void DownlinkPacketScheduler::SelectFlowsToSchedule () { #ifdef SCHEDULER_DEBUG std::cout << "\t Select Flows to schedule" << std::endl; #endif ClearFlowsToSchedule (); RrcEntity *rrc = GetMacEntity ()->GetDevice ()->GetProtocolStack ()->GetRrcEntity (); RrcEntity::RadioBearersContainer* bearers = rrc->GetRadioBearerContainer (); for (std::vector<RadioBearer* >::iterator it = bearers->begin (); it != bearers->end (); it++) { //SELECT FLOWS TO SCHEDULE RadioBearer *bearer = (*it); if (bearer->HasPackets () && bearer->GetDestination ()->GetNodeState () == NetworkNode::STATE_ACTIVE) { //compute data to transmit int dataToTransmit; if (bearer->GetApplication ()->GetApplicationType () == Application::APPLICATION_TYPE_INFINITE_BUFFER) { dataToTransmit = 100000000; } else { dataToTransmit = bearer->GetQueueSize (); } //compute spectral efficiency ENodeB *enb = (ENodeB*) GetMacEntity ()->GetDevice (); ENodeB::UserEquipmentRecord *ueRecord = enb->GetUserEquipmentRecord (bearer->GetDestination ()->GetIDNetworkNode ()); std::vector<double> spectralEfficiency; std::vector<int> cqiFeedbacks = ueRecord->GetCQI (); int numberOfCqi = cqiFeedbacks.size (); for (int i = 0; i < numberOfCqi; i++) { double sEff = GetMacEntity ()->GetAmcModule ()->GetEfficiencyFromCQI (cqiFeedbacks.at (i)); spectralEfficiency.push_back (sEff); } //create flow to scheduler record InsertFlowToSchedule(bearer, dataToTransmit, spectralEfficiency, cqiFeedbacks); } else {} } }
bool PowerBasedHoManager::CheckHandoverNeed (UserEquipment* ue) { /*//test RX cqi success? std::cout<<"PBHM: UE "<<ue->GetIDNetworkNode(); ENodeB *testenb=nm->GetENodeBByID(ue->GetTargetNode()->GetIDNetworkNode()); std::vector<int> testtemp=testenb->GetUserEquipmentRecord(ue->GetIDNetworkNode())->GetCQI(); int testj=0; for(std::vector<int>::iterator testit=testtemp.begin();testit!=testtemp.end();testit++,testj++){ std::cout<<"cqi="<<testtemp.at(testj)<<std::endl; }*/ return false; //std::cout<<"power based ho"<<std::endl;//test /* NetworkNode *targetNode = ue->GetTargetNode (); double TXpower = 10 * log10 ( pow (10., (targetNode->GetPhy()->GetTxPower() - 30)/10) / targetNode->GetPhy()->GetBandwidthManager()->GetDlSubChannels().size () ); double pathLoss = ComputePathLossForInterference(targetNode, ue); double targetRXpower = TXpower - pathLoss; double RXpower; std::vector<ENodeB*> *listOfNodes = NetworkManager::Init ()->GetENodeBContainer (); std::vector<ENodeB*>::iterator it; for (it = listOfNodes->begin (); it != listOfNodes->end (); it++) { if ((*it)->GetIDNetworkNode () != targetNode->GetIDNetworkNode () ) { NetworkNode *probableNewTargetNode = (*it); TXpower = 10 * log10 ( pow (10., (probableNewTargetNode->GetPhy()->GetTxPower() - 30)/10) / probableNewTargetNode->GetPhy()->GetBandwidthManager()->GetDlSubChannels().size () ); pathLoss = ComputePathLossForInterference(probableNewTargetNode, ue); RXpower = TXpower - pathLoss; if (RXpower > targetRXpower) { if (NetworkManager::Init()->CheckHandoverPermissions(probableNewTargetNode,ue)) { targetRXpower = RXpower; targetNode = probableNewTargetNode; } } } } std::vector<HeNodeB*> *listOfNodes2 = NetworkManager::Init ()->GetHomeENodeBContainer(); std::vector<HeNodeB*>::iterator it2; for (it2 = listOfNodes2->begin (); it2 != listOfNodes2->end (); it2++) { if ((*it2)->GetIDNetworkNode () != targetNode->GetIDNetworkNode () ) { NetworkNode *probableNewTargetNode = (*it2); TXpower = 10 * log10 ( pow (10., (probableNewTargetNode->GetPhy()->GetTxPower() - 30)/10) / probableNewTargetNode->GetPhy()->GetBandwidthManager()->GetDlSubChannels().size () ); pathLoss = ComputePathLossForInterference(probableNewTargetNode, ue); RXpower = TXpower - pathLoss; if (RXpower > targetRXpower) { if (NetworkManager::Init()->CheckHandoverPermissions(probableNewTargetNode,ue)) { targetRXpower = RXpower; targetNode = probableNewTargetNode; } } } } if (ue->GetTargetNode ()->GetIDNetworkNode () != targetNode->GetIDNetworkNode ()) { m_target = targetNode; return true; } else { return false; }*/ //mouan //NetworkNode *targetNode = ue->GetTargetNode (); NetworkNode *targetNode; //if(targetNode->GetNodeType()==NetworkNode::TYPE_ENODEB){ std::cout<<"enb vs ue"<<std::endl;//test ENodeB *targetenb; int compare[2]; int selected_bus_id=0; { std::vector<ENodeB *> *enbs=nm->GetENodeBContainer(); double mindis=9999999.0; for(std::vector<ENodeB *>::iterator ie=enbs->begin();ie!=enbs->end();ie++){ CartesianCoordinates *dis=(*ie)->GetCell()->GetCellCenterPosition(); double temp=dis->GetDistance(ue->GetMobilityModel()->GetAbsolutePosition()); if(mindis>temp){ mindis=temp; targetenb=(*ie); } } if(targetenb==NULL){ std::cout<<"ERROR! targetenb==NULL"<<std::endl; } else{ targetNode=nm->GetNetworkNodeByID(targetenb->GetIDNetworkNode()); } //ENodeB *targetenb=nm->GetENodeBByID(targetNode->GetIDNetworkNode()); //std::vector<int> uecqi=targetenb->GetUserEquipmentRecord(ue->GetIDNetworkNode())->GetCQI(); std::vector<double> mouan_bstoueSinr; std::vector<double> rxSignalValues; std::vector<double>::iterator it; rxSignalValues = ue->GetPhy()->GetTxSignal()->Getvalues(); //compute noise + interference double interference; if (ue->GetPhy()->GetInterference () != NULL) { ENodeB *node; interference = 0; std::vector<ENodeB*> *eNBs = NetworkManager::Init ()->GetENodeBContainer (); std::vector<ENodeB*>::iterator it; //std::cout << "Compute interference for UE " << ue->GetIDNetworkNode () << " ,target node " << ue->GetTargetNode ()->GetIDNetworkNode ()<< std::endl; for (it = eNBs->begin (); it != eNBs->end (); it++) { node = (*it); if (node->GetIDNetworkNode () != targetenb->GetIDNetworkNode () && node->GetPhy ()->GetBandwidthManager ()->GetUlOffsetBw () == ue->GetTargetNode ()->GetPhy ()->GetBandwidthManager ()->GetUlOffsetBw ()) { double powerTXForSubBandwidth = 10 * log10 ( pow (10., (node->GetPhy()->GetTxPower() - 30)/10) / node->GetPhy()->GetBandwidthManager ()->GetUlSubChannels().size ()); double nodeInterference_db = powerTXForSubBandwidth - 10 - ComputePathLossForInterference (node, ue); // in dB double nodeInterference = pow(10, nodeInterference_db/10); interference += nodeInterference; /* std::cout << "\t add interference from eNB " << node->GetIDNetworkNode () << " " << powerTXForSubBandwidth << " " << ComputePathLossForInterference (node, ue) << " " << nodeInterference_db << " " << nodeInterference << " --> tot: " << interference << std::endl; */ } } } else { interference = 0; } double noise_interference = 10. * log10 (pow(10., -148.95/10) + interference); // dB for (it = rxSignalValues.begin(); it != rxSignalValues.end(); it++) { double power; // power transmission for the current sub channel [dB] if ((*it) != 0.) { power = (*it); } else { power = 0.; } mouan_bstoueSinr.push_back (power - noise_interference); } AMCModule *amc = ue->GetProtocolStack ()->GetMacEntity ()->GetAmcModule (); std::vector<int> uecqi = amc->CreateCqiFeedbacks (mouan_bstoueSinr); /*std::vector<double> spectralEfficiency; //std::vector<int> cqiFeedbacks = ueRecord->GetCQI (); int numberOfCqi = uecqi.size (); for (int i = 0; i < numberOfCqi; i++) { double sEff = GetMacEntity ()->GetAmcModule ()->GetEfficiencyFromCQI (uecqi.at (i)); spectralEfficiency.push_back (sEff);//i didn't do * 180000.0,because just for compare }*/ //copy start (from enhance-uplink-scheduler.cpp) UplinkPacketScheduler *ulps=targetenb->GetULScheduler(); UplinkPacketScheduler::UsersToSchedule *users = ulps->GetUsersToSchedule(); UplinkPacketScheduler::UserToSchedule* scheduledUser; int nbOfRBs = ulps->GetMacEntity()->GetDevice ()->GetPhy ()->GetBandwidthManager ()->GetUlSubChannels ().size (); int availableRBs; // No of RB's not allocated int unallocatedUsers; // No of users who remain unallocated int selectedUser; // user to be selected for allocation int selectedPRB; // PRB to be selected for allocation double bestMetric; // best metric to identify user/RB combination int left, right; // index of left and left PRB's to check if(nbOfRBs>1000||users->size()>1000){ std::cout<<"ERROR! some value wrong."<<std::endl; return false; } bool Allocated[nbOfRBs]; bool allocationMade; double metrics[nbOfRBs][users->size ()]; int requiredPRBs[users->size ()]; //std::vector<int> m_mouan; int m_mouan[users->size()]; int ueat=-1; //test int tt=0; for(UplinkPacketScheduler::UsersToSchedule::iterator test=users->begin();test!=users->end();test++){ tt++; } std::cout<<"3:"<<users->size()<<"="<<tt<<std::endl;//test for(int i=0 ; i < users->size() ; i++){ std::cout<<"A ";//test m_mouan[i]=0; } std::cout<<"3end"<<std::endl;//test std::cout<<"4"<<std::endl;//test //Some initialization availableRBs = nbOfRBs; unallocatedUsers = users->size (); for(int i=0; i < nbOfRBs; i++) Allocated[i] = false; //create a matrix of flow metrics for (int i = 0; i < nbOfRBs; i++) { for (int j = 0; j < users->size (); j++) { //metrics[i][j] = ComputeSchedulingMetric (users->at (j), i); double spectralEfficiency = ulps->GetMacEntity ()->GetAmcModule ()->GetSinrFromCQI (uecqi.at(i)); metrics[i][j] = spectralEfficiency * 180000; } } std::cout<<"5"<<std::endl;//test //create number of required PRB's per scheduled users for(int j=0; j < users->size(); j++) { std::cout<<"1 "<<std::endl;//test scheduledUser = users->at(j); std::cout<<"2 "<<std::endl;//test std::vector<double> sinrs; for(int c=0;c<scheduledUser->m_channelContition.size();c++) //for (std::vector<int>::iterator c = scheduledUser->m_channelContition.begin (); // c != scheduledUser->m_channelContition.end (); c++) { //cout << *c <<" "; std::cout<<"a="<<c<<"="<<scheduledUser->m_channelContition.at(c)<<std::endl;//test std::cout<<"size="<<scheduledUser->m_channelContition.size()<<std::endl;//test std::cout<<"id="<<scheduledUser->m_userToSchedule->GetIDNetworkNode()<<std::endl;//test //if(scheduledUser->m_channelContition.at(c)>14)scheduledUser->m_channelContition.at(c)=14; //else if(scheduledUser->m_channelContition.at(c)<0)scheduledUser->m_channelContition.at(c)=0; if(scheduledUser->m_channelContition.at(c)>14||scheduledUser->m_channelContition.at(c)<0){ return false; } sinrs.push_back (ulps->GetMacEntity ()->GetAmcModule ()->GetSinrFromCQI (scheduledUser->m_channelContition.at(c))); std::cout<<"b "<<std::endl;//test } std::cout<<"3 "<<std::endl;//test double effectiveSinr = GetEesmEffectiveSinr (sinrs); std::cout<<"4 "<<std::endl;//test int mcs = ulps->GetMacEntity ()->GetAmcModule ()->GetMCSFromCQI ( ulps->GetMacEntity ()->GetAmcModule ()->GetCQIFromSinr (effectiveSinr)); //scheduledUser->m_selectedMCS = mcs; std::cout<<"5 "<<std::endl;//test requiredPRBs[j] = (floor) (scheduledUser->m_dataToTransmit / (ulps->GetMacEntity ()->GetAmcModule ()->GetTBSizeFromMCS (mcs, 1) / 