# include # include # include # include using namespace std; # include "nintlib.hpp" int main ( ); void testnd ( int dim_num, double func ( int dim_num, double x[] ) ); void test01 ( int dim_num, double func ( int dim_num, double x[] ) ); void test02 ( int dim_num, double func ( int dim_num, double x[] ) ); void test03 ( int dim_num, double func ( int dim_num, double x[] ) ); void test04 ( int dim_num, double func ( int dim_num, double x[] ) ); void test05 ( int dim_num, double func ( int dim_num, double x[] ) ); void test06 ( int dim_num, double func ( int dim_num, double x[] ) ); double f1dn ( int dim_num, double x[] ); double fbdn ( int dim_num, double x[] ); double fedn ( int dim_num, double x[] ); double fxdn ( int dim_num, double x[] ); double fx2dn ( int dim_num, double x[] ); double fx3dn ( int dim_num, double x[] ); //****************************************************************************8080 int main ( ) //****************************************************************************8080 // // Purpose: // // MAIN is the main program for NINTLIB_TEST. // // Discussion: // // NINTLIB_TEST tests the NINTLIB library. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // { # define TEST_NUM 3 double a; double b; int dim_num; int dim_num_test[TEST_NUM] = { 2, 3, 4 }; int test; timestamp ( ); cout << "\n"; cout << "NINTLIB_TEST\n"; cout << " C++ version\n"; cout << " Test the NINTLIB library.\n"; a = 0.0; b = 1.0; cout << "\n"; cout << "TESTND\n"; cout << " Test routines for estimating the integral of\n"; cout << " of F(X) in the hypercube [A,B]**DIM_NUM.\n"; cout << "\n"; for ( test = 0; test < TEST_NUM; test++ ) { dim_num = dim_num_test[test]; cout << "\n"; cout << "\n"; cout << " DIM_NUM = " << dim_num << "\n"; cout << "\n"; cout << "\n"; cout << " A(1:DIM_NUM) = " << a << "\n"; cout << " B(1:DIM_NUM) = " << b << "\n"; cout << "\n"; cout << "\n"; cout << " F(X(1:DIM_NUM)) = 1\n"; cout << "\n"; testnd ( dim_num, &f1dn ); cout << "\n"; cout << "\n"; cout << " F(X(1:DIM_NUM)) = sum ( X(1:DIM_NUM) )\n"; cout << "\n"; testnd ( dim_num, &fxdn ); cout << "\n"; cout << "\n"; cout << " F(X(1:DIM_NUM)) = sum( X(1:DIM_NUM)^2 )\n"; cout << "\n"; testnd ( dim_num, &fx2dn ); cout << "\n"; cout << "\n"; cout << " F(X(1:DIM_NUM)) = sum ( X(1:DIM_NUM)^3 )\n"; cout << "\n"; testnd ( dim_num, &fx3dn ); cout << "\n"; cout << "\n"; cout << " F(X(1:DIM_NUM)) = exp(sum(X(1:DIM_NUM)))\n"; cout << "\n"; testnd ( dim_num, &fedn ); cout << "\n"; cout << "\n"; cout << " F(X(1:DIM_NUM)) = 1/(1+sum(X(1:DIM_NUM)^2))\n"; cout << "\n"; testnd ( dim_num, &fbdn ); } // // Terminate. // cout << "\n"; cout << "NINTLIB_TEST\n"; cout << " Normal end of execution.\n"; cout << "\n"; timestamp ( ); return 0; # undef TEST_NUM } //****************************************************************************8080 void testnd ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************8080 // // Purpose: // // TESTND tests the integrators on a particular function. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 01 March 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates // the function to be integrated. // { test01 ( dim_num, func ); test02 ( dim_num, func ); test03 ( dim_num, func ); test04 ( dim_num, func ); if ( dim_num == 2 ) { test05 ( dim_num, func ); } test06 ( dim_num, func ); return; } //****************************************************************************80 void test01 ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************80 // // Purpose: // // TEST01 tests BOX_ND. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates the function // to be integrated. // { # define ORDER 5 int eval_num; int i; double result; double wtab[ORDER] = { 0.236926885056189087514264040720, 0.478628670499366468041291514836, 0.568888888888888888888888888889, 0.478628670499366468041291514836, 0.236926885056189087514264040720 }; double wtab2[ORDER]; double xtab[ORDER] = { -0.906179845938663992797626878299, -0.538469310105683091036314420700, 0.0, 0.538469310105683091036314420700, 0.906179845938663992797626878299 }; double xtab2[ORDER]; // // Adjust the quadrature rule from [-1,1] to [0,1]: // for ( i = 0; i < ORDER; i++ ) { xtab2[i] = ( xtab[i] + 1.0 ) / 2.0; } for ( i = 0; i < ORDER; i++ ) { wtab2[i] = 0.5 * wtab[i]; } result = box_nd ( func, dim_num, ORDER, xtab2, wtab2, &eval_num ); cout << " BOX_ND: " << setprecision(12) << setw(20) << result << setw(8) << " " << eval_num << "\n"; return; # undef ORDER } //****************************************************************************80 void test02 ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************80 // // Purpose: // // TEST02 tests P5_ND. