void MAIAllocator::SwapCarriers(std::string & sU1, std::string & sC1, std::string & sU2, std::string & sC2) { unsigned int foundj1=J(); unsigned int foundj2=foundj1; unsigned int u1 = atoi(sU1.c_str()); unsigned int u2 = atoi(sU2.c_str()); unsigned int c1 = atoi(sC1.c_str()); unsigned int c2 = atoi(sC2.c_str()); // we find the indexes of current allocations for (int j=0; j<J(); j++) { if (gsl_matrix_uint_get(signature_frequencies,u1,j) == c1) foundj1 = j; if (gsl_matrix_uint_get(signature_frequencies,u2,j) == c2) foundj2 = j; } // we perform the swap allocation and reset power gsl_matrix_uint_set(signature_frequencies,u1,foundj1,c2); gsl_matrix_uint_set(signature_frequencies,u2,foundj2,c1); gsl_matrix_set(signature_powers,u1,foundj1,INIT_CARR_POWER); gsl_matrix_set(signature_powers,u1,foundj2,INIT_CARR_POWER); }
/*! Find a zero (Z) in the resulting matrix. If there is no starred zero in its row or column, star Z. Repeat for each element in the matrix. Go to STEP3. */ nextstep Step2(const gsl_matrix * const M, gsl_matrix_uint * const mask, gsl_vector_uint * const rowCov, gsl_vector_uint * const colCov) { unsigned int i, j; for(i = 0; i < M->size1; i++) { for(j = 0; j < M->size2; j++) { if(gsl_vector_uint_get(rowCov, i) == COVERED) break; if(gsl_vector_uint_get(colCov, j) == UNCOVERED && gsl_matrix_get(M, i, j) == (float) 0 ) { gsl_matrix_uint_set(mask, i, j, STAR); #ifdef VERBOSE fprintf(stderr, "Covering col %d\n", j); #endif gsl_vector_uint_set(colCov, j, COVERED); #ifdef VERBOSE fprintf(stderr, "Covering row %d\n", i); #endif gsl_vector_uint_set(rowCov, i, COVERED); } } } gsl_vector_uint_set_all(rowCov, UNCOVERED); gsl_vector_uint_set_all(colCov, UNCOVERED); return STEP3; }
void ConvertPath(const gsl_matrix_int * const path, unsigned int count, gsl_matrix_uint * const mask) { int r, c; unsigned int i; for(i = 0; i < count; i++) { r = gsl_matrix_int_get(path, i, 0); c = gsl_matrix_int_get(path, i, 1); if(gsl_matrix_uint_get(mask, r, c) == STAR) gsl_matrix_uint_set(mask, r, c, UNMASKED); else gsl_matrix_uint_set(mask, r, c, STAR); } }
void ErasePrimes(gsl_matrix_uint * const mask) { unsigned i, j; for(i = 0; i < mask->size1; i++) { for(j = 0; j < mask->size2; j++) { if(gsl_matrix_uint_get(mask, i, j) == PRIME) gsl_matrix_uint_set(mask, i, j, UNMASKED); } } }
/*! Find a noncovered zero and prime it. If there is no starred zero in the row containing this primed zero, go to STEP5. Otherwise, cover this row and uncover the column containing the starred zero. Continue in this manner until there are no uncovered zeroes left. Save the smallest uncovered value and go to STEP6. */ nextstep Step4(const gsl_matrix * const M, gsl_matrix_uint * const mask, gsl_vector_uint * const rowCov, gsl_vector_uint * const colCov, int * const z0_r, int * const z0_c) { bool done = false; int row, col; nextstep next; while(done == false) { FindAZero(M, rowCov, colCov, &row, &col); if(row == -1) { #ifdef VERBOSE fprintf(stderr, "Step4: Cannot find zero.\n"); #endif done = true; next = STEP6; } else { #ifdef VERBOSE fprintf(stderr, "Ste4: Found zero at M[%d, %d]. Setting PRIME.\n", row, col); #endif gsl_matrix_uint_set(mask, row, col, PRIME); if(StarInRow(mask, row) == true) { FindStarInRow(mask, row, &col); gsl_vector_uint_set(rowCov, row, COVERED); gsl_vector_uint_set(colCov, col, UNCOVERED); } else { done = true; next = STEP5; *z0_r = row; *z0_c = col; } } } return next; }