8)); std::cout<<"6end"<<std::endl;//test } std::cout<<"6"<<std::endl;//test //RBs allocation while(availableRBs > 0 && unallocatedUsers > 0) // { // First step: find the best user-RB combo selectedPRB = -1; selectedUser = -1; bestMetric = (double) (-(1<<30)); for(int i=0; i < nbOfRBs; i++) { if (!Allocated[i]){ // check only unallocated PRB's for(int j=0; j < users->size (); j++) { if ( users->at (j)->m_listOfAllocatedRBs.size() == 0 && requiredPRBs[j] > 0) //only unallocated users requesting some RB's if (bestMetric < metrics[i][j]){ selectedPRB = i; selectedUser = j; bestMetric = metrics[i][j]; } } } } // Now start allocating for the selected user at the selected PRB the required blocks // using how many PRB's are needed for the user if (selectedUser != -1) { scheduledUser = users->at(selectedUser); //scheduledUser->m_listOfAllocatedRBs.push_back (selectedPRB); m_mouan[selectedUser]++; Allocated[selectedPRB] = true; left = selectedPRB - 1; right = selectedPRB + 1; availableRBs--; unallocatedUsers--; allocationMade = true; for(int i = 1; i < requiredPRBs[selectedUser] && availableRBs > 0 && allocationMade; i++ ) { // search right and left of initial allocation allocationMade = false; if (left >=0 && Allocated[left] && right < nbOfRBs && Allocated[right]) break; // nothing is available, since we need to have contiguous allocation if ( (right < nbOfRBs) && (! Allocated[right]) && ( ((left >=0) && (metrics[right][selectedUser] >= metrics[left][selectedUser])) // right is better than left || (left < 0) || Allocated[left]// OR no more left ) ) { //Allocate PRB at right to the user Allocated[right] = true; //scheduledUser->m_listOfAllocatedRBs.push_back (right); m_mouan[selectedUser]++; right++; allocationMade = true; availableRBs--; } else if ( (left >=0) && (! Allocated[left]) && ( ((right < nbOfRBs) && (metrics[left][selectedUser] > metrics[right][selectedUser])) //left better than right || (right >= nbOfRBs) || Allocated[right]// OR no more right ) ) { //Allocate PRB at left to the user Allocated[left] = true; //scheduledUser->m_listOfAllocatedRBs.push_back (left); m_mouan[selectedUser]++; left--; allocationMade = true; availableRBs--; } } // end of for if(scheduledUser->m_userToSchedule->GetIDNetworkNode()==ue->GetIDNetworkNode()){ ueat=selectedUser; printf("selected user %d is ueat\n",ueat);//test } } else { // nothing to do exit the allocation loop break; } } //while std::cout<<"7"<<std::endl;//test //copy end if(ueat==-1)return false;//temp compare[1]=m_mouan[ueat];//m_mouan[ueat];//bs vs ue result } std::cout<<"enb vs ue end"<<std::endl;//test //bus route std::vector<Bus *> *buses=nm->GetBusContainer(); std::vector<Bus *>::iterator select_bus; for(select_bus=buses->begin();select_bus != buses->end();select_bus++) { Bus *selectedbus=(*select_bus); std::vector<double> mouan_bustoueSinr; std::vector<double> rxSignalValues; std::vector<double>::iterator it; rxSignalValues = ue->GetPhy()->GetTxSignal()->Getvalues(); //compute noise + interference double interference; if (ue->GetPhy()->GetInterference () != NULL) { ENodeB *node; interference = 0; std::vector<ENodeB*> *eNBs = NetworkManager::Init ()->GetENodeBContainer (); std::vector<ENodeB*>::iterator it; //std::cout << "Compute interference for UE " << ue->GetIDNetworkNode () << " ,target node " << ue->GetTargetNode ()->GetIDNetworkNode ()<< std::endl; for (it = eNBs->begin (); it != eNBs->end (); it++) { node = (*it); if (//node->GetIDNetworkNode () != ue->GetTargetNode ()->GetIDNetworkNode () && node->GetPhy ()->GetBandwidthManager ()->GetUlOffsetBw () == ue->GetTargetNode ()->GetPhy ()->GetBandwidthManager ()->GetUlOffsetBw ()) { double powerTXForSubBandwidth = 10 * log10 ( pow (10., (node->GetPhy()->GetTxPower() - 30)/10) / node->GetPhy()->GetBandwidthManager ()->GetUlSubChannels().size ()); double nodeInterference_db = powerTXForSubBandwidth - 10 - ComputePathLossForInterference (node, ue); // in dB double nodeInterference = pow(10, nodeInterference_db/10); interference += nodeInterference; /* std::cout << "\t add interference from eNB " << node->GetIDNetworkNode () << " " << powerTXForSubBandwidth << " " << ComputePathLossForInterference (node, ue) << " " << nodeInterference_db << " " << nodeInterference << " --> tot: " << interference << std::endl; */ } } } else { interference = 0; } double noise_interference = 10. * log10 (pow(10., -148.95/10) + interference); // dB for (it = rxSignalValues.begin(); it != rxSignalValues.end(); it++) { double power; // power transmission for the current sub channel [dB] if ((*it) != 0.) { power = (*it); } else { power = 0.; } mouan_bustoueSinr.push_back (power - noise_interference); } AMCModule *amc = ue->GetProtocolStack ()->GetMacEntity ()->GetAmcModule (); std::vector<int> mouan_bustouecqi = amc->CreateCqiFeedbacks (mouan_bustoueSinr); //run the bus scheduler UplinkPacketScheduler *ulps=selectedbus->GetULScheduler(); UplinkPacketScheduler::UsersToSchedule *users = ulps->GetUsersToSchedule(); UplinkPacketScheduler::UserToSchedule* scheduledUser; int nbOfRBs = ulps->GetMacEntity()->GetDevice ()->GetPhy ()->GetBandwidthManager ()->GetUlSubChannels ().size (); int availableRBs; // No of RB's not allocated int unallocatedUsers; // No of users who remain unallocated int selectedUser; // user to be selected for allocation int selectedPRB; // PRB to be selected for allocation double bestMetric; // best metric to identify user/RB combination int left, right; // index of left and left PRB's to check bool Allocated[nbOfRBs]; bool allocationMade; double metrics[nbOfRBs][users->size ()]; int requiredPRBs[users->size ()]; //std::vector<int> m_mouan; int m_mouan[users->size()]; int ueat; for(int i=0;i<users->size();i++)m_mouan[i]=0; //Some initialization availableRBs = nbOfRBs; unallocatedUsers = users->size (); for(int i=0; i < nbOfRBs; i++) Allocated[i] = false; //create a matrix of flow metrics for (int i = 0; i < nbOfRBs; i++) { for (int j = 0; j < users->size (); j++) { //metrics[i][j] = ComputeSchedulingMetric (users->at (j), i); double spectralEfficiency = ulps->GetMacEntity ()->GetAmcModule ()->GetSinrFromCQI (mouan_bustouecqi.at(i)); metrics[i][j] = spectralEfficiency * 180000; } } //create number of required PRB's per scheduled users for(int j=0; j < users->size(); j++) { scheduledUser = users->at(j); std::vector<double> sinrs; for (std::vector<int>::iterator c = scheduledUser->m_channelContition.begin (); c != scheduledUser->m_channelContition.end (); c++) { //cout << *c <<" "; sinrs.push_back (ulps->GetMacEntity ()->GetAmcModule ()->GetSinrFromCQI (*c)); } double effectiveSinr = GetEesmEffectiveSinr (sinrs); int mcs = ulps->GetMacEntity ()->GetAmcModule ()->GetMCSFromCQI ( ulps->GetMacEntity ()->GetAmcModule ()->GetCQIFromSinr (effectiveSinr)); //scheduledUser->m_selectedMCS = mcs; requiredPRBs[j] = (floor) (scheduledUser->m_dataToTransmit / (ulps->GetMacEntity ()->GetAmcModule ()->GetTBSizeFromMCS (mcs, 1) / 8)); } //RBs allocation while(availableRBs > 0 && unallocatedUsers > 0) // { // First step: find the best user-RB combo selectedPRB = -1; selectedUser = -1; bestMetric = (double) (-(1<<30)); for(int i=0; i < nbOfRBs; i++) { if (!Allocated[i]){ // check only unallocated PRB's for(int j=0; j < users->size (); j++) { if ( users->at (j)->m_listOfAllocatedRBs.size() == 0 && requiredPRBs[j] > 0) //only unallocated users requesting some RB's if (bestMetric < metrics[i][j]){ selectedPRB = i; selectedUser = j; bestMetric = metrics[i][j]; } } } } // Now start allocating for the selected user at the selected PRB the required blocks // using how many PRB's are needed for the user if (selectedUser != -1) { scheduledUser = users->at(selectedUser); //scheduledUser->m_listOfAllocatedRBs.push_back (selectedPRB); m_mouan[selectedUser]++; Allocated[selectedPRB] = true; left = selectedPRB - 1; right = selectedPRB + 1; availableRBs--; unallocatedUsers--; allocationMade = true; for(int i = 1; i < requiredPRBs[selectedUser] && availableRBs > 0 && allocationMade; i++ ) { // search right and left of initial allocation allocationMade = false; if (left >=0 && Allocated[left] && right < nbOfRBs && Allocated[right]) break; // nothing is available, since we need to have contiguous allocation if ( (right < nbOfRBs) && (! Allocated[right]) && ( ((left >=0) && (metrics[right][selectedUser] >= metrics[left][selectedUser])) // right is better than left || (left < 0) || Allocated[left]// OR no more left ) ) { //Allocate PRB at right to the user Allocated[right] = true; //scheduledUser->m_listOfAllocatedRBs.push_back (right); m_mouan[selectedUser]++; right++; allocationMade = true; availableRBs--; } else if ( (left >=0) && (! Allocated[left]) && ( ((right < nbOfRBs) && (metrics[left][selectedUser] > metrics[right][selectedUser])) //left better than right || (right >= nbOfRBs) || Allocated[right]// OR no more right ) ) { //Allocate PRB at left to the user Allocated[left] = true; //scheduledUser->m_listOfAllocatedRBs.push_back (left); m_mouan[selectedUser]++; left--; allocationMade = true; availableRBs--; } } // end of for if(scheduledUser->m_userToSchedule->GetIDNetworkNode()==ue->GetIDNetworkNode()){ ueat=selectedUser; printf("selected user %d is ueat\n",ueat);//test } } else { // nothing to do exit the allocation loop break; } }//end while if(m_mouan[ueat]>compare[0]){ compare[0]=m_mouan[ueat];//bus vs ue selected_bus_id=selectedbus->GetIDNetworkNode(); } }//end for std::cout<<"bus vs ue end"<<std::endl;//test //bus vs bs { //ENodeB *targetenb=nm->GetENodeBByID(targetNode->GetIDNetworkNode()); std::vector<int> buscqi=targetenb->GetUserEquipmentRecord(selected_bus_id)->GetCQI(); /*std::vector<double> spectralEfficiency; //std::vector<int> cqiFeedbacks = ueRecord->GetCQI (); int numberOfCqi = uecqi.size (); for (int i = 0; i < numberOfCqi; i++) { double sEff = GetMacEntity ()->GetAmcModule ()->GetEfficiencyFromCQI (uecqi.at (i)); spectralEfficiency.push_back (sEff);//i didn't do * 180000.0,because just for compare }*/ //copy start (from enhance-uplink-scheduler.cpp) UplinkPacketScheduler *ulps=targetenb->GetULScheduler(); UplinkPacketScheduler::UsersToSchedule *users = ulps->GetUsersToSchedule(); UplinkPacketScheduler::UserToSchedule* scheduledUser; int nbOfRBs = ulps->GetMacEntity()->GetDevice ()->GetPhy ()->GetBandwidthManager ()->GetUlSubChannels ().size (); int availableRBs; // No of RB's not allocated int unallocatedUsers; // No of users who remain unallocated int selectedUser; // user to be selected for allocation int selectedPRB; // PRB to be selected for allocation double bestMetric; // best metric to identify user/RB combination int left, right; // index of left and left PRB's to check bool