#include

#include "environment_mgr.hxx" #include "environment_ctrl.hxx" SG_USING_STD(sort); //////////////////////////////////////////////////////////////////////// // Implementation of FGEnvironmentCtrl abstract base class. //////////////////////////////////////////////////////////////////////// FGEnvironmentCtrl::FGEnvironmentCtrl () : _environment(0), _lon_deg(0), _lat_deg(0), _elev_ft(0) { } FGEnvironmentCtrl::~FGEnvironmentCtrl () { } void FGEnvironmentCtrl::setEnvironment (FGEnvironment * environment) { _environment = environment; } void FGEnvironmentCtrl::setLongitudeDeg (double lon_deg) { _lon_deg = lon_deg; } void FGEnvironmentCtrl::setLatitudeDeg (double lat_deg) { _lat_deg = lat_deg; } void FGEnvironmentCtrl::setElevationFt (double elev_ft) { _elev_ft = elev_ft; } void FGEnvironmentCtrl::setPosition (double lon_deg, double lat_deg, double elev_ft) { _lon_deg = lon_deg; _lat_deg = lat_deg; _elev_ft = elev_ft; } //////////////////////////////////////////////////////////////////////// // Implementation of FGUserDefEnvironmentCtrl. //////////////////////////////////////////////////////////////////////// FGUserDefEnvironmentCtrl::FGUserDefEnvironmentCtrl () : _base_wind_speed_node(0), _gust_wind_speed_node(0), _current_wind_speed_kt(0), _delta_wind_speed_kt(0) { } FGUserDefEnvironmentCtrl::~FGUserDefEnvironmentCtrl () { } void FGUserDefEnvironmentCtrl::init () { // Fill in some defaults. if (!fgHasNode("/environment/params/base-wind-speed-kt")) fgSetDouble("/environment/params/base-wind-speed-kt", fgGetDouble("/environment/wind-speed-kt")); if (!fgHasNode("/environment/params/gust-wind-speed-kt")) fgSetDouble("/environment/params/gust-wind-speed-kt", fgGetDouble("/environment/params/base-wind-speed-kt")); _base_wind_speed_node = fgGetNode("/environment/params/base-wind-speed-kt", true); _gust_wind_speed_node = fgGetNode("/environment/params/gust-wind-speed-kt", true); _current_wind_speed_kt = _base_wind_speed_node->getDoubleValue(); _delta_wind_speed_kt = 0.1; } void FGUserDefEnvironmentCtrl::update (double dt) { double base_wind_speed = _base_wind_speed_node->getDoubleValue(); double gust_wind_speed = _gust_wind_speed_node->getDoubleValue(); if (gust_wind_speed < base_wind_speed) { gust_wind_speed = base_wind_speed; _gust_wind_speed_node->setDoubleValue(gust_wind_speed); } if (base_wind_speed == gust_wind_speed) { _current_wind_speed_kt = base_wind_speed; } else { int rn = rand() % 128; int sign = (_delta_wind_speed_kt < 0 ? -1 : 1); double gust = _current_wind_speed_kt - base_wind_speed; double incr = gust / 50; if (rn == 0) _delta_wind_speed_kt = - _delta_wind_speed_kt; else if (rn < 4) _delta_wind_speed_kt -= incr * sign; else if (rn < 16) _delta_wind_speed_kt += incr * sign; _current_wind_speed_kt += _delta_wind_speed_kt; if (_current_wind_speed_kt < base_wind_speed) { _current_wind_speed_kt = base_wind_speed; _delta_wind_speed_kt = 0.01; } else if (_current_wind_speed_kt > gust_wind_speed) { _current_wind_speed_kt = gust_wind_speed; _delta_wind_speed_kt = -0.01; } } if (_environment != 0) _environment->set_wind_speed_kt(_current_wind_speed_kt); } //////////////////////////////////////////////////////////////////////// // Implementation of FGInterpolateEnvironmentCtrl. //////////////////////////////////////////////////////////////////////// FGInterpolateEnvironmentCtrl::FGInterpolateEnvironmentCtrl () { } FGInterpolateEnvironmentCtrl::~FGInterpolateEnvironmentCtrl () { unsigned int i; for (i = 0; i < _boundary_table.size(); i++) delete _boundary_table[i]; for (i = 0; i < _aloft_table.size(); i++) delete _aloft_table[i]; } void FGInterpolateEnvironmentCtrl::init () { read_table(fgGetNode("/environment/config/boundary", true), _boundary_table); read_table(fgGetNode("/environment/config/aloft", true), _aloft_table); } void FGInterpolateEnvironmentCtrl::reinit () { unsigned int i; for (i = 0; i < _boundary_table.size(); i++) delete _boundary_table[i]; for (i = 0; i < _aloft_table.size(); i++) delete _aloft_table[i]; _boundary_table.clear(); _aloft_table.clear(); init(); } void FGInterpolateEnvironmentCtrl::read_table (const SGPropertyNode * node, vector &table) { for (int i = 0; i < node->nChildren(); i++) { const SGPropertyNode * child = node->getChild(i); if ( strcmp(child->getName(), "entry") == 0 && child->getStringValue("elevation-ft", "")[0] != '\0' && ( child->getDoubleValue("elevation-ft") > 0.1 || i == 0 ) ) { bucket * b = new bucket; if (i > 0) b->environment.copy(table[i-1]->environment); b->environment.read(child); b->altitude_ft = b->environment.get_elevation_ft(); table.push_back(b); } } sort(table.begin(), table.end()); } void FGInterpolateEnvironmentCtrl::update (double delta_time_sec) { // FIXME double altitude_ft = fgGetDouble("/position/altitude-ft"); double altitude_agl_ft = fgGetDouble("/position/altitude-agl-ft"); double boundary_transition = fgGetDouble("/environment/config/boundary-transition-ft", 500); // double ground_elevation_ft = altitude_ft - altitude_agl_ft; int length = _boundary_table.size(); if (length > 0) { // boundary table double boundary_limit = _boundary_table[length-1]->altitude_ft; if (boundary_limit >= altitude_agl_ft) { do_interpolate(_boundary_table, altitude_agl_ft, _environment); return; } else if ((boundary_limit + boundary_transition) >= altitude_agl_ft) { // both tables do_interpolate(_boundary_table, altitude_agl_ft, &env1); do_interpolate(_aloft_table, altitude_ft, &env2); double fraction = (altitude_agl_ft - boundary_limit) / boundary_transition; interpolate(&env1, &env2, fraction, _environment); return; } } // aloft table do_interpolate(_aloft_table, altitude_ft, _environment); } void FGInterpolateEnvironmentCtrl::do_interpolate (vector &table, double altitude_ft, FGEnvironment * environment) { int length = table.size(); if (length == 0) return; // Boundary conditions if ((length == 1) || (table[0]->altitude_ft >= altitude_ft)) { environment->copy(table[0]->environment); return; } else if (table[length-1]->altitude_ft <= altitude_ft) { environment->copy(table[length-1]->environment); return; } // Search the interpolation table for (int i = 0; i < length - 1; i++) { if ((i == length - 1) || (table[i]->altitude_ft <= altitude_ft)) { FGEnvironment * env1 = &(table[i]->environment); FGEnvironment * env2 = &(table[i+1]->environment); double fraction; if (table[i]->altitude_ft == table[i+1]->altitude_ft) fraction = 1.0; else fraction = ((altitude_ft - table[i]->altitude_ft) / (table[i+1]->altitude_ft - table[i]->altitude_ft)); interpolate(env1, env2, fraction, environment); return; } } } bool FGInterpolateEnvironmentCtrl::bucket::operator< (const bucket &b) const { return (altitude_ft < b.altitude_ft); } //////////////////////////////////////////////////////////////////////// // Implementation of FGMetarEnvironmentCtrl. //////////////////////////////////////////////////////////////////////// FGMetarEnvironmentCtrl::FGMetarEnvironmentCtrl () : env( new FGInterpolateEnvironmentCtrl ), _icao( "" ), search_interval_sec( 60.0 ), // 1 minute same_station_interval_sec( 900.0 ), // 15 minutes search_elapsed( 