void Simulation::UpdateFlowAtDoors(const Pedestrian& ped) const { if (_config->ShowStatistics()) { Transition* trans = _building->GetTransitionByUID(ped.GetExitIndex()); if (trans) { //check if the pedestrian left the door correctly if (trans->DistTo(ped.GetPos())>0.5) { Log->Write("WARNING:\t pedestrian [%d] left room/subroom [%d/%d] in an unusual way. Please check", ped.GetID(), ped.GetRoomID(), ped.GetSubRoomID()); Log->Write(" :\t distance to last door (%d | %d) is %f. That should be smaller.", trans->GetUniqueID(), ped.GetExitIndex(), trans->DistTo(ped.GetPos())); Log->Write(" :\t correcting the door statistics"); //ped.Dump(ped.GetID()); //checking the history and picking the nearest previous destination double biggest = 0.3; bool success = false; for (const auto& dest:ped.GetLastDestinations()) { if (dest!=-1) { Transition* trans_tmp = _building->GetTransitionByUID(dest); if (trans_tmp && trans_tmp->DistTo(ped.GetPos())<biggest) { biggest = trans_tmp->DistTo(ped.GetPos()); trans = trans_tmp; Log->Write(" :\t Best match found at door %d", dest); success = true;//at least one door was found } } } if (!success) { Log->Write("WARNING :\t correcting the door statistics"); return; //todo we need to check if the ped is in a subroom neighboring the target. If so, no problems! } } //#pragma omp critical trans->IncreaseDoorUsage(1, ped.GetGlobalTime()); } } }
void VelocityModel::ComputeNextTimeStep(double current, double deltaT, Building* building, int periodic) { double delta = 0.5; // collect all pedestrians in the simulation. const vector< Pedestrian* >& allPeds = building->GetAllPedestrians(); unsigned long nSize; nSize = allPeds.size(); int nThreads = omp_get_max_threads(); //nThreads = 1; //debug only int partSize; partSize = (int) (nSize / nThreads); #pragma omp parallel default(shared) num_threads(nThreads) { vector< Point > result_acc = vector<Point > (); result_acc.reserve(nSize); vector< my_pair > spacings = vector<my_pair > (); spacings.reserve(nSize); // larger than needed spacings.push_back(my_pair(100, 1)); // in case there are no neighbors const int threadID = omp_get_thread_num(); int start = threadID*partSize; int end; end = (threadID + 1) * partSize - 1; if ((threadID == nThreads - 1)) end = (int) (nSize - 1); for (int p = start; p <= end; ++p) { Pedestrian* ped = allPeds[p]; Room* room = building->GetRoom(ped->GetRoomID()); SubRoom* subroom = room->GetSubRoom(ped->GetSubRoomID()); double normVi = ped->GetV().ScalarProduct(ped->GetV()); //squared double HighVel = (ped->GetV0Norm() + delta) * (ped->GetV0Norm() + delta); //(v0+delta)^2 if (normVi > HighVel && ped->GetV0Norm() > 0) { fprintf(stderr, "WARNING: VelocityModel::ComputeNextTimeStep() actual velocity (%f) of iped %d " "is bigger than desired velocity (%f) at time: %fs\n", sqrt(normVi), ped->GetID(), ped->GetV0Norm(), current); // remove the pedestrian and abort Log->Write("\tERROR: ped [%d] was removed due to high velocity",ped->GetID()); building->DeletePedestrian(ped); exit(EXIT_FAILURE); } Point repPed = Point(0,0); vector<Pedestrian*> neighbours; building->GetGrid()->GetNeighbourhood(ped,neighbours); int size = (int) neighbours.size(); for (int i = 0; i < size; i++) { Pedestrian* ped1 = neighbours[i]; //if they are in the same subroom Point p1 = ped->GetPos(); Point