Displays more details in case of singular system
parent
91d47148c5
commit
3072c6e611
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@ -71,7 +71,7 @@ double
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Interpreter::pow1(double a, double b)
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{
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double r = pow_(a, b);
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if (isnan(r))
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if (isnan(r)
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{
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res1 = NAN;
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r = 0.0000000000000000000000001;
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@ -1718,6 +1718,16 @@ Interpreter::evaluate_a_block(const int size, const int type, string bin_basenam
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}
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}
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void
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Interpreter::SingularDisplay(int Per_u_, bool evaluate, int Block_Count, int size, bool steady_state, it_code_type begining)
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{
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it_code = begining;
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compute_block_time(Per_u_, evaluate, Block_Count, size, steady_state);
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Singular_display(Block_Count, size, steady_state, begining);
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}
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int
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Interpreter::simulate_a_block(const int size, const int type, string file_name, string bin_basename, bool Gaussian_Elimination, bool steady_state, bool print_it, int block_num,
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const bool is_linear, const int symbol_table_endo_nbr, const int Block_List_Max_Lag, const int Block_List_Max_Lead, const int u_count_int)
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@ -1726,6 +1736,7 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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int i;
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bool cvg;
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bool result = true;
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bool singular_system;
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double *y_save;
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res1 = 0;
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#ifdef DEBUG
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@ -1979,7 +1990,10 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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if (cvg)
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continue;
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int prev_iter = iter;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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iter++;
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if (iter > prev_iter)
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{
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@ -2024,7 +2038,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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}
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else
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cvg = false;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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if (!result)
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{
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mexPrintf(" in Solve Forward complete, convergence not achieved in block %d\n", Block_Count+1);
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@ -2076,7 +2092,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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if (cvg)
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continue;
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int prev_iter = iter;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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iter++;
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if (iter > prev_iter)
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{
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@ -2123,7 +2141,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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}
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else
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cvg = false;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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}
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}
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}
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@ -2181,7 +2201,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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if (cvg)
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continue;
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int prev_iter = iter;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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iter++;
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if (iter > prev_iter)
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{
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@ -2225,7 +2247,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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}
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else
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cvg = false;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, 0, 0, 0, size, print_it, cvg, iter, true, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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if (!result)
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{
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mexPrintf(" in Solve Backward complete, convergence not achieved in block %d\n", Block_Count+1);
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@ -2277,7 +2301,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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if (cvg)
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continue;
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int prev_iter = iter;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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iter++;
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if (iter > prev_iter)
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{
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@ -2320,7 +2346,9 @@ Interpreter::simulate_a_block(const int size, const int type, string file_name,
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}
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else
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cvg = false;
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Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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singular_system = Simulate_Newton_One_Boundary(Block_Count, symbol_table_endo_nbr, it_, y_kmin, y_kmax, size, print_it, cvg, iter, false, stack_solve_algo, solve_algo);
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if (singular_system)
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SingularDisplay(0, false, block_num, size, steady_state, begining);
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}
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}
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}
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@ -61,6 +61,7 @@ protected:
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void print_a_block(const int size, const int type, string bin_basename, bool steady_state, int block_num,
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const bool is_linear, const int symbol_table_endo_nbr, const int Block_List_Max_Lag,
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const int Block_List_Max_Lead, const int u_count_int, int block);
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void SingularDisplay(int Per_u_, bool evaluate, int Block_Count, int size, bool steady_state, it_code_type begining);
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vector<Block_contain_type> Block_Contain;
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code_liste_type code_liste;
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it_code_type it_code;
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@ -366,7 +366,7 @@ SparseMatrix::Read_SparseMatrix(string file_name, const int Size, int periods, i
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}
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void
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SparseMatrix::Simple_Init(int it_, int y_kmin, int y_kmax, int Size, map<pair<pair<int, int>, int>, int> &IM, bool &zero_solution)
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SparseMatrix::Simple_Init(int Size, map<pair<pair<int, int>, int>, int> &IM, bool &zero_solution)
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{
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int i, eq, var, lag;
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map<pair<pair<int, int>, int>, int>::iterator it4;