9999.0 ), fetch_elapsed( 9999.0 ), proxy_host( fgGetNode("/sim/presets/proxy/host", true) ), proxy_port( fgGetNode("/sim/presets/proxy/port", true) ), proxy_auth( fgGetNode("/sim/presets/proxy/authentication", true) ), metar_max_age( fgGetNode("/environment/params/metar-max-age-min", true) ), _error_count( 0 ), _stale_count( 0 ), _dt( 0.0 ), _error_dt( 0.0 ) { #if defined(ENABLE_THREADS) thread = new MetarThread(this); thread->start( 1 ); #endif // ENABLE_THREADS } FGMetarEnvironmentCtrl::~FGMetarEnvironmentCtrl () { #if defined(ENABLE_THREADS) thread->cancel(); thread->join(); #endif // ENABLE_THREADS delete env; env = NULL; } // use a "command" to set station temp at station elevation static void set_temp_at_altitude( float temp_degc, float altitude_ft ) { SGPropertyNode args; SGPropertyNode *node = args.getNode("temp-degc", 0, true); node->setFloatValue( temp_degc ); node = args.getNode("altitude-ft", 0, true); node->setFloatValue( altitude_ft ); globals->get_commands()->execute("set-outside-air-temp-degc", &args); } static void set_dewpoint_at_altitude( float dewpoint_degc, float altitude_ft ) { SGPropertyNode args; SGPropertyNode *node = args.getNode("dewpoint-degc", 0, true); node->setFloatValue( dewpoint_degc ); node = args.getNode("altitude-ft", 0, true); node->setFloatValue( altitude_ft ); globals->get_commands()->execute("set-dewpoint-temp-degc", &args); } void FGMetarEnvironmentCtrl::update_env_config () { fgSetupWind( fgGetDouble("/environment/metar/base-wind-range-from"), fgGetDouble("/environment/metar/base-wind-range-to"), fgGetDouble("/environment/metar/base-wind-speed-kt"), fgGetDouble("/environment/metar/gust-wind-speed-kt") ); fgDefaultWeatherValue( "visibility-m", fgGetDouble("/environment/metar/min-visibility-m") ); set_temp_at_altitude( fgGetDouble("/environment/metar/temperature-degc"), station_elevation_ft ); set_dewpoint_at_altitude( fgGetDouble("/environment/metar/dewpoint-degc"), station_elevation_ft ); fgDefaultWeatherValue( "pressure-sea-level-inhg", fgGetDouble("/environment/metar/pressure-inhg") ); } void FGMetarEnvironmentCtrl::init () { const SGPropertyNode *longitude = fgGetNode( "/position/longitude-deg", true ); const SGPropertyNode *latitude = fgGetNode( "/position/latitude-deg", true ); bool found_metar = false; long max_age = metar_max_age->getLongValue(); // Don't check max age during init so that we don't loop over a lot // of airports metar if there is a problem. // The update() calls will find a correct metar if things went wrong here metar_max_age->setLongValue(0); while ( !found_metar && (_error_count < 3) ) { const FGAirport* a = globals->get_airports() ->search( longitude->getDoubleValue(), latitude->getDoubleValue(), true ); if ( a ) { FGMetarResult result = fetch_data( a->getId() ); if ( result.m != NULL ) { SG_LOG( SG_GENERAL, SG_INFO, "closest station w/ metar = " << a->getId()); last_apt = *a; _icao = a->getId(); search_elapsed = 0.0; fetch_elapsed = 0.0; update_metar_properties( result.m ); update_env_config(); env->init(); found_metar = true; } else { // mark as no metar so it doesn't show up in subsequent // searches. SG_LOG( SG_GENERAL, SG_INFO, "no metar at metar = " << a->getId() ); globals->get_airports()->no_metar( a->getId() ); } } } metar_max_age->setLongValue(max_age); } void FGMetarEnvironmentCtrl::reinit () { _error_count = 0; _error_dt = 0.0; #if 0 update_env_config(); #endif env->reinit(); } void FGMetarEnvironmentCtrl::update(double delta_time_sec) { _dt += delta_time_sec; if (_error_count >= 3) return; FGMetarResult