void MAIAllocator::AssignFree(std::string & sUid, std::string & sDeassign, std::string & sAssign) { unsigned int foundj=J(); unsigned int u = atoi(sUid.c_str()); unsigned int newcarr = atoi(sAssign.c_str()); unsigned int lastcarr = atoi(sDeassign.c_str()); // we find the index of current allocation for (int j=0; j<J(); j++) if (gsl_matrix_uint_get(signature_frequencies,u,j) == lastcarr) { foundj = j; break; } // we perform the allocation and reset power gsl_matrix_uint_set(signature_frequencies,u,foundj,newcarr); gsl_matrix_set(signature_powers,u,foundj,INIT_CARR_POWER); }
void MAIAllocator::Run() { // fetch channel matrix gsl_matrix_complex hmm = min1.GetDataObj(); // hmm : channel coeffs matrix h(n) (M**2xN) // ij // ch matrix structure // // +- -+ // | h(0) . . . . h(n) | | // | 11 11 | | // | | | Rx1 // | h(0) . . . . h(n) | | // | 12 12 | | // | | // | h(0) . . . . h(n) | | // | 21 21 | | // | | | Rx2 // | h(0) . . . . h(n) | | // | 22 22 | | // +- -+ // // where h(n) represents the channel impulse response // ij // // at time n, from tx_i to rx_j // the matrix has MxM rows and N comumns. // The (i,j) channel is locater at row i*M+j // with i,j in the range [0,M-1] and rows counting from 0 // // // fetch error report // e(u) = errors for user u in the last ERROR_REPORT_INTERVAL (ERI) frames gsl_vector_uint temperr = vin2.GetDataObj(); // update error reports at receiver rx_m every ERI if (ericount % ERROR_REPORT_INTERVAL == 0) { // once every ERU if (temperr.size == M()) { gsl_vector_uint_memcpy(errs,&temperr); } ericount = 0; } // // every DECISION_INTERVAL frames we updates the CSI knowledge // if (framecount % DECISION_INTERVAL == 0) { for (int u=0;u<M();u++) { // user loop // extract time domain response from hmm corresponding to txn-->rxn channel gsl_vector_complex_const_view hii = gsl_matrix_complex_const_row(&hmm,u*M()+u); // copy the N-sized vector hii into u-th column of huu gsl_matrix_complex_set_col(huu,u,&hii.vector); } // user loop //cout << "maiallocator:453 - CSI update received" << endl; // huu matrix structure // // +- -+ // | h(0) . . . . h(n) | // | 11 uu | // | | // | h(n) . . . . h(n) | // | 11 uu | // +- -+ // // where h(n) represents the channel impulse response // ii // // at time n, from tx_u to rx_u // the matrix has N rows and M columns. // // ATTENTION! user_0 channel response is the first column // // Hmat(NxM) = Fourier( huu(NxM) ) // gsl_blas_zgemm(CblasNoTrans, CblasNoTrans, gsl_complex_rect(1,0), transform_mat, huu, gsl_complex_rect(0,0), Hmat); #ifdef SHOW_MATRIX cout << "Hmat(freq,user) (frame:" << framecount << ") = " << endl; gsl_matrix_complex_show(Hmat); #endif // // *********************************************************** // CARRIER ALLOCATION STRATEGIES // *********************************************************** // switch (Mode()) { case 0: // FIXED_ALLOCATION break; case 1: // GIVE_BEST_CARR // // SORT CARRIERS OF EACH USERS // // uses Hmat: the frequency responses of channel tx_n --> rx_n // // starting from user u ... // find the best (in u ranking) unused carrier and assign it to u // next user until no more available carriers for(int u=0; u<M(); u++) { // cycle through users gsl_vector_complex_const_view huser = gsl_matrix_complex_const_column(Hmat,u); gsl_vector_uint_view sortindu = gsl_matrix_uint_column(Hperm,u); for (int j=0; j<N(); j++) { double currpower = gsl_complex_abs2(gsl_vector_complex_get(&huser.vector,j)); gsl_vector_set(huserabs,j,currpower); } // sort over c using abs(h(u,c)) gsl_sort_vector_index(p,huserabs); for (int j=0; j<N(); j++) { uint currindex = p->data[j]; gsl_vector_uint_set(&sortindu.vector,j,currindex); } } // // FIND INITIAL USER RANDOMLY // curruser = gsl_rng_uniform_int(ran,M()); // // ASSIGN