#include

#include #include #include #include #include #include "AIFlightPlan.hxx" #include "AIAircraft.hxx" using std::cerr; FGAIWaypoint::FGAIWaypoint() { latitude = 0; longitude = 0; altitude = 0; speed = 0; crossat = 0; finished = 0; gear_down = 0; flaps_down = 0; on_ground = 0; routeIndex = 0; time_sec = 0; trackLength = 0; } bool FGAIWaypoint::contains(string target) { size_t found = name.find(target); if (found == string::npos) return false; else return true; } FGAIFlightPlan::FGAIFlightPlan() { sid = 0; repeat = false; distance_to_go = 0; lead_distance = 0; start_time = 0; arrivalTime = 0; leg = 10; gateId = 0; lastNodeVisited = 0; taxiRoute = 0; wpt_iterator = waypoints.begin(); isValid = true; } FGAIFlightPlan::FGAIFlightPlan(const string& filename) { sid = 0; repeat = false; distance_to_go = 0; lead_distance = 0; start_time = 0; arrivalTime = 0; leg = 10; gateId = 0; lastNodeVisited = 0; taxiRoute = 0; SGPath path( globals->get_fg_root() ); path.append( ("/AI/FlightPlans/" + filename).c_str() ); SGPropertyNode root; try { readProperties(path.str(), &root); } catch (const sg_exception &) { SG_LOG(SG_AI, SG_ALERT, "Error reading AI flight plan: " << path.str()); // cout << path.str() << endl; return; } SGPropertyNode * node = root.getNode("flightplan"); for (int i = 0; i < node->nChildren(); i++) { //cout << "Reading waypoint " << i << endl; FGAIWaypoint* wpt = new FGAIWaypoint; SGPropertyNode * wpt_node = node->getChild(i); wpt->setName (wpt_node->getStringValue("name", "END" )); wpt->setLatitude (wpt_node->getDoubleValue("lat", 0 )); wpt->setLongitude (wpt_node->getDoubleValue("lon", 0 )); wpt->setAltitude (wpt_node->getDoubleValue("alt", 0 )); wpt->setSpeed (wpt_node->getDoubleValue("ktas", 0 )); wpt->setCrossat (wpt_node->getDoubleValue("crossat", -10000 )); wpt->setGear_down (wpt_node->getBoolValue("gear-down", false )); wpt->setFlaps_down (wpt_node->getBoolValue("flaps-down", false )); wpt->setOn_ground (wpt_node->getBoolValue("on-ground", false )); wpt->setTime_sec (wpt_node->getDoubleValue("time-sec", 0 )); wpt->setTime (wpt_node->getStringValue("time", "" )); if (wpt->getName() == "END") wpt->setFinished(true); else wpt->setFinished(false); pushBackWaypoint( wpt ); } wpt_iterator = waypoints.begin(); isValid = true; //cout << waypoints.size() << " waypoints read." << endl; } // This is a modified version of the constructor, // Which not only reads the waypoints from a // Flight plan file, but also adds the current // Position computed by the traffic manager, as well // as setting speeds and altitude computed by the // traffic manager. FGAIFlightPlan::FGAIFlightPlan(FGAIAircraft *ac, const std::string& p, double course, time_t start, FGAirport *dep, FGAirport *arr, bool firstLeg, double radius, double alt, double lat, double lon, double speed, const string& fltType, const string& acType, const string& airline) { sid = 0; repeat = false; distance_to_go = 0; lead_distance = 0; start_time = start; arrivalTime = 0; leg = 10; gateId = 0; lastNodeVisited = 0; taxiRoute = 0; SGPath path( globals->get_fg_root() ); path.append( "/AI/FlightPlans" ); path.append( p ); SGPropertyNode root; isValid = true; // This is a bit of a hack: // Normally the value of course will be used to evaluate whether // or not a waypoint will be used for midair initialization of // an AI aircraft. However, if a course value of 999 will be passed // when an update request is received, which will by definition always be // on the ground and should include all waypoints. // bool useInitialWayPoint = true; // bool useCurrentWayPoint = false; // if (course == 999) // { // useInitialWayPoint = false; // useCurrentWayPoint = true; // } if (path.exists()) { try { readProperties(path.str(), &root); SGPropertyNode * node = root.getNode("flightplan"); //pushBackWaypoint( init_waypoint ); for (int