result; static const SGPropertyNode *longitude = fgGetNode( "/position/longitude-deg", true ); static const SGPropertyNode *latitude = fgGetNode( "/position/latitude-deg", true ); search_elapsed += delta_time_sec; fetch_elapsed += delta_time_sec; // if time for a new search request, push it onto the request // queue if ( search_elapsed > search_interval_sec ) { const FGAirport* a = globals->get_airports() ->search( longitude->getDoubleValue(), latitude->getDoubleValue(), true ); if ( a ) { if ( last_apt.getId() != a->getId() || fetch_elapsed > same_station_interval_sec ) { SG_LOG( SG_GENERAL, SG_INFO, "closest station w/ metar = " << a->getId()); request_queue.push( a->getId() ); last_apt = *a; _icao = a->getId(); search_elapsed = 0.0; fetch_elapsed = 0.0; } else { search_elapsed = 0.0; SG_LOG( SG_GENERAL, SG_INFO, "same station, waiting = " << same_station_interval_sec - fetch_elapsed ); } } else { SG_LOG( SG_GENERAL, SG_WARN, "Unable to find any airports with metar" ); } } #if !defined(ENABLE_THREADS) // No loader thread running so manually fetch the data string id = ""; while ( !request_queue.empty() ) { id = request_queue.front(); request_queue.pop(); } if ( !id.empty() ) { SG_LOG( SG_GENERAL, SG_INFO, "inline fetching = " << id ); result = fetch_data( id ); result_queue.push( result ); } #endif // ENABLE_THREADS // process any results from the loader. while ( !result_queue.empty() ) { result = result_queue.front(); result_queue.pop(); if ( result.m != NULL ) { update_metar_properties( result.m ); delete result.m; update_env_config(); env->reinit(); } else { // mark as no metar so it doesn't show up in subsequent // searches, and signal an immediate re-search. SG_LOG( SG_GENERAL, SG_WARN, "no metar at station = " << result.icao ); globals->get_airports()->no_metar( result.icao ); search_elapsed = 9999.0; } } env->update(delta_time_sec); } void FGMetarEnvironmentCtrl::setEnvironment (FGEnvironment * environment) { env->setEnvironment(environment); } FGMetarResult FGMetarEnvironmentCtrl::fetch_data( const string &icao ) { FGMetarResult result; result.icao = icao; // if the last error was more than three seconds ago, // then pretent nothing happened. if (_error_dt < 3) { _error_dt += _dt; } else { _error_dt = 0.0; _error_count = 0; } // fetch station elevation if exists const FGAirport* a = globals->get_airports()->search( icao ); if ( a ) { station_elevation_ft = a->getElevation(); } // fetch current metar data try { string host = proxy_host->getStringValue(); string auth = proxy_auth->getStringValue(); string port = proxy_port->getStringValue(); result.m = new FGMetar( icao, host, port, auth); long max_age = metar_max_age->getLongValue(); long age = result.m->getAge_min(); if (max_age && age > max_age) { SG_LOG( SG_GENERAL, SG_WARN, "METAR data too old (" << age << " min)."); delete result.m; result.m = NULL; if (++_stale_count > 10) { _error_count = 1000; throw sg_io_exception("More than 10 stale METAR messages in a row." " Check your system time!"); } } else _stale_count = 0; } catch (const sg_io_exception& e) { SG_LOG( SG_GENERAL, SG_WARN, "Error fetching live weather data: " << e.getFormattedMessage().c_str() ); #if defined(ENABLE_THREADS) if (_error_count++ >= 3) { SG_LOG( SG_GENERAL, SG_WARN, "Stop fetching data permanently."); thread->cancel(); thread->join(); } #endif result.m = NULL; } _dt = 0; return result; } void FGMetarEnvironmentCtrl::update_metar_properties( const FGMetar *m ) { int i; double d; char s[128]; fgSetString("/environment/metar/real-metar", m->getData()); // don't