Allocated[nbOfRBs]; bool allocationMade; double metrics[nbOfRBs][users->size ()]; int requiredPRBs[users->size ()]; //std::vector<int> m_mouan; int m_mouan[users->size()]; int busat; for(int i=0;i<users->size();i++)m_mouan[i]=0; //Some initialization availableRBs = nbOfRBs; unallocatedUsers = users->size (); for(int i=0; i < nbOfRBs; i++) Allocated[i] = false; //create a matrix of flow metrics for (int i = 0; i < nbOfRBs; i++) { for (int j = 0; j < users->size (); j++) { //metrics[i][j] = ComputeSchedulingMetric (users->at (j), i); double spectralEfficiency = ulps->GetMacEntity ()->GetAmcModule ()->GetSinrFromCQI (buscqi.at(i)); metrics[i][j] = spectralEfficiency * 180000; } } //create number of required PRB's per scheduled users for(int j=0; j < users->size(); j++) { scheduledUser = users->at(j); std::vector<double> sinrs; for (std::vector<int>::iterator c = scheduledUser->m_channelContition.begin (); c != scheduledUser->m_channelContition.end (); c++) { //cout << *c <<" "; sinrs.push_back (ulps->GetMacEntity ()->GetAmcModule ()->GetSinrFromCQI (*c)); } double effectiveSinr = GetEesmEffectiveSinr (sinrs); int mcs = ulps->GetMacEntity ()->GetAmcModule ()->GetMCSFromCQI ( ulps->GetMacEntity ()->GetAmcModule ()->GetCQIFromSinr (effectiveSinr)); //scheduledUser->m_selectedMCS = mcs; requiredPRBs[j] = (floor) (scheduledUser->m_dataToTransmit / (ulps->GetMacEntity ()->GetAmcModule ()->GetTBSizeFromMCS (mcs, 1) / 8)); } //RBs allocation while(availableRBs > 0 && unallocatedUsers > 0) // { // First step: find the best user-RB combo selectedPRB = -1; selectedUser = -1; bestMetric = (double) (-(1<<30)); for(int i=0; i < nbOfRBs; i++) { if (!Allocated[i]){ // check only unallocated PRB's for(int j=0; j < users->size (); j++) { if ( users->at (j)->m_listOfAllocatedRBs.size() == 0 && requiredPRBs[j] > 0) //only unallocated users requesting some RB's if (bestMetric < metrics[i][j]){ selectedPRB = i; selectedUser = j; bestMetric = metrics[i][j]; } } } } // Now start allocating for the selected user at the selected PRB the required blocks // using how many PRB's are needed for the user if (selectedUser != -1) { scheduledUser = users->at(selectedUser); //scheduledUser->m_listOfAllocatedRBs.push_back (selectedPRB); m_mouan[selectedUser]++; Allocated[selectedPRB] = true; left = selectedPRB - 1; right = selectedPRB + 1; availableRBs--; unallocatedUsers--; allocationMade = true; for(int i = 1; i < requiredPRBs[selectedUser] && availableRBs > 0 && allocationMade; i++ ) { // search right and left of initial allocation allocationMade = false; if (left >=0 && Allocated[left] && right < nbOfRBs && Allocated[right]) break; // nothing is available, since we need to have contiguous allocation if ( (right < nbOfRBs) && (! Allocated[right]) && ( ((left >=0) && (metrics[right][selectedUser] >= metrics[left][selectedUser])) // right is better than left || (left < 0) || Allocated[left]// OR no more left ) ) { //Allocate PRB at right to the user Allocated[right] = true; //scheduledUser->m_listOfAllocatedRBs.push_back (right); m_mouan[selectedUser]++; right++; allocationMade = true; availableRBs--; } else if ( (left >=0) && (! Allocated[left]) && ( ((right < nbOfRBs) && (metrics[left][selectedUser] > metrics[right][selectedUser])) //left better than right || (right >= nbOfRBs) || Allocated[right]// OR no more right ) ) { //Allocate PRB at left to the user Allocated[left] = true; //scheduledUser->m_listOfAllocatedRBs.push_back (left); m_mouan[selectedUser]++; left--; allocationMade = true; availableRBs--; } } // end of for