FREQUENCIES // gsl_vector_uint_set_all(nextcarr,0); gsl_vector_uint_set_all(usedcarr,0); for (int j=0; j<J(); j++) { for (int uu=0; uu<M(); uu++) { int u = (uu+curruser) % M(); int isassigned = 0; while (! isassigned) { int tag = gsl_vector_uint_get(nextcarr,u); gsl_vector_uint_set(nextcarr,u,++tag); int carrier = gsl_matrix_uint_get(Hperm,N()-tag,u); if (! gsl_vector_uint_get(usedcarr,carrier)) { isassigned = 1; gsl_vector_uint_set(usedcarr,carrier,isassigned); gsl_matrix_uint_set(signature_frequencies,u,j,carrier); } else if (tag==N()) { cerr << "Block: " << BlockName << " allocation problem." << endl; exit(1); } } } } // // show channels and permutations // // gsl_matrix_complex_show(Hmat); //gsl_matrix_uint_show(Hperm); //gsl_matrix_uint_show(signature_frequencies); break; case 2: // SWAP_BAD_GOOD // // SWAP_BAD_GOOD // // sort carriers for each user // choose randomly a starting user u // for each user starting with u // swap worst carrier used by u with best carrier if used by others // sort carriers for(int u=0; u<M(); u++) { gsl_vector_complex_const_view huser = gsl_matrix_complex_const_column(Hmat,u); gsl_vector_uint_view sortindu = gsl_matrix_uint_column(Hperm,u); gsl_vector_view huserabs = gsl_matrix_column(habs,u); for (int j=0; j<N(); j++) { double currpower = gsl_complex_abs2(gsl_vector_complex_get(&huser.vector,j)); gsl_vector_set(&huserabs.vector,j,currpower); } // // sort channels for user <u> // gsl_sort_vector_index(p,&huserabs.vector); for (int j=0; j<N(); j++) { uint currindex = p->data[j]; gsl_vector_uint_set(&sortindu.vector,j,currindex); } } // // Hperm(N,USERS) contains sorted channels index for each users // habs(N,USERS) contains channel energy per each user // // // FIND INITIAL USER RANDOMLY for fairness // curruser = gsl_rng_uniform_int(ran,M()); // // ASSIGN FREQUENCIES // // // for each user ... // for (int uu=0; uu<M(); uu++) { int u = (uu+curruser) % M(); // // worst allocated channel for user u // double worstvalue=GSL_POSINF; unsigned int worstjindex; for (int j=0; j<J(); j++) { unsigned int chind = gsl_matrix_uint_get(signature_frequencies,u,j); double currh = gsl_matrix_get(habs,chind,u); if (currh < worstvalue) { worstvalue = currh; worstjindex = j; } } // // find best channel allocated by other users // // double bestvalue=0; unsigned int bestuser, bestjindex; for (int uuu=0; uuu<M()-1; uuu++) { unsigned int otheru = (uuu+u) % M(); for (int j=0; j<J(); j++) { unsigned int chind = gsl_matrix_uint_get(signature_frequencies,otheru,j); double currh = gsl_matrix_get(habs,chind,otheru); if (currh > bestvalue) { bestvalue = currh; bestjindex = j; bestuser = otheru; } } } // // finally the swap ! // unsigned int chind = gsl_matrix_uint_get(signature_frequencies,u,worstjindex); gsl_matrix_uint_set(signature_frequencies,u,worstjindex, gsl_matrix_uint_get(signature_frequencies, bestuser,bestjindex)); gsl_matrix_uint_set(signature_frequencies,bestuser,bestjindex,chind); // cout << "\n\nProcessing user " << u << endl // << "\tSwapped " << u << "." << worstjindex // << " <-> " << bestuser << "." << bestjindex << endl; } break; case 3: // BEST_OVERLAP // // SORT CARRIERS OF EACH USERS // gsl_matrix_uint_memcpy(signature_frequencies, signature_frequencies_init); for(int u=0; u<M(); u++) { gsl_vector_complex_const_view huser = gsl_matrix_complex_const_column(Hmat,u); gsl_vector_uint_view sortindu = gsl_matrix_uint_column(Hperm,u); for (int j=0; j<N(); j++) { double currpower = gsl_complex_abs2(gsl_vector_complex_get(&huser.vector, j)); gsl_vector_set(huserabs,j,currpower); } gsl_sort_vector_index(p,huserabs); for (int j=0; j<N(); j++) { uint currindex = p->data[j]; gsl_vector_uint_set(&sortindu.vector,j,currindex); } } // // each user take his best carriers allowing carrier overlap // for (int u=0; u<M(); u++) { for (int j=0; j<J(); j++) { int carrier = gsl_matrix_uint_get(Hperm,N()-j-1,u); gsl_matrix_uint_set(signature_frequencies,u,j,carrier); } } // // show channels and permutations // //gsl_matrix_complex_show(Hmat); //gsl_matrix_uint_show(Hperm); //gsl_matrix_uint_show(signature_frequencies); break; case 4: // SOAR_AI // // SOAR // // agent crai5 // bases the decisions on the frequency response tx_m --> rx_m in Hmat(N,M) // for each user it proposes a swap between carriers if the instantaneous impulse channel response // is better // // agent crai6 // for each user it proposes a swap of allocated carriers with one other users // error report is the metric for correct decisions (RL) #ifdef PAUSED // keypress cout << "pause maillocator: before decision loop ... (press ENTER key)" << endl; cin.ignore(); #endif // Every DECISION_INTERVAL we increase the input-time and allow decisions if (framecount % DECISION_INTERVAL == 0) { pAgent->Update(inputTime,++input_time); pAgent->Commit(); } // run agent till output noDecisions = 0; numberCommands=0; while (! (noDecisions) ) { // main decisional loop // // INPUT LINK Update // UpdateInputLink(); //pAgent->RunSelf(1); pAgent->RunSelfTilOutput(); numberCommands = pAgent->GetNumberCommands() ; #ifdef PAUSED // keypress cout << "pause maillocator: after RunSelfTilOutput() ... (press ENTER key)" << endl; cin.ignore(); #endif // loop through received commands for (int cmd = 0 ; cmd < numberCommands ; cmd++) { Identifier* pCommand = pAgent->GetCommand(cmd) ; string name = pCommand->GetCommandName() ; if (name == "assign-free") { std::string sUid = pCommand->GetParameterValue("uid"); std::string sDeassign = pCommand->GetParameterValue("deassign"); std::string sAssign = pCommand->GetParameterValue("assign"); #ifdef SHOW_SOAR cout << "assign-free command received [ u:" << sUid << " , -" << sDeassign << " , +" << sAssign << " ]" << endl; #endif AssignFree(sUid,sDeassign,sAssign); pCommand->AddStatusComplete(); } else if (name == "swap-carriers") { std::string sU1 = pCommand->GetParameterValue("u1"); std::string sC1 = pCommand->GetParameterValue("c1"); std::string sU2 = pCommand->GetParameterValue("u2"); std::string sC2 = pCommand->GetParameterValue("c2"); #ifdef SHOW_SOAR cout << "swap-carriers command received [ u1:" << sU1 << " , c1:" << sC1 << " , u2:" << sU2 << " , c2:" << sC2 << " ]" << endl; #endif SwapCarriers(sU1,sC1,sU2,sC2); pCommand->AddStatusComplete(); } else if (name == "increase-power") { std::string sUid = pCommand->GetParameterValue("uid"); std::string sCid = pCommand->GetParameterValue("cid"); #ifdef SHOW_SOAR cout << "increase-power command received [ u:" << sUid << " , c:" << sCid << " ]" << endl; #endif IncreasePower(sUid,sCid); pCommand->AddStatusComplete(); break; } else if (name == "no-choices") { #ifdef SHOW_SOAR cout << "no-choices command received" << endl; #endif noDecisions = 1; pCommand->AddStatusComplete(); break; } else { #ifdef SHOW_SOAR cout << "ignoring unknown output command from SOAR" << endl; #endif break; } // cout << "framecount = " << framecount << endl; } // end command loop } // while (! (noDecisions) ) break; } // switch (Mode()) } // if DECISION_INTERVAL % 0 // // every 10s dump frame count // time(&nowtime); if (difftime(nowtime,reporttime) > TIMEDELTA) { reporttime = nowtime; cout << "frame:" << framecount << "\r"; cout.flush(); } //////// production of data framecount++; ericount++; mout1.DeliverDataObj( *signature_frequencies ); mout2.DeliverDataObj( *signature_powers ); #ifdef SHOW_MATRIX cout << "signature frequencies (frame:" << framecount-1 << ") = " << endl; gsl_matrix_uint_show(signature_frequencies); #endif }