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@ -2153,6 +2153,94 @@ SparseMatrix::Solve_Matlab_BiCGStab(mxArray *A_m, mxArray *b_m, int Size, double
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}
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void
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SparseMatrix::Singular_display(int block, int Size, bool steady_state, it_code_type it_code)
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{
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bool zero_solution;
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Simple_Init(Size, IM_i, zero_solution);
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NonZeroElem *first;
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mxArray *rhs[1];
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rhs[0] = mxCreateDoubleMatrix(Size, Size, mxREAL);
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double *pind;
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pind = mxGetPr(rhs[0]);
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for (int j = 0; j < Size * Size; j++)
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pind[j] = 0.0;
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for (int ii = 0; ii < Size; ii++)
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{
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int nb_eq = At_Col(ii, &first);
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for (int j = 0; j < nb_eq; j++)
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{
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int k = first->u_index;
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int jj = first->r_index;
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pind[ii * Size + jj ] = u[k];
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first = first->NZE_C_N;
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}
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}
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mxArray *lhs[3];
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mexCallMATLAB(3, lhs, 1, rhs, "svd");
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mxArray* SVD_u = lhs[0];
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mxArray* SVD_s = lhs[1];
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mxArray* SVD_v = lhs[2];
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double *SVD_ps = mxGetPr(SVD_s);
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double *SVD_pu = mxGetPr(SVD_u);
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for (int i = 0; i < Size; i++)
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{
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if (abs(SVD_ps[i * (1 + Size)]) < 1e-12)
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{
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mexPrintf(" The following equations form a linear combination:\n ");
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double max_u = 0;
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for (int j = 0; j < Size; j++)
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if (abs(SVD_pu[j + i * Size]) > abs(max_u))
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max_u = SVD_pu[j + i * Size];
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vector<int> equ_list;
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for (int j = 0; j < Size; j++)
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{
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double rr = SVD_pu[j + i * Size] / max_u;
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if ( rr < -1e-10)
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{
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equ_list.push_back(j);
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if (rr != -1)
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mexPrintf(" - %3.2f*Dequ_%d_dy",abs(rr),j+1);
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else
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mexPrintf(" - Dequ_%d_dy",j+1);
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}
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else if (rr > 1e-10)
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{
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equ_list.push_back(j);
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if (j > 0)
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if (rr != 1)
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mexPrintf(" + %3.2f*Dequ_%d_dy",rr,j+1);
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else
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mexPrintf(" + Dequ_%d_dy",j+1);
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else
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if (rr != 1)
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mexPrintf(" %3.2f*Dequ_%d_dy",rr,j+1);
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else
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mexPrintf(" Dequ_%d_dy",j+1);
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}
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}
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mexPrintf(" = 0\n");
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/*mexPrintf(" with:\n");
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it_code = get_begin_block(block);
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for (int j=0; j < Size; j++)
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{
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if (find(equ_list.begin(), equ_list.end(), j) != equ_list.end())
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mexPrintf(" equ_%d: %s\n",j, print_expression(it_code_expr, false, Size, block, steady_state, 0, 0, it_code, true).c_str());
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}*/
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}
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}
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mxDestroyArray(lhs[0]);
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mxDestroyArray(lhs[1]);
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mxDestroyArray(lhs[2]);
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ostringstream tmp;
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if (block > 1)
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tmp << " in Solve_ByteCode_Sparse_GaussianElimination, singular system in block " << block+1 << "\n";
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else
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tmp << " in Solve_ByteCode_Sparse_GaussianElimination, singular system\n";
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throw FatalExceptionHandling(tmp.str());
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}
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bool
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SparseMatrix::Solve_ByteCode_Sparse_GaussianElimination(int Size, int blck, bool steady_state, int it_)
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{
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bool one;
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@ -2219,7 +2307,6 @@ SparseMatrix::Solve_ByteCode_Sparse_GaussianElimination(int Size, int blck, bool
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}
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if (piv_abs < eps)
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{
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mexEvalString("drawnow;");
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mxFree(piv_v);
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mxFree(pivj_v);
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mxFree(pivk_v);
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@ -2231,7 +2318,7 @@ SparseMatrix::Solve_ByteCode_Sparse_GaussianElimination(int Size, int blck, bool
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mexPrintf("Error: singular system in Simulate_NG in block %d\n", blck+1);
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else
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mexPrintf("Error: singular system in Simulate_NG\n");
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return;
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return true;
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}
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else
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{
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@ -2411,6 +2498,7 @@ SparseMatrix::Solve_ByteCode_Sparse_GaussianElimination(int Size, int blck, bool
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mxFree(pivk_v);
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mxFree(NR);
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mxFree(bc);
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return false;
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}
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void
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@ -2898,13 +2986,14 @@ SparseMatrix::Solve_ByteCode_Symbolic_Sparse_GaussianElimination(int Size, bool
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End_GE(Size);
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}
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void
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bool