i = 0; i < node->nChildren(); i++) { //cout << "Reading waypoint " << i << endl; FGAIWaypoint* wpt = new FGAIWaypoint; SGPropertyNode * wpt_node = node->getChild(i); wpt->setName (wpt_node->getStringValue("name", "END" )); wpt->setLatitude (wpt_node->getDoubleValue("lat", 0 )); wpt->setLongitude (wpt_node->getDoubleValue("lon", 0 )); wpt->setAltitude (wpt_node->getDoubleValue("alt", 0 )); wpt->setSpeed (wpt_node->getDoubleValue("ktas", 0 )); wpt->setCrossat (wpt_node->getDoubleValue("crossat", -10000 )); wpt->setGear_down (wpt_node->getBoolValue("gear-down", false )); wpt->setFlaps_down (wpt_node->getBoolValue("flaps-down", false )); if (wpt->getName() == "END") wpt->setFinished(true); else wpt->setFinished(false); pushBackWaypoint(wpt); } // of node loop wpt_iterator = waypoints.begin(); } catch (const sg_exception &e) { SG_LOG(SG_AI, SG_WARN, "Error reading AI flight plan: " << e.getMessage() << " from " << e.getOrigin()); } } else { // cout << path.str() << endl; // cout << "Trying to create this plan dynamically" << endl; // cout << "Route from " << dep->id << " to " << arr->id << endl; time_t now = time(NULL) + fgGetLong("/sim/time/warp"); time_t timeDiff = now-start; leg = 1; if ((timeDiff > 60) && (timeDiff < 1500)) leg = 2; //else if ((timeDiff >= 1200) && (timeDiff < 1500)) { //leg = 3; //ac->setTakeOffStatus(2); //} else if ((timeDiff >= 1500) && (timeDiff < 2000)) leg = 4; else if (timeDiff >= 2000) leg = 5; /* if (timeDiff >= 2000) leg = 5; */ SG_LOG(SG_AI, SG_INFO, "Route from " << dep->getId() << " to " << arr->getId() << ". Set leg to : " << leg << " " << ac->getTrafficRef()->getCallSign()); wpt_iterator = waypoints.begin(); bool dist = 0; isValid = create(ac, dep,arr, leg, alt, speed, lat, lon, firstLeg, radius, fltType, acType, airline, dist); wpt_iterator = waypoints.begin(); } } FGAIFlightPlan::~FGAIFlightPlan() { deleteWaypoints(); delete taxiRoute; } FGAIWaypoint* const FGAIFlightPlan::getPreviousWaypoint( void ) const { if (wpt_iterator == waypoints.begin()) { return 0; } else { wpt_vector_iterator prev = wpt_iterator; return *(--prev); } } FGAIWaypoint* const FGAIFlightPlan::getCurrentWaypoint( void ) const { return *wpt_iterator; } FGAIWaypoint* const FGAIFlightPlan::getNextWaypoint( void ) const { wpt_vector_iterator i = waypoints.end(); i--; // end() points to one element after the last one. if (wpt_iterator == i) { return 0; } else { wpt_vector_iterator next = wpt_iterator; return *(++next); } } void FGAIFlightPlan::IncrementWaypoint(bool eraseWaypoints ) { if (eraseWaypoints) { if (wpt_iterator == waypoints.begin()) wpt_iterator++; else { delete *(waypoints.begin()); waypoints.erase(waypoints.begin()); wpt_iterator = waypoints.begin(); wpt_iterator++; } } else wpt_iterator++; } void FGAIFlightPlan::DecrementWaypoint(bool eraseWaypoints ) { if (eraseWaypoints) { if (wpt_iterator == waypoints.end()) wpt_iterator--; else { delete *(waypoints.end()); waypoints.erase(waypoints.end()); wpt_iterator = waypoints.end(); wpt_iterator--; } } else wpt_iterator--; } void FGAIFlightPlan::eraseLastWaypoint() { delete (waypoints.back()); waypoints.pop_back();; wpt_iterator = waypoints.begin(); wpt_iterator++; } // gives distance in feet from a position to a waypoint double FGAIFlightPlan::getDistanceToGo(double lat, double lon, FGAIWaypoint* wp) const{ return SGGeodesy::distanceM(SGGeod::fromDeg(lon, lat), SGGeod::fromDeg(wp->getLongitude(), wp->getLatitude())); } // sets distance in feet from a lead point to the current waypoint void FGAIFlightPlan::setLeadDistance(double speed, double bearing, FGAIWaypoint* current, FGAIWaypoint* next){ double turn_radius; // Handle Ground steering // At a turn rate of 30 degrees per second, it takes 12 seconds to do a full 360 degree turn // So, to get an estimate of the turn radius, calculate the cicumference of the circle // we travel on. Get the turn radius by dividing by PI (*2). if (speed < 0.5) { lead_distance = 0.5; return; } if (speed < 25) { turn_radius = ((360/30)*fabs(speed)) / (2*M_PI); } else turn_radius = 0.1911 * speed * speed; // an estimate for 25 degrees bank double inbound = bearing; double outbound = getBearing(current, next); leadInAngle = fabs(inbound - outbound); if (leadInAngle > 180.0) leadInAngle = 360.0 - leadInAngle; //if (leadInAngle < 30.0) // To prevent lead_dist from getting so small it is skipped // leadInAngle = 30.0; //lead_distance = turn_radius * sin(leadInAngle * SG_DEGREES_TO_RADIANS); lead_distance = turn_radius * tan((leadInAngle * SG_DEGREES_TO_RADIANS)/2); /* if ((lead_distance > (3*turn_radius)) && (current->on_ground == false)) { // cerr << "Warning: Lead-in distance is large. Inbound = " << inbound // << ". Outbound = " << outbound << ". Lead in angle = " << leadInAngle << ". Turn radius = " << turn_radius << endl; lead_distance = 3 * turn_radius; return; } if ((leadInAngle > 90) && (current->on_ground == true)) { lead_distance = turn_radius * tan((90 * SG_DEGREES_TO_RADIANS)/2); return; }*/ } void FGAIFlightPlan::setLeadDistance(double distance_ft){ lead_distance = distance_ft; } double FGAIFlightPlan::getBearing(FGAIWaypoint* first, FGAIWaypoint* second) const{ return getBearing(first->getLatitude(), first->getLongitude(), second); } double FGAIFlightPlan::getBearing(double lat, double lon, FGAIWaypoint* wp) const{ return SGGeodesy::courseDeg(SGGeod::fromDeg(lon, lat), SGGeod::fromDeg(wp->getLongitude(), wp->getLatitude())); } void FGAIFlightPlan::deleteWaypoints() { for (wpt_vector_iterator i = waypoints.begin(); i != waypoints.end();i++) delete (*i); waypoints.clear(); } // Delete all waypoints except the last, // which we will recycle as the first waypoint in the next leg; void FGAIFlightPlan::resetWaypoints() { if (waypoints.begin() == waypoints.end()) return; else { FGAIWaypoint *wpt = new FGAIWaypoint; wpt_vector_iterator i = waypoints.end(); i--; wpt->setName ( (*i)->getName() ); wpt->setLatitude ( (*i)->getLatitude() ); wpt->setLongitude ( (*i)->getLongitude() ); wpt->setAltitude ( (*i)->getAltitude() ); wpt->setSpeed ( (*i)->getSpeed() ); wpt->setCrossat ( (*i)->getCrossat() ); wpt->setGear_down ( (*i)->getGear_down() ); wpt->setFlaps_down ( (*i)->getFlaps_down() ); wpt->setFinished ( false ); wpt->setOn_ground ( (*i)->getOn_ground() ); //cerr << "Recycling waypoint " << wpt->name << endl; deleteWaypoints(); pushBackWaypoint(wpt); } } void FGAIFlightPlan::pushBackWaypoint(FGAIWaypoint *wpt) { // std::vector::push_back invalidates waypoints // so we should restore wpt_iterator after push_back // (or it could be an index in the vector) size_t pos = wpt_iterator - waypoints.begin(); waypoints.push_back(wpt); wpt_iterator = waypoints.begin() + pos; } // Start flightplan over from the beginning void FGAIFlightPlan::restart() { wpt_iterator = waypoints.begin(); } void FGAIFlightPlan::deleteTaxiRoute() { delete taxiRoute; taxiRoute = 0; } int FGAIFlightPlan::getRouteIndex(int i) { if ((i > 0) && (i < (int)waypoints.size())) { return waypoints[i]->getRouteIndex(); } else return 0; } double FGAIFlightPlan::checkTrackLength(string wptName) { // skip the first two waypoints: first one is behind, second one is partially done; double trackDistance = 0; wpt_vector_iterator wptvec = waypoints.begin(); wptvec++; wptvec++; while ((wptvec != waypoints.end()) && (!((*wptvec)->contains(wptName)))) { trackDistance += (*wptvec)->getTrackLength(); wptvec++; } if (wptvec == waypoints.end()) { trackDistance = 0; // name not found } return trackDistance; } void FGAIFlightPlan::shortenToFirst(unsigned int number, string name) { while (waypoints.size() > number + 3) { eraseLastWaypoint(); } (waypoints.back())->setName((waypoints.back())->getName() + name); }