void MAIAllocator::Setup() { //////// initialization of dynamic data structures Hmat = gsl_matrix_complex_alloc(N(),M()); Hchan = gsl_vector_complex_alloc(N()); Hperm = gsl_matrix_uint_alloc(N(),M()); p = gsl_permutation_alloc(N()); huserabs = gsl_vector_alloc(N()); nextcarr = gsl_vector_uint_alloc(M()); usedcarr = gsl_vector_uint_alloc(N()); errs = gsl_vector_uint_alloc(M()); habs = gsl_matrix_alloc(N(),M()); huu = gsl_matrix_complex_alloc(N(),M()); framecount = 0; ericount = 0; csicount = 0; noDecisions = 0; ostringstream cmd; // // time // time(&reporttime); // // Random Generator // ran = gsl_rng_alloc( gsl_rng_default ); // SIGNATURE FREQUENCIES INITIAL SETUP signature_frequencies = gsl_matrix_uint_alloc(M(),J()); signature_frequencies_init = gsl_matrix_uint_alloc(M(),J()); signature_powers = gsl_matrix_alloc(M(),J()); for (int i=0; i<M(); i++) for (int j=0; j<J(); j++) gsl_matrix_uint_set(signature_frequencies_init,i,j,(j*M()+i) % N()); // // INITIAL ALLOCATION // gsl_matrix_uint_memcpy(signature_frequencies, signature_frequencies_init); // maximum initial powers for all carriers gsl_matrix_set_all(signature_powers,INIT_CARR_POWER); gsl_vector_uint_set_zero(errs); // // // FFT Transform Matrix // // transform_mat = gsl_matrix_complex_calloc(N(),N()); double fftarg=-2.0*double(M_PI/N()); double fftamp=1.0/sqrt(double(N())); for (int i=0; i<N(); i++) for (int j=0; j<N(); j++) gsl_matrix_complex_set(transform_mat,i,j, gsl_complex_polar(fftamp,fftarg*i*j) ); switch (Mode()) { case 0: cout << BlockName << " - Allocator type FIXED_ALLOCATION selected" << endl; break; case 1: cout << BlockName << " - Allocator type GIVE_BEST_CARR selected" << endl; break; case 2: cout << BlockName << " - Allocator type SWAP_BAD_GOOD selected" << endl; break; case 3: cout << BlockName << " - Allocator type BEST_OVERLAP selected" << endl; break; case 4: cout << BlockName << " - Allocator type SOAR_AI selected" << endl; // // SOAR INITIALIZATION // max_errors = MAX_ERROR_RATE * ERROR_REPORT_INTERVAL * Nb() * K(); cout << BlockName << " - Max errors tuned to " << max_errors << " errors/frame." << endl; // // first we initialize the vectors and matrices // in the order of appearance in the header file. // umapUserVec = vector < Identifier * > (M()); umapUserUidVec = vector < IntElement * > (M()); umapUserErrsVec = vector < IntElement * > (M()); umapUserPowerVec = vector < FloatElement * > (M()); umapUserCarrMat = vector < Identifier * > (M()*J()); umapUserCarrCidMat = vector < IntElement * > (M()*J()); umapUserCarrPowerMat = vector < FloatElement * > (M()*J()); chansCoeffMat = vector < Identifier * > (M()*N()); chansCoeffUserMat = vector < IntElement * > (M()*N()); chansCoeffCarrMat = vector < IntElement * > (M()*N()); chansCoeffValueMat = vector < FloatElement * > (M()*N()); carmapCarrVec = vector < Identifier * > (N()); carmapCarrCidVec = vector < IntElement * > (N()); // // then we create an instance of the Soar kernel in our process // pKernel = Kernel::CreateKernelInNewThread() ; //pKernel = Kernel::CreateRemoteConnection() ; // Check that nothing went wrong. We will always get back a kernel object // even if something went wrong and we have to abort. if (pKernel->HadError()) { cerr << BlockName << ".SOAR - " << pKernel->GetLastErrorDescription() << endl ; exit(1); } // We check if an agent has been prevoiusly created, otherwise we create it // NOTE: We don't delete the agent pointer. It's owned by the kernel pAgent = pKernel->GetAgent("AIAllocator") ; if (! pKernel->IsAgentValid(pAgent)) { pAgent = pKernel->CreateAgent("AIAllocator") ; } // Check that nothing went wrong // NOTE: No agent gets created if there's a problem, so we have to check for // errors through the kernel object. if (pKernel->HadError()) { cerr << BlockName << ".SOAR - " << pKernel->GetLastErrorDescription() << endl ; exit(1); } // // load productions // pAgent->LoadProductions(SoarFn()); // spawn debugger #ifdef SPAWN_DEBUGGER pAgent->SpawnDebugger(); #endif // Check that nothing went wrong // NOTE: No agent gets created if there's a problem, so we have to check for // errors through the kernel object. if (pKernel->HadError()) { cerr << BlockName << ".SOAR - " << pKernel->GetLastErrorDescription() << endl ; exit(1); } // keypress //cout << "pause maillocator:203 ... (press ENTER key)" << endl; //cin.ignore(); // // we can now generate initial input link structure // // NO MORE adjust max-nil-output-cycle //cmd << "max-nil-output-cycles " << 120; //pAgent->ExecuteCommandLine(cmd.str().c_str()); // the input-link pInputLink = pAgent->GetInputLink(); // input-time input_time = 0; inputTime = pAgent->CreateIntWME(pInputLink,"input-time",input_time); // the usrmap structure (common wmes) umap = pAgent->CreateIdWME(pInputLink,"usrmap"); // BITS_PER_REPORT = ERROR_REPORT_INTERVAL * Nb() * K() // MAX_ERRORS = MAX_ERROR_RATE * BITS_PER_REPORT umapMaxerr = pAgent->CreateIntWME(umap,"maxerr",max_errors); umapPstep = pAgent->CreateFloatWME(umap,"pstep",POWER_STEP); umapPmax = pAgent->CreateFloatWME(umap,"pmax",MAX_POWER); // the channels chans = pAgent->CreateIdWME(pInputLink,"channels"); // the carmap carmap = pAgent->CreateIdWME(pInputLink,"carmap"); // the usrmap structure (users substructure) for (int i=0;i<M();i++) { // user loop umapUserVec[i] = pAgent->CreateIdWME(umap,"user"); umapUserUidVec[i] = pAgent->CreateIntWME(umapUserVec[i],"uid",i); umapUserErrsVec[i] = pAgent->CreateIntWME(umapUserVec[i],"errs",int(0)); umapUserPowerVec[i] = pAgent->CreateFloatWME(umapUserVec[i],"power",J()); // update the current allocation for (int j=0;j<J();j++) { // allocated carriers loop unsigned int usedcarr = gsl_matrix_uint_get(signature_frequencies,i,j); double usedpow = gsl_matrix_get(signature_powers,i,j); umapUserCarrMat[i*J()+j] = pAgent->CreateIdWME(umapUserVec[i],"carr"); umapUserCarrCidMat[i*J()+j] = pAgent->CreateIntWME(umapUserCarrMat[i*J()+j],"cid",usedcarr); umapUserCarrPowerMat[i*J()+j] = pAgent->CreateFloatWME(umapUserCarrMat[i*J()+j],"power",usedpow); } // allocated carriers loop // the channels for (int j=0;j<N();j++) { // all channels loop chansCoeffMat[i*N()+j] = pAgent->CreateIdWME(chans,"coeff"); chansCoeffUserMat[i*N()+j] = pAgent->CreateIntWME(chansCoeffMat[i*N()+j],"user",i); chansCoeffCarrMat[i*N()+j] = pAgent->CreateIntWME(chansCoeffMat[i*N()+j],"carr",j); chansCoeffValueMat[i*N()+j] = pAgent->CreateFloatWME(chansCoeffMat[i*N()+j],"value",0.0); } // all channels loop } // user loop // the carmap structure for (int j=0;j<N();j++) { // all carriers loop carmapCarrVec[j] = pAgent->CreateIdWME(carmap,"carr"); carmapCarrCidVec[j] = pAgent->CreateIntWME(carmapCarrVec[j],"cid",j); } // all carriers loop // // END OF SOAR INITIALIZAZION // break; default: cerr << BlockName << " - Unhandled allocator type !" << endl; exit(1); } //////// rate declaration for ports }