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SparseMatrix::Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_kmin, int y_kmax, int Size, bool print_it, bool cvg, int &iter, bool steady_state, int stack_solve_algo, int solve_algo)
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{
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int i, j;
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mxArray *b_m = NULL, *A_m = NULL, *x0_m = NULL;
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Clear_u();
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error_not_printed = true;
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bool singular_system = false;
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u_count_alloc_save = u_count_alloc;
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if (isnan(res1) || isinf(res1) || (res2 > 12*g0 && iter > 0))
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{
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@ -2931,7 +3020,7 @@ SparseMatrix::Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_
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else
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mexPrintf(" dynare cannot improve the simulation in block %d at time %d (variable %d)\n", blck+1, it_+1, index_vara[max_res_idx]+1);
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mexEvalString("drawnow;");
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return;
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return singular_system;
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}
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else
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{
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@ -2972,11 +3061,11 @@ SparseMatrix::Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_
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for (i = 0; i < y_size; i++)
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y[i+it_*y_size] = ya[i+it_*y_size] + slowc_save*direction[i+it_*y_size];
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iter--;
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return;
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return singular_system;
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}
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if (cvg)
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{
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return;
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return singular_system;
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}
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if (print_it)
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{
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@ -3024,7 +3113,7 @@ SparseMatrix::Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_
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}
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bool zero_solution;
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if ((solve_algo == 5 && steady_state) || (stack_solve_algo == 5 && !steady_state))
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Simple_Init(it_, y_kmin, y_kmax, Size, IM_i, zero_solution);
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Simple_Init(Size, IM_i, zero_solution);
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else
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{
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b_m = mxCreateDoubleMatrix(Size, 1, mxREAL);
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@ -3063,7 +3152,7 @@ SparseMatrix::Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_
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else
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{
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if ((solve_algo == 5 && steady_state) || (stack_solve_algo == 5 && !steady_state))
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Solve_ByteCode_Sparse_GaussianElimination(Size, blck, steady_state, it_);
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singular_system = Solve_ByteCode_Sparse_GaussianElimination(Size, blck, steady_state, it_);
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else if ((solve_algo == 7 && steady_state) || (stack_solve_algo == 2 && !steady_state))
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Solve_Matlab_GMRES(A_m, b_m, Size, slowc, blck, false, it_, steady_state, x0_m);
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else if ((solve_algo == 8 && steady_state) || (stack_solve_algo == 3 && !steady_state))
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@ -3071,7 +3160,7 @@ SparseMatrix::Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_
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else if ((solve_algo == 6 && steady_state) || ((stack_solve_algo == 0 || stack_solve_algo == 1) && !steady_state))
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Solve_Matlab_LU_UMFPack(A_m, b_m, Size, slowc, false, it_);
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}
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return;
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return singular_system;
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}
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void
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@ -63,21 +63,22 @@ class SparseMatrix : public ErrorMsg
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public:
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SparseMatrix();
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void Simulate_Newton_Two_Boundaries(int blck, int y_size, int it_, int y_kmin, int y_kmax, int Size, int periods, bool print_it, bool cvg, int &iter, int minimal_solving_periods, int stack_solve_algo, unsigned int endo_name_length, char *P_endo_names) /*throw(ErrorHandlingException)*/;
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void Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_kmin, int y_kmax, int Size, bool print_it, bool cvg, int &iter, bool steady_state, int stack_solve_algo, int solve_algo);
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bool Simulate_Newton_One_Boundary(int blck, int y_size, int it_, int y_kmin, int y_kmax, int Size, bool print_it, bool cvg, int &iter, bool steady_state, int stack_solve_algo, int solve_algo);
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void Direct_Simulate(int blck, int y_size, int it_, int y_kmin, int y_kmax, int Size, int periods, bool print_it, int iter);
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void fixe_u(double **u, int u_count_int, int max_lag_plus_max_lead_plus_1);
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void Read_SparseMatrix(string file_name, const int Size, int periods, int y_kmin, int y_kmax, bool steady_state, bool two_boundaries, int stack_solve_algo, int solve_algo);
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void Read_file(string file_name, int periods, int u_size1, int y_size, int y_kmin, int y_kmax, int &nb_endo, int &u_count, int &u_count_init, double *u);
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void Singular_display(int block, int Size, bool steady_state, it_code_type it_code);
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double g0, gp0, glambda2, try_at_iteration;
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private:
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void Init_GE(int periods, int y_kmin, int y_kmax, int Size, map<pair<pair<int, int>, int>, int> &IM);
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void Init_Matlab_Sparse(int periods, int y_kmin, int y_kmax, int Size, map<pair<pair<int, int>, int>, int> &IM, mxArray *A_m, mxArray *b_m, mxArray *x0_m);
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void Init_Matlab_Sparse_Simple(int Size, map<pair<pair<int, int>, int>, int> &IM, mxArray *A_m, mxArray *b_m, bool &zero_solution, mxArray *x0_m);
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void Simple_Init(int it_, int y_kmin, int y_kmax, int Size, std::map<std::pair<std::pair<int, int>, int>, int> &IM, bool &zero_solution);
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void Simple_Init(int Size, std::map<std::pair<std::pair<int, int>, int>, int> &IM, bool &zero_solution);
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void End_GE(int Size);
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void Solve_ByteCode_Symbolic_Sparse_GaussianElimination(int Size, bool symbolic, int Block_number);
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void Solve_ByteCode_Sparse_GaussianElimination(int Size, int blck, bool steady_state, int it_);
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bool Solve_ByteCode_Sparse_GaussianElimination(int Size, int blck, bool steady_state, int it_);
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void Solve_Matlab_Relaxation(mxArray *A_m, mxArray *b_m, unsigned int Size, double slowc_l, bool is_two_boundaries, int it_);
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void Solve_Matlab_LU_UMFPack(mxArray *A_m, mxArray *b_m, int Size, double slowc_l, bool is_two_boundaries, int it_);
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void Solve_Matlab_GMRES(mxArray *A_m, mxArray *b_m, int Size, double slowc, int block, bool is_two_boundaries, int it_, bool steady_state, mxArray *x0_m);
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Loading…
Reference in New Issue