update with real weather when we use a custom weather scenario const char *current_scenario = fgGetString("/environment/weather-scenario", "METAR"); if( strcmp(current_scenario, "METAR") && strcmp(current_scenario, "none")) return; fgSetString("/environment/metar/last-metar", m->getData()); fgSetString("/environment/metar/station-id", m->getId()); fgSetDouble("/environment/metar/min-visibility-m", m->getMinVisibility().getVisibility_m() ); fgSetDouble("/environment/metar/max-visibility-m", m->getMaxVisibility().getVisibility_m() ); const SGMetarVisibility *dirvis = m->getDirVisibility(); for (i = 0; i < 8; i++, dirvis++) { const char *min = "/environment/metar/visibility[%d]/min-m"; const char *max = "/environment/metar/visibility[%d]/max-m"; d = dirvis->getVisibility_m(); snprintf(s, 128, min, i); fgSetDouble(s, d); snprintf(s, 128, max, i); fgSetDouble(s, d); } fgSetInt("/environment/metar/base-wind-range-from", m->getWindRangeFrom() ); fgSetInt("/environment/metar/base-wind-range-to", m->getWindRangeTo() ); fgSetDouble("/environment/metar/base-wind-speed-kt", m->getWindSpeed_kt() ); fgSetDouble("/environment/metar/gust-wind-speed-kt", m->getGustSpeed_kt() ); fgSetDouble("/environment/metar/temperature-degc", m->getTemperature_C() ); fgSetDouble("/environment/metar/dewpoint-degc", m->getDewpoint_C() ); fgSetDouble("/environment/metar/rel-humidity-norm", m->getRelHumidity() ); fgSetDouble("/environment/metar/pressure-inhg", m->getPressure_inHg() ); vector cv = m->getClouds(); vector::const_iterator cloud; const char *cl = "/environment/clouds/layer[%i]"; for (i = 0, cloud = cv.begin(); cloud != cv.end(); cloud++, i++) { const char *coverage_string[5] = { "clear", "few", "scattered", "broken", "overcast" }; const double thickness[5] = { 0, 65, 600,750, 1000}; int q; snprintf(s, 128, cl, i); strncat(s, "/coverage", 128); q = cloud->getCoverage(); fgSetString(s, coverage_string[q] ); snprintf(s, 128, cl, i); strncat(s, "/elevation-ft", 128); fgSetDouble(s, cloud->getAltitude_ft() + station_elevation_ft); snprintf(s, 128, cl, i); strncat(s, "/thickness-ft", 128); fgSetDouble(s, thickness[q]); snprintf(s, 128, cl, i); strncat(s, "/span-m", 128); fgSetDouble(s, 40000.0); } for (; i < FGEnvironmentMgr::MAX_CLOUD_LAYERS; i++) { snprintf(s, 128, cl, i); strncat(s, "/coverage", 128); fgSetString(s, "clear"); snprintf(s, 128, cl, i); strncat(s, "/elevation-ft", 128); fgSetDouble(s, -9999); snprintf(s, 128, cl, i); strncat(s, "/thickness-ft", 128); fgSetDouble(s, 0); snprintf(s, 128, cl, i); strncat(s, "/span-m", 128); fgSetDouble(s, 40000.0); } fgSetDouble("/environment/metar/rain-norm", m->getRain()); fgSetDouble("/environment/metar/hail-norm", m->getHail()); fgSetDouble("/environment/metar/snow-norm", m->getSnow()); fgSetBool("/environment/metar/snow-cover", m->getSnowCover()); } #if defined(ENABLE_THREADS) /** * */ void FGMetarEnvironmentCtrl::MetarThread::run() { pthread_cleanup_push( metar_cleanup_handler, fetcher ); while ( true ) { set_cancel( SGThread::CANCEL_DISABLE ); string icao = fetcher->request_queue.pop(); SG_LOG( SG_GENERAL, SG_INFO, "Thread: fetch metar data = " << icao ); FGMetarResult result = fetcher->fetch_data( icao ); set_cancel( SGThread::CANCEL_DEFERRED ); fetcher->result_queue.push( result ); } pthread_cleanup_pop(1); } /** * Ensure mutex is unlocked. */ void metar_cleanup_handler( void* arg ) { FGMetarEnvironmentCtrl* fetcher = (FGMetarEnvironmentCtrl*) arg; fetcher->mutex.unlock(); } #endif // ENABLE_THREADS // end of environment_ctrl.cxx