p2 = ped1->GetPos(); //subrooms to consider when looking for neighbour for the 3d visibility vector<SubRoom*> emptyVector; emptyVector.push_back(subroom); emptyVector.push_back(building->GetRoom(ped1->GetRoomID())->GetSubRoom(ped1->GetSubRoomID())); bool isVisible = building->IsVisible(p1, p2, emptyVector, false); if (!isVisible) continue; if (ped->GetUniqueRoomID() == ped1->GetUniqueRoomID()) { repPed += ForceRepPed(ped, ped1, periodic); } else { // or in neighbour subrooms SubRoom* sb2=building->GetRoom(ped1->GetRoomID())->GetSubRoom(ped1->GetSubRoomID()); if(subroom->IsDirectlyConnectedWith(sb2)) { repPed += ForceRepPed(ped, ped1, periodic); } } } // for i //repulsive forces to walls and closed transitions that are not my target Point repWall = ForceRepRoom(allPeds[p], subroom); // calculate new direction ei according to (6) Point direction = e0(ped, room) + repPed + repWall; for (int i = 0; i < size; i++) { Pedestrian* ped1 = neighbours[i]; // calculate spacing // my_pair spacing_winkel = GetSpacing(ped, ped1); if (ped->GetUniqueRoomID() == ped1->GetUniqueRoomID()) { spacings.push_back(GetSpacing(ped, ped1, direction, periodic)); } else { // or in neighbour subrooms SubRoom* sb2=building->GetRoom(ped1->GetRoomID())->GetSubRoom(ped1->GetSubRoomID()); if(subroom->IsDirectlyConnectedWith(sb2)) { spacings.push_back(GetSpacing(ped, ped1, direction, periodic)); } } } // @todo: get spacing to walls // @todo: update direction every DT? // if(ped->GetID()==-10) // std::cout << "time: " << ped->GetGlobalTime() << " | updateRate " <<ped->GetUpdateRate() << " modulo " <<fmod(ped->GetGlobalTime(), ped->GetUpdateRate())<<std::endl; // calculate min spacing std::sort(spacings.begin(), spacings.end(), sort_pred()); double spacing = spacings[0].first; double winkel = spacings[0].second; Point tmp; // if(fmod(ped->GetGlobalTime(), ped->GetUpdateRate())<0.0001 || (spacing-ped->GetLastE0()._x)>0.01) // { // if(ped->GetID()==-10) // std::cout << "Min Spacing "<< spacing << ", " << winkel << std::endl; // ped->SetLastE0(Point(spacing, winkel)); // } // else // { // tmp = ped->GetLastE0(); // if(ped->GetID()==10) // std::cout << "keep direction "<<tmp._x << ", " << tmp._y << std::endl; // spacing = tmp._x; // winkel = tmp._y; // } // if(ped->GetID()==-10) // getc(stdin); // spacing = *std::min_element(std::begin(spacings), std::end(spacings)); // if(ped->GetID()==10){ // fprintf(stderr, "%f %f %f\n", ped->GetGlobalTime(), (repPed+repWall).Norm(), spacing); // } Point speed = direction.Normalized() * OptimalSpeed(ped, spacing, winkel); result_acc.push_back(speed); spacings.clear(); //clear for ped p } // for p //#pragma omp barrier // update for (int p = start; p <= end; ++p) { Pedestrian* ped = allPeds[p]; Point v_neu = result_acc[p - start]; Point pos_neu = ped->GetPos() + v_neu * deltaT; //Jam is based on the current velocity if ( v_neu.Norm() >= ped->GetV0Norm()*0.5) { ped->ResetTimeInJam(); } else { ped->UpdateTimeInJam(); } //only update the position if the velocity is above a threshold if (v_neu.Norm() >= J_EPS_V) { ped->SetPhiPed(); } ped->SetPos(pos_neu); if(periodic){ if(ped->GetPos()._x >= xRight){ ped->SetPos(Point(ped->GetPos()._x - (xRight - xLeft), ped->GetPos()._y)); //ped->SetID( ped->GetID() + 1); } } ped->SetV(v_neu); } }//end parallel }