# include "sandia_rules.hpp" # include "sparse_grid_mixed.hpp" # include # include # include # include int main ( ); void sparse_grid_mixed_point_tests ( double tol ); void sparse_grid_mixed_point_test ( int dim_num, int level_max_min, int level_max_max, int rule[], double alpha[], double beta[], double tol ); //****************************************************************************80 int main ( ) //****************************************************************************80 // // Purpose: // // MAIN is the main program for SPARSE_GRID_MIXED_POINT_TEST. // // Discussion: // // SPARSE_GRID_MIXED_POINT_TEST tests the SPARSE_GRID_MIXED_POINT routines. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 21 December 2009 // // Author: // // John Burkardt // // Reference: // // Fabio Nobile, Raul Tempone, Clayton Webster, // A Sparse Grid Stochastic Collocation Method for Partial Differential // Equations with Random Input Data, // SIAM Journal on Numerical Analysis, // Volume 46, Number 5, 2008, pages 2309-2345. // { double tol; webbur::timestamp ( ); std::cout << "\n"; std::cout << "SPARSE_GRID_MIXED_POINT_TEST\n"; std::cout << " C++ version\n"; tol = sqrt ( webbur::r8_epsilon ( ) ); sparse_grid_mixed_point_tests ( tol ); // // Terminate. // std::cout << "\n"; std::cout << "SPARSE_GRID_MIXED_POINT_TEST\n"; std::cout << " Normal end of execution.\n"; std::cout << "\n"; webbur::timestamp ( ); return 0; } //****************************************************************************80 void sparse_grid_mixed_point_tests ( double tol ) //****************************************************************************80 // // Purpose: // // SPARSE_GRID_MIXED_POINT_TESTS calls SPARSE_GRID_MIXED_POINT_TEST. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 07 March 2011 // // Author: // // John Burkardt // // Parameters: // // Input, double TOL, a tolerance for point equality. // A value of sqrt ( eps ) is reasonable, and will allow the code to // consolidate points which are equal, or very nearly so. A value of // -1.0, on the other hand, will force the code to use every point, regardless // of duplication. // { double *alpha; double *beta; int dim_num; int level_max_max; int level_max_min; int *order_1d; int order_nd; int *rule; std::cout << "\n"; std::cout << "SPARSE_GRID_MIXED_POINT_TESTS\n"; std::cout << " Call SPARSE_GRID_MIXED_POINT_TEST with various arguments..\n"; std::cout << " All tests will use a point equality tolerance of " << tol << "\n"; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 1; rule[1] = 1; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 1; rule[1] = 3; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 1; rule[1] = 4; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 1; rule[1] = 7; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 1.5; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 1; rule[1] = 8; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.5; beta[0] = 0.0; beta[1] = 1.5; rule[0] = 2; rule[1] = 9; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; dim_num = 2; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 2.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 6; rule[1] = 4; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; // // Rule 1x2x5 // dim_num = 3; level_max_min = 0; level_max_max = 2; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; alpha[2] = 0.0; beta[0] = 0.0; beta[1] = 0.0; beta[2] = 0.0; rule[0] = 1; rule[1] = 2; rule[2] = 5; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; // // Rule 13x13 // dim_num = 2; level_max_min = 4; level_max_max = 4; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 13; rule[1] = 13; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; // // Rule 16x16. // dim_num = 2; level_max_min = 4; level_max_max = 4; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 16; rule[1] = 16; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; // // Rule 17x17. // dim_num = 2; level_max_min = 4; level_max_max = 4; alpha = new double[dim_num]; beta = new double[dim_num]; rule = new int[dim_num]; alpha[0] = 0.0; alpha[1] = 0.0; beta[0] = 0.0; beta[1] = 0.0; rule[0] = 17; rule[1] = 17; sparse_grid_mixed_point_test ( dim_num, level_max_min, level_max_max, rule, alpha, beta, tol ); delete [] alpha; delete [] beta; delete [] rule; return; } //***************************************************************************80 void sparse_grid_mixed_point_test ( int dim_num, int level_max_min, int level_max_max, int rule[], double alpha[], double beta[], double tol ) //***************************************************************************80 // // Purpose: // // SPARSE_GRID_MIXED_POINT_TEST tests SPARSE_GRID_MIXED_POINT. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 21 November 2008 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, int LEVEL_MAX_MIN, LEVEL_MAX_MAX, the minimum and // maximum values of LEVEL_MAX. // // Input, int RULE[DIM_NUM], the rule in each dimension. // 1, "CC", Clenshaw Curtis, Closed Fully Nested. // 2, "F2", Fejer Type 2, Open Fully Nested. // 3, "GP", Gauss Patterson, Open Fully Nested. // 4, "GL", Gauss Legendre, Open Weakly Nested. // 5, "GH", Gauss Hermite, Open Weakly Nested. // 6, "GGH", Generalized Gauss Hermite, Open Weakly Nested. // 7, "LG", Gauss Laguerre, Open Non Nested. // 8, "GLG", Generalized Gauss Laguerre, Open Non Nested. // 9, "GJ", Gauss Jacobi, Open Non Nested. // 10, "GW", Golub Welsch, (presumed) Open Non Nested. // 11, "CC_SE", Clenshaw Curtis Slow Exponential, Closed Fully Nested. // 12, "F2_SE", Fejer Type 2 Slow Exponential, Closed Fully Nested. // 13, "GP_SE", Gauss Patterson Slow Exponential, Closed Fully Nested. // 14, "CC_ME", Clenshaw Curtis Moderate Exponential, Closed Fully Nested. // 15, "F2_ME", Fejer Type 2 Moderate Exponential, Closed Fully Nested. // 16, "GP_ME", Gauss Patterson Moderate Exponential, Closed Fully Nested. // 17, "CCN", Clenshaw Curtis Nested, Linear, Closed Fully Nested rule. // // Input, double ALPHA[DIM_NUM], BETA[DIM_NUM], parameters used for // Generalized Gauss Hermite, Generalized Gauss Laguerre, and Gauss Jacobi rules. // // Input, double TOL, a tolerance for point equality. // { int dim; int level_max; int point; int point_num; int point_total_num; int *sparse_index; int *sparse_order; double *sparse_point; int *sparse_unique_index; std::cout << "\n"; std::cout << "SPARSE_GRID_MIXED_POINT_TEST\n"; std::cout << " SPARSE_GRID_MIXED_POINT returns an array of the points\n"; std::cout << " forming a multidimensional sparse grid with mixed factors.\n"; std::cout << "\n"; std::cout << " Each sparse grid is of spatial dimension DIM_NUM,\n"; std::cout << " and is made up of product grids of levels up to LEVEL_MAX.\n"; std::cout << "\n"; std::cout << " Dimension Rule Alpha Beta\n"; std::cout << "\n"; for ( dim = 0; dim < dim_num; dim++ ) { if ( rule[dim] == 1 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 2 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 3 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 4 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 5 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 6 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << " " << std::setw(14) << alpha[dim] << "\n"; } else if ( rule[dim] == 7 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 8 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << " " << std::setw(14) << alpha[dim] << "\n"; } else if ( rule[dim] == 9 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << " " << std::setw(14) << alpha[dim] << " " << std::setw(14) << beta[dim] << "\n"; } else if ( rule[dim] == 10 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 11 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 12 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 13 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 14 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 15 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 16 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else if ( rule[dim] == 17 ) { std::cout << " " << std::setw(8) << dim << " " << std::setw(8) << rule[dim] << "\n"; } else { std::cout << "\n"; std::cout << "SPARSE_GRID_MIXED_POINT_TEST - Fatal error!\n"; std::cout << " Unexpected value of RULE = " << rule[dim] << "\n"; exit ( 1 ); } } for ( level_max = level_max_min; level_max <= level_max_max; level_max++ ) { point_total_num = webbur::sparse_grid_mixed_size_total ( dim_num, level_max, rule ); point_num = webbur::sparse_grid_mixed_size ( dim_num, level_max, rule, alpha, beta, tol ); sparse_unique_index = new int[point_total_num]; webbur::sparse_grid_mixed_unique_index ( dim_num, level_max, rule, alpha, beta, tol, point_num, point_total_num, sparse_unique_index ); sparse_order = new int[dim_num*point_num]; sparse_index = new int[dim_num*point_num]; webbur::sparse_grid_mixed_index ( dim_num, level_max, rule, point_num, point_total_num, sparse_unique_index, sparse_order, sparse_index ); sparse_point = new double [ dim_num * point_num ]; webbur::sparse_grid_mixed_point ( dim_num, level_max, rule, alpha, beta, point_num, sparse_order, sparse_index, sparse_point ); std::cout << "\n"; std::cout << " For LEVEL_MAX = " << level_max << "\n"; std::cout << "\n"; for ( point = 0; point < point_num; point++ ) { std::cout << " " << std::setw(4) << point << " "; for ( dim = 0; dim < dim_num; dim++ ) { std::cout << " " << std::setw(10) << sparse_point[dim+point*dim_num]; } std::cout << "\n"; } delete [] sparse_index; delete [] sparse_order; delete [] sparse_point; delete [] sparse_unique_index; } return; }