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 26 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates the function // to be integrated. // { double *a; double *b; int dim; int eval_num; double result; // // Set the integration limits. // a = new double[dim_num]; b = new double[dim_num]; for ( dim = 0; dim < dim_num; dim++ ) { a[dim] = 0.0; } for ( dim = 0; dim < dim_num; dim++ ) { b[dim] = 1.0; } result = p5_nd ( func, dim_num, a, b, &eval_num ); cout << " P5_ND: " << setprecision(12) << setw(20) << result << setw(8) << " " << eval_num << "\n"; delete [] a; delete [] b; return; } //****************************************************************************80 void test03 ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************80 // // Purpose: // // TEST03 tests ROMBERG_ND. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 26 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates the function // to be integrated. // { double *a; double *b; int dim; int eval_num; int ind; int it_max = 3; double result; int *sub_num; double tol; // // Set the integration limits. // a = new double[dim_num]; b = new double[dim_num]; sub_num = new int[dim_num]; for ( dim = 0; dim < dim_num; dim++ ) { a[dim] = 0.0; } for ( dim = 0; dim < dim_num; dim++ ) { b[dim] = 1.0; } tol = 0.001; for ( dim = 0; dim < dim_num; dim++ ) { sub_num[dim] = 10; } result = romberg_nd ( func, a, b, dim_num, sub_num, it_max, tol, &ind, &eval_num ); cout << " ROMBERG_ND: " << setprecision(12) << setw(20) << result << setw(8) << " " << eval_num << "\n"; delete [] a; delete [] b; delete [] sub_num; return; } //****************************************************************************80 void test04 ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************80 // // Purpose: // // TEST04 tests SAMPLE_ND. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 01 March 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates the function // to be integrated. // { # define K2 4 double dev1[K2]; double dev2[K2]; double err1[K2]; double est1[K2]; double est2[K2]; double err2[K2]; int eval_num; int k1; k1 = 1; sample_nd ( func, k1, K2, dim_num, est1, err1, dev1, est2, err2, dev2, &eval_num ); cout << " SAMPLE_ND: " << setprecision(12) << setw(20) << est2[K2-1] << setw(8) << " " << eval_num << "\n"; return; # undef K2 } //****************************************************************************80 void test05 ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************80 // // Purpose: // // TEST05 demonstrates how to refine multi-dimensional integration results. // // Discussion: // // This routine is only set up for DIM_NUM = 2 for now. // // We are given a routine, NDP5, which will integrate over a // DIM_NUM dimensional hypercube using a fixed method. In order to // improve the approximation to an integral, we can subdivide // the hypercube and call NDP5 to integrate again over each of // these regions. // // The information that we gather can be used to tell us when // to expect that we have achieved a certain degree of accuracy. // // With a little more work, we could make this code adaptive. // That is, it would only refine SOME of the subregions, where // the approximation to the integral was still not good enough. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 26 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, integer DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates the function // to be integrated. // { double *a; double *b; int dim; int eval_num; int eval_total; int i; int igrid; int j; int ngrid; double result; double result_total; double *xlo; double *xhi; a = new double[dim_num]; b = new double[dim_num]; xlo = new double[dim_num]; xhi = new double[dim_num]; for ( dim = 0; dim < dim_num; dim++ ) { xlo[dim] = 0.0; } for ( dim = 0; dim < dim_num; dim++ ) { xhi[dim] = 1.0; } for ( igrid = 1; igrid <= 6; igrid++ ) { ngrid = i4_power ( 2, igrid - 1 ); result_total = 0.0; eval_total = 0; for ( i = 1; i <= ngrid; i++ ) { a[0] = ( ( double ) ( ngrid - i + 1 ) * xlo[0] + ( double ) ( i - 1 ) * xhi[0] ) / ( double ) ( ngrid ); b[0] = ( ( double ) ( ngrid - i ) * xlo[0] + ( double ) ( i ) * xhi[0] ) / ( double ) ( ngrid ); for ( j = 1; j <= ngrid; j++ ) { a[1] = ( ( double ) ( ngrid - j + 1 ) * xlo[1] + ( double ) ( j - 1 ) * xhi[1] ) / ( double ) ( ngrid ); b[1] = ( ( double ) ( ngrid - j ) * xlo[1] + ( double ) ( j ) * xhi[1] ) / ( double ) ( ngrid ); result = p5_nd ( func, dim_num, a, b, &eval_num ); result_total = result_total + result; eval_total = eval_total + eval_num; } } cout << " P5_ND+: " << setprecision(12) << setw(20) << result_total << setw(8) << " " << eval_total << "\n"; } delete [] a; delete [] b; delete [] xhi; delete [] xlo; return; } //****************************************************************************80 void test06 ( int dim_num, double func ( int dim_num, double x[] ) ) //****************************************************************************80 // // Purpose: // // TEST06 tests MONTE_CARLO_ND. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double FUNC ( int dim_num, double x[] ), evaluates the function // to be integrated. // { double *a; double *b; int dim; int eval_num; double result; int seed; int test; int test_num = 3; seed = 123456789; // // Set the integration limits. // a = new double[dim_num]; b = new double[dim_num]; for ( dim = 0; dim < dim_num; dim++ ) { a[dim] = 0.0; } for ( dim = 0; dim < dim_num; dim++ ) { b[dim] = 1.0; } for ( test = 1; test <= test_num; test++ ) { eval_num = i4_power ( 8, test ) * 10000; result = monte_carlo_nd ( func, dim_num, a, b, eval_num, &seed ); cout << " MONTE_CARLO_ND: " << setprecision(12) << setw(20) << result << setw(8) << " " << eval_num << "\n"; } delete [] a; delete [] b; return; } //****************************************************************************80 double fbdn ( int dim_num, double x[] ) //****************************************************************************80 // // Purpose: // // FBDN(X(1:DIM_NUM)) = 1 / ( 1 + sum ( X(1:DIM_NUM)**2 ) ) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double X[DIM_NUM], the argument. // // Output, double FBDN, the value of the function at X. // { double arg; int dim; double value; arg = 0.0; for ( dim = 0; dim < dim_num; dim++ ) { arg = arg + x[dim] * x[dim]; } value = 1.0 / ( 1.0 + arg ); return value; } //****************************************************************************80 double fedn ( int dim_num, double x[] ) //****************************************************************************80 // // Purpose: // // FEDN(X(1:DIM_NUM)) = EXP ( sum ( X(1:DIM_NUM) ) ) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double X[DIM_NUM], the argument. // // Output, double FEDN, the value of the function at X. // { double arg; int dim; double value; arg = 0.0; for ( dim = 0; dim < dim_num; dim++ ) { arg = arg + x[dim]; } value = exp ( arg ); return value; } //****************************************************************************80 double f1dn ( int dim_num, double x[] ) //****************************************************************************80 // // Purpose: // // F1DN(X(1:DIM_NUM)) = 1. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double X[DIM_NUM], the argument. // // Output, double F1DN, the value of the function at X. // { double value; value = 1.0; return value; } //****************************************************************************80 double fxdn ( int dim_num, double x[] ) //****************************************************************************80 // // Purpose: // // FXDN(X(1:DIM_NUM)) = sum ( X(1:DIM_NUM) ) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double X[DIM_NUM], the argument. // // Output, double FXDN, the value of the function at X. // { double arg; int dim; double value; arg = 0.0; for ( dim = 0; dim < dim_num; dim++ ) { arg = arg + x[dim]; } value = arg; return value; } //****************************************************************************80 double fx2dn ( int dim_num, double x[] ) //****************************************************************************80 // // Purpose: // // FX2DN(X(1:DIM_NUM)) = sum ( X(1:DIM_NUM)**2 ) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double X[DIM_NUM], the argument. // // Output, double FX2DN, the value of the function at X. // { double arg; int dim; double value; arg = 0.0; for ( dim = 0; dim < dim_num; dim++ ) { arg = arg + x[dim] * x[dim]; } value = arg; return value; } //****************************************************************************80 double fx3dn ( int dim_num, double x[] ) //****************************************************************************80 // // Purpose: // // FX3DN(X(1:DIM_NUM)) = sum ( X(1:DIM_NUM)**3 ) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 February 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int DIM_NUM, the spatial dimension. // // Input, double X[DIM_NUM], the argument. // // Output, double FX3DN, the value of the function at X. // { double arg; int dim; double value; arg = 0.0; for ( dim = 0; dim < dim_num; dim++ ) { arg = arg + x[dim] * x[dim] * x[dim]; } value = arg; return value; }