) { // do nothing obs[1] = obs[0]; } else if ( obs[2] > 980 ) { if ( obs[1] <= 956 && obs[1] > 480 ) { result = -6; obs[2] = obs[1]; obs[1] = obs[0]; } else if ( obs[1] <= 480 ) { result = 6; if ( obs[0] > obs[1] ) { obs[2] = obs[1]; obs[1] = obs[0]; } else { obs[2] = obs[0]; obs[1] = obs[0]; } } } else { if ( obs[1] < 480 && obs[2] > 480 ) { // crossed gap going up if ( obs[0] < obs[1] ) { // caught a bogus intermediate value coming out of the gap obs[1] = obs[0]; } } else if ( obs[1] > 480 && obs[2] < 480 ) { // crossed gap going down if ( obs[0] > obs[1] ) { // caught a bogus intermediate value coming out of the gap obs[1] = obs[0]; } } else if ( obs[0] > 480 && obs[1] < 480 && obs[2] < 480 ) { // crossed the gap going down if ( obs[1] > obs[2] ) { // caught a bogus intermediate value coming out of the gap obs[1] = obs[2]; } } else if ( obs[0] < 480 && obs[1] > 480 && obs[2] > 480 ) { // crossed the gap going up if ( obs[1] < obs[2] ) { // caught a bogus intermediate value coming out of the gap obs[1] = obs[2]; } } result = obs[1] - obs[2]; if ( abs(result) > 400 ) { // ignore result = 0; } obs[2] = obs[1]; obs[1] = obs[0]; } // cout << " result = " << result << endl; if ( result < -500 ) { result += 1024; } if ( result > 500 ) { result -= 1024; } return result; } static double instr_pot_filter( double ave, double val ) { if ( fabs(ave - val) < 400 || fabs(val) < fabs(ave) ) { return 0.5 * ave + 0.5 * val; } else { return ave; } } bool FGATCInput::do_analog_in() { // Read raw data in byte form ATCReadAnalogInputs( analog_in_fd, analog_in_bytes ); // Convert to integer values for ( int channel = 0; channel < ATC_ANAL_IN_VALUES; ++channel ) { unsigned char hi = analog_in_bytes[2 * channel] & 0x03; unsigned char lo = analog_in_bytes[2 * channel + 1]; analog_in_data[channel] = hi * 256 + lo; // printf("%02x %02x ", hi, lo ); // printf("%04d ", value ); } // Process analog inputs if ( analog_in_node != NULL ) { for ( int i = 0; i < analog_in_node->nChildren(); ++i ) { // read the next config entry from the property tree SGPropertyNode *child = analog_in_node->getChild(i); string cname = child->getName(); int index = child->getIndex(); string name = ""; string type = ""; string subtype = ""; vector output_nodes; output_nodes.clear(); int center = -1; int min = 0; int max = 1023; float factor = 1.0; if ( cname == "channel" ) { SGPropertyNode *prop; prop = child->getChild( "name" ); if ( prop != NULL ) { name = prop->getStringValue(); } prop = child->getChild( "type", 0 ); if ( prop != NULL ) { type = prop->getStringValue(); } prop = child->getChild( "type", 1 ); if ( prop != NULL ) { subtype = prop->getStringValue(); } int j = 0; while ( (prop = child->getChild("prop", j)) != NULL ) { SGPropertyNode *tmp = fgGetNode( prop->getStringValue(), true ); output_nodes.push_back( tmp ); j++; } prop = child->getChild( "center" ); if ( prop != NULL ) { center = prop->getIntValue(); } prop = child->getChild( "min" ); if ( prop != NULL ) { min = prop->getIntValue(); } prop = child->getChild( "max" ); if ( prop != NULL ) { max = prop->getIntValue(); } prop = child->getChild( "factor" ); if ( prop != NULL ) { factor = prop->getFloatValue(); } // Fetch the raw value int raw_value = analog_in_data[index]; // Update the target properties if ( type == "flight" && !ignore_flight_controls->getBoolValue() ) { if ( subtype != "pedals" || ( subtype == "pedals" && !ignore_pedal_controls->getBoolValue() ) ) { // "Cook" the raw value float scaled_value = 0.0f; if ( center >= 0 ) { scaled_value = scale( center, min, max, raw_value ); } else { scaled_value = scale( min, max, raw_value ); } scaled_value *= factor; // update the property tree values for ( j = 0; j < (int)output_nodes.size(); ++j ) { output_nodes[j]->setDoubleValue( scaled_value ); } } } else if ( type == "avionics-simple" ) { // "Cook" the raw value float scaled_value = 0.0f; if ( center >= 0 ) { scaled_value = scale( center, min, max, raw_value ); } else { scaled_value = scale( min, max, raw_value ); } scaled_value *= factor; // update the property tree values for ( j = 0; j < (int)output_nodes.size(); ++j ) { output_nodes[j]->setDoubleValue( scaled_value ); } } else if ( type == "avionics-resolver" ) { // this type of analog input impliments a // rotational knob. We first caclulate the amount // of knob rotation (slightly complex to work with // hardware specific goofiness) and then multiply // that amount of movement by a scaling factor, // and finally add the result to the original // value. bool do_init = false; float scaled_value = 0.0f; // fetch intermediate values from property tree prop = child->getChild( "is-inited", 0 ); if ( prop == NULL ) { do_init = true; prop = child->getChild( "is-inited", 0, true ); prop->setBoolValue( true ); } int raw[3]; for ( j = 0; j < 3; ++j ) { prop = child->getChild( "raw", j, true ); if ( do_init ) { raw[j] = analog_in_data[index]; } else { raw[j] = prop->getIntValue(); } } // do Tony's magic to calculate knob movement // based on current analog input position and // historical data. int diff = tony_magic( analog_in_data[index], raw ); // write raw intermediate values (updated by // tony_magic()) back to property tree for ( j = 0; j < 3; ++j ) { prop = child->getChild( "raw", j, true ); prop->setIntValue( raw[j] ); } // filter knob position prop = child->getChild( "diff-average", 0, true ); double diff_ave = prop->getDoubleValue(); diff_ave = instr_pot_filter( diff_ave, diff ); prop->setDoubleValue( diff_ave ); // calculate value adjustment in real world units scaled_value = diff_ave * factor; // update the property tree values for ( j = 0; j < (int)output_nodes.size(); ++j ) { float value = output_nodes[j]->getDoubleValue(); value += scaled_value; prop = child->getChild( "min-clamp" ); if ( prop != NULL ) { double min = prop->getDoubleValue(); if ( value < min ) { value = min; } } prop = child->getChild( "max-clamp" ); if ( prop != NULL ) { double max = prop->getDoubleValue(); if ( value > max ) { value = max; } } prop = child->getChild( "compass-heading" ); if ( prop != NULL ) { bool compass = prop->getBoolValue(); if ( compass ) { while ( value >= 360.0 ) { value -= 360.0; } while ( value < 0.0 ) { value += 360.0; } } } output_nodes[j]->setDoubleValue( value ); } } else { SG_LOG( SG_IO, SG_DEBUG, "Invalid channel type = " << type ); } } else { SG_LOG( SG_IO, SG_DEBUG, "Input config error, expecting 'channel' but found " << cname ); } } } return true; } ///////////////////////////////////////////////////////////////////// // Read the switch positions ///////////////////////////////////////////////////////////////////// // decode the packed switch data static void update_switch_matrix( int board, unsigned char switch_data[ATC_SWITCH_BYTES], int switch_matrix[2][ATC_NUM_COLS][ATC_SWITCH_BYTES] ) { for ( int row = 0; row < ATC_SWITCH_BYTES; ++row ) { unsigned char switches = switch_data[row]; for( int column = 0; column < ATC_NUM_COLS; ++column ) { switch_matrix[board][column][row] = switches & 1; switches = switches >> 1; } } } bool FGATCInput::do_switches() { // Read the raw data ATCReadSwitches( switches_fd, switch_data ); // unpack the switch data int switch_matrix[2][ATC_NUM_COLS][ATC_SWITCH_BYTES]; update_switch_matrix( board, switch_data, switch_matrix ); // Process the switch