if(scheduledUser->m_userToSchedule->GetIDNetworkNode()==selected_bus_id){ busat=selectedUser; printf("selected bus %d is busat\n",busat);//test } } else { // nothing to do exit the allocation loop break; } } //while //copy end if(compare[0]>m_mouan[busat]){ compare[0]=m_mouan[busat]; } //compare[1]=m_mouan[ueat];//m_mouan[ueat];//bs vs ue result } if(compare[0]>compare[1]){//using bs if(ue->GetTargetNode()->GetIDNetworkNode()==targetenb->GetIDNetworkNode()){ return false; } else{ m_target=nm->GetNetworkNodeByID(targetenb->GetIDNetworkNode()); //std::cout<<"HO TRUE"<<std::endl;//test NetworkNode* newTagertNode = m_target; #ifdef HANDOVER_DEBUG std::cout << "** HO ** \t time: " << time << " user " << ue->GetIDNetworkNode () << " old eNB " << targetNode->GetIDNetworkNode () << " new eNB " << newTagertNode->GetIDNetworkNode () << std::endl; #endif double time=0; nm->HandoverProcedure(time, ue, targetNode, newTagertNode); return true; } } else{//using bus if(ue->GetTargetNode()->GetIDNetworkNode()==selected_bus_id){ return false; } else{ m_target=nm->GetNetworkNodeByID(selected_bus_id); //std::cout<<"HO TRUE"<<std::endl;//test NetworkNode* newTagertNode = m_target; #ifdef HANDOVER_DEBUG std::cout << "** HO ** \t time: " << time << " user " << ue->GetIDNetworkNode () << " old eNB " << targetNode->GetIDNetworkNode () << " new eNB " << newTagertNode->GetIDNetworkNode () << std::endl; #endif double time=0; nm->HandoverProcedure(time, ue, targetNode, newTagertNode); return true; } } //std::cout<<"enb vs bus end"<<std::endl;//test /*} else{//default bus route ; } double TXpower = 10 * log10 ( pow (10., (targetNode->GetPhy()->GetTxPower() - 30)/10) / targetNode->GetPhy()->GetBandwidthManager()->GetDlSubChannels().size () ); double pathLoss = ComputePathLossForInterference(targetNode, ue); double targetRXpower = TXpower - pathLoss; double RXpower; std::vector<ENodeB*> *listOfNodes = NetworkManager::Init ()->GetENodeBContainer (); std::vector<ENodeB*>::iterator it; for (it = listOfNodes->begin (); it != listOfNodes->end (); it++) { if ((*it)->GetIDNetworkNode () != targetNode->GetIDNetworkNode () ) { NetworkNode *probableNewTargetNode = (*it); TXpower = 10 * log10 ( pow (10., (probableNewTargetNode->GetPhy()->GetTxPower() - 30)/10) / probableNewTargetNode->GetPhy()->GetBandwidthManager()->GetDlSubChannels().size () ); pathLoss = ComputePathLossForInterference(probableNewTargetNode, ue); RXpower = TXpower - pathLoss; if (RXpower > targetRXpower) { if (NetworkManager::Init()->CheckHandoverPermissions(probableNewTargetNode,ue)) { targetRXpower = RXpower; targetNode = probableNewTargetNode; } } } } std::vector<HeNodeB*> *listOfNodes2 = NetworkManager::Init ()->GetHomeENodeBContainer(); std::vector<HeNodeB*>::iterator it2; for (it2 = listOfNodes2->begin (); it2 != listOfNodes2->end (); it2++) { if ((*it2)->GetIDNetworkNode () != targetNode->GetIDNetworkNode () ) { NetworkNode *probableNewTargetNode = (*it2); TXpower = 10 * log10 ( pow (10., (probableNewTargetNode->GetPhy()->GetTxPower() - 30)/10) / probableNewTargetNode->GetPhy()->GetBandwidthManager()->GetDlSubChannels().size () ); pathLoss = ComputePathLossForInterference(probableNewTargetNode, ue); RXpower = TXpower - pathLoss; if (RXpower > targetRXpower) { if (NetworkManager::Init()->CheckHandoverPermissions(probableNewTargetNode,ue)) { targetRXpower = RXpower; targetNode = probableNewTargetNode; } } } } if (ue->GetTargetNode ()->GetIDNetworkNode () != targetNode->GetIDNetworkNode ()) { m_target = targetNode; return true; } else { return false; }*/ }