inputs if ( switches_node != NULL ) { for ( int i = 0; i < switches_node->nChildren(); ++i ) { // read the next config entry from the property tree SGPropertyNode *child = switches_node->getChild(i); string cname = child->getName(); string name = ""; string type = ""; vector output_nodes; output_nodes.clear(); int row = -1; int col = -1; float factor = 1.0; int filter = -1; float scaled_value = 0.0f; bool invert = false; // get common options SGPropertyNode *prop; prop = child->getChild( "name" ); if ( prop != NULL ) { name = prop->getStringValue(); } prop = child->getChild( "type" ); if ( prop != NULL ) { type = prop->getStringValue(); } int j = 0; while ( (prop = child->getChild("prop", j)) != NULL ) { SGPropertyNode *tmp = fgGetNode( prop->getStringValue(), true ); output_nodes.push_back( tmp ); j++; } prop = child->getChild( "factor" ); if ( prop != NULL ) { factor = prop->getFloatValue(); } prop = child->getChild( "invert" ); if ( prop != NULL ) { invert = prop->getBoolValue(); } prop = child->getChild( "steady-state-filter" ); if ( prop != NULL ) { filter = prop->getIntValue(); } // handle different types of switches if ( cname == "switch" ) { prop = child->getChild( "row" ); if ( prop != NULL ) { row = prop->getIntValue(); } prop = child->getChild( "col" ); if ( prop != NULL ) { col = prop->getIntValue(); } // Fetch the raw value int raw_value = switch_matrix[board][row][col]; // Invert if ( invert ) { raw_value = !raw_value; } // Cook the value scaled_value = (float)raw_value * factor; } else if ( cname == "combo-switch" ) { float combo_value = 0.0f; SGPropertyNode *pos; int k = 0; while ( (pos = child->getChild("position", k++)) != NULL ) { // read the combo position entries from the property tree prop = pos->getChild( "row" ); if ( prop != NULL ) { row = prop->getIntValue(); } prop = pos->getChild( "col" ); if ( prop != NULL ) { col = prop->getIntValue(); } prop = pos->getChild( "value" ); if ( prop != NULL ) { combo_value = prop->getFloatValue(); } // Fetch the raw value int raw_value = switch_matrix[board][row][col]; // cout << "sm[" << board << "][" << row << "][" << col // << "] = " << raw_value << endl; if ( raw_value ) { // set scaled_value to the first combo_value // that matches and jump out of loop. scaled_value = combo_value; break; } } // Cook the value scaled_value *= factor; } else if ( cname == "additive-switch" ) { float additive_value = 0.0f; float increment = 0.0f; SGPropertyNode *pos; int k = 0; while ( (pos = child->getChild("position", k++)) != NULL ) { // read the combo position entries from the property tree prop = pos->getChild( "row" ); if ( prop != NULL ) { row = prop->getIntValue(); } prop = pos->getChild( "col" ); if ( prop != NULL ) { col = prop->getIntValue(); } prop = pos->getChild( "value" ); if ( prop != NULL ) { increment = prop->getFloatValue(); } // Fetch the raw value int raw_value = switch_matrix[board][row][col]; // cout << "sm[" << board << "][" << row << "][" << col // << "] = " << raw_value << endl; if ( raw_value ) { // set scaled_value to the first combo_value // that matches and jump out of loop. additive_value += increment; } } // Cook the value scaled_value = additive_value * factor; } // handle filter request. The value of the switch must be // steady-state for "n" frames before the property value // is updated. bool update_prop = true; if ( filter > 1 ) { SGPropertyNode *fv = child->getChild( "filter-value", 0, true ); float filter_value = fv->getFloatValue(); SGPropertyNode *fc = child->getChild( "filter-count", 0, true ); int filter_count = fc->getIntValue(); if ( fabs(scaled_value - filter_value) < 0.0001 ) { filter_count++; } else { filter_count = 0; } if ( filter_count < filter ) { update_prop = false; } fv->setFloatValue( scaled_value ); fc->setIntValue( filter_count ); } if ( update_prop ) { if ( type == "engine" || type == "flight" ) { if ( ! ignore_flight_controls->getBoolValue() ) { // update the property tree values for ( j = 0; j < (int)output_nodes.size(); ++j ) { output_nodes[j]->setDoubleValue( scaled_value ); } } } else if ( type == "avionics" ) { // update the property tree values for ( j = 0; j < (int)output_nodes.size(); ++j ) { output_nodes[j]->setDoubleValue( scaled_value ); } } } } } return true; } ///////////////////////////////////////////////////////////////////// // Read radio switches ///////////////////////////////////////////////////////////////////// bool FGATCInput::do_radio_switches() { // Read the raw data ATCReadRadios( radios_fd, radio_switch_data ); // Process the radio switch/knob inputs if ( radio_in_node != NULL ) { for ( int i = 0; i < radio_in_node->nChildren(); ++i ) { // read the next config entry from the property tree SGPropertyNode *child = radio_in_node->getChild(i); string cname = child->getName(); if ( cname == "switch" ) { string name = ""; string type = ""; vector output_nodes; output_nodes.clear(); int byte_num = -1; int right_shift = 0; int mask = 0xff; int factor = 1; int offset = 0; bool invert = false; int scaled_value = 0; // get common options SGPropertyNode *prop; prop = child->getChild( "name" ); if ( prop != NULL ) { name = prop->getStringValue(); } prop = child->getChild( "type" ); if ( prop != NULL ) { type = prop->getStringValue(); } int j = 0; while ( (prop = child->getChild("prop", j)) != NULL ) { SGPropertyNode *tmp = fgGetNode( prop->getStringValue(), true ); output_nodes.push_back( tmp ); j++; } prop = child->getChild( "byte" ); if ( prop != NULL ) { byte_num = prop->getIntValue(); } prop = child->getChild( "right-shift" ); if ( prop != NULL ) { right_shift = prop->getIntValue(); } prop = child->getChild( "mask" ); if ( prop != NULL ) { mask = prop->getIntValue(); } prop = child->getChild( "factor" ); if ( prop != NULL ) { factor = prop->getIntValue(); } prop = child->getChild( "offset" ); if ( prop != NULL ) { offset = prop->getIntValue(); } prop = child->getChild( "invert" ); if ( prop != NULL ) { invert = prop->getBoolValue(); } // Fetch the raw value int raw_value = (radio_switch_data[byte_num] >> right_shift) & mask; // Cook the value if ( invert ) { raw_value = !raw_value; } scaled_value = raw_value * factor + offset; // update the property tree values for ( j = 0; j < (int)output_nodes.size(); ++j ) { output_nodes[j]->setIntValue( scaled_value ); } } } } return true; } // process the hardware inputs. This code assumes the calling layer // will lock the hardware. bool FGATCInput::process() { if ( !is_open ) { SG_LOG( SG_IO, SG_ALERT, "This board has not been opened for input! " << board ); return false; } do_analog_in(); do_switches(); do_radio_switches(); return true; } bool FGATCInput::close() { #if defined( unix ) || defined( __CYGWIN__ ) if ( !is_open ) { return true; } int result; result = ::close( analog_in_fd ); if ( result == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error closing %s", analog_in_file ); perror( msg ); exit( -1 ); } result = ::close( radios_fd ); if ( result == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error closing %s", radios_file ); perror( msg ); exit( -1 ); } result = ::close( switches_fd ); if ( result == -1 ) { SG_LOG( SG_IO, SG_ALERT, "errno = " << errno ); char msg[256]; snprintf( msg, 256, "Error closing %s", switches_file ); perror( msg ); exit( -1 ); } #endif return true; }