# include # include # include # include # include using namespace std; # include "halton_advanced.hpp" int main ( ); void test01 ( ); void test0125 ( ); void test0126 ( ); void test02 ( ); void test025 ( ); void test03 ( ); void test04 ( ); void test045 ( ); void test05 ( ); void test06 ( ); void test07 ( ); void test08 ( ); void test09 ( ); void test10 ( ); void test11 ( ); void test12 ( ); void test13 ( ); //****************************************************************************80 int main ( ) //****************************************************************************80 // // Purpose: // // MAIN is the main program for HALTON_ADVANCED_TEST. // // Discussion: // // HALTON_TEST tests the HALTON_ADVANCED library. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 20 October 2006 // // Author: // // John Burkardt // { timestamp ( ); cout << "\n"; cout << "HALTON_ADVANCED_TEST:\n"; cout << " C++ version\n"; cout << " Test the HALTON library.\n"; test01 ( ); test0125 ( ); test0126 ( ); test02 ( ); test025 ( ); test03 ( ); test04 ( ); test045 ( ); test05 ( ); test06 ( ); test07 ( ); test08 ( ); test09 ( ); test10 ( ); test11 ( ); test12 ( ); test13 ( ); // // Terminate. // cout << "\n"; cout << "HALTON_ADVANCED_TEST:\n"; cout << " Normal end of execution.\n"; cout << "\n"; timestamp ( ); return 0; } //****************************************************************************80 void test01 ( ) //****************************************************************************80 // // Purpose: // // TEST01 tests HALTON, HALTON_STEP_SET. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_MAX 3 # define TEST_NUM 4 int base[DIM_MAX]; int i; int j; int n; int dim_num; double r[DIM_MAX]; int seed[DIM_MAX]; int step_vec[TEST_NUM] = { 0, 5, 1000, 1000000 }; int step; int test; cout << "\n"; cout << "TEST01\n"; cout << " HALTON computes the next element of a Halton sequence.\n"; cout << " HALTON_STEP_SET sets the step.\n"; cout << "\n"; cout << " In this test, we try several values of STEP.\n"; cout << " We repeat the test for several dimensions.\n"; cout << " We assume defaults for SEED, LEAP and BASE.\n"; for ( dim_num = 1; dim_num <= DIM_MAX; dim_num++ ) { for ( test = 0; test < TEST_NUM; test++ ) { halton_dim_num_set ( dim_num ); n = 11; step = step_vec[test]; halton_step_set ( step ); for ( i = 0; i < dim_num; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); for ( i = 0; i < dim_num; i++ ) { base[i] = prime ( i + 1 ); } halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << dim_num << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( dim_num, seed, " SEED = " ); i4vec_transpose_print ( dim_num, base, " BASE = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( r ); cout << setw(6) << step + j << " "; for ( i = 0; i < dim_num; i++ ) { cout << setw(12) << r[i] << " "; } cout << "\n"; } } } return; # undef DIM_MAX # undef TEST_NUM } //****************************************************************************80 void test0125 ( ) //****************************************************************************80 // // Purpose: // // TEST0125 tests I4_TO_HALTON. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_MAX 3 int base[DIM_MAX]; int i; int j; int leap[DIM_MAX]; int n; int dim_num; double r[DIM_MAX]; int seed[DIM_MAX]; int step; cout << "\n"; cout << "TEST0125\n"; cout << " I4_TO_HALTON computes a Halton sequence.\n"; cout << " The user gives the seed and bases as explicit input.\n"; cout << "\n"; cout << " In this test, we call I4_TO_HALTON repeatedly.\n"; cout << " We use distinct primes as bases.\n"; for ( dim_num = 1; dim_num <= DIM_MAX; dim_num++ ) { n = 11; step = 0; for ( i = 0; i < dim_num; i++ ) { seed[i] = 0; } for ( i = 0; i < dim_num; i++ ) { leap[i] = 1; } for ( i = 0; i < dim_num; i++ ) { base[i] = prime ( i + 1 ); } cout << "\n"; cout << " DIM_NUM = " << setw(12) << dim_num << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( dim_num, seed, " SEED = " ); i4vec_transpose_print ( dim_num, leap, " LEAP = " ); i4vec_transpose_print ( dim_num, base, " BASE = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { step = j; i4_to_halton ( dim_num, step, seed, leap, base, r ); cout << " " << setw(6) << step << " "; for ( i = 0; i < dim_num; i++ ) { cout << setw(8) << r[i] << " "; } cout << "\n"; } } return; # undef DIM_MAX } //****************************************************************************80 void test0126 ( ) //****************************************************************************80 // // Purpose: // // TEST0126 tests I4_TO_HALTON. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 3 int base[DIM_NUM]; int i; int j; int leap[DIM_NUM]; int n; int dim_num; double r[DIM_NUM]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST0126\n"; cout << " I4_TO_HALTON computes a Halton sequence.\n"; cout << " The user gives the seed and bases as explicit input.\n"; cout << "\n"; cout << " In this test, we call I4_TO_HALTON repeatedly.\n"; cout << " We use the same value for all bases.\n"; n = 11; for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } for ( i = 0; i < DIM_NUM; i++ ) { leap[i] = 1; } for ( i = 0; i < DIM_NUM; i++ ) { base[i] = 2; } cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, leap, " LEAP = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { step = j; i4_to_halton ( DIM_NUM, step, seed, leap, base, r ); cout << " " << setw(6) << j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(8) << r[i] << " "; } cout << "\n"; } return; # undef DIM_NUM } //****************************************************************************80 void test02 ( ) //****************************************************************************80 // // Purpose: // // TEST02 tests HALTON_SEQUENCE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define N 10 # define DIM_NUM 3 int i; int j; double r[DIM_NUM*N]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST02\n"; cout << " HALTON_SEQUENCE computes N elements of \n"; cout << " a Halton sequence on a single call.\n"; halton_dim_num_set ( DIM_NUM ); step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << N << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); halton_sequence ( N, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } return; # undef N # undef DIM_NUM } //****************************************************************************80 void test025 ( ) //****************************************************************************80 // // Purpose: // // TEST025 tests I4_TO_HALTON_SEQUENCE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define N 10 # define DIM_NUM 3 int base[DIM_NUM]; int i; int j; int leap[DIM_NUM]; double r[DIM_NUM*N]; int seed[DIM_NUM]; int step; int test; cout << "\n"; cout << "TEST025\n"; cout << " I4_TO_HALTON_SEQUENCE computes N elements of \n"; cout << " a Halton sequence on a single call.\n"; cout << " All arguments are specified explicitly.\n"; for ( test = 1; test <= 4; test++ ) { if ( test == 1 ) { step = 0; for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } for ( i = 0; i < DIM_NUM; i++ ) { leap[i] = 1; } for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } } else if ( test == 2 ) { step = 0; for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = i + 1; } for ( i = 0; i < DIM_NUM; i++ ) { leap[i] = 1; } for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } } else if ( test == 3 ) { step = 0; for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 1; } for ( i = 0; i < DIM_NUM; i++ ) { leap[i] = 3; } for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } } else if ( test == 4 ) { step = 0; for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = i + 1; } for ( i = 0; i < DIM_NUM; i++ ) { leap[i] = 1; } for ( i = 0; i < DIM_NUM; i++ ) { base[i] = 2; } } cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << N << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, leap, " LEAP = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); i4_to_halton_sequence ( DIM_NUM, N, step, seed, leap, base, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } } return; # undef N # undef DIM_NUM } //****************************************************************************80 void test03 ( ) //****************************************************************************80 // // Purpose: // // TEST03 tests HALTON_SEQUENCE, HALTON_STEP_SET. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 1 # define NMAX 11 int base[DIM_NUM]; int i; int j; int n; double r[DIM_NUM*NMAX]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST03\n"; cout << " HALTON_STEP_SET specifies the next element of\n"; cout << " the Halton sequence to compute.\n"; cout << "\n"; cout << " In this test, we demonstrate how resetting \n"; cout << " STEP determines the next element computed.\n"; halton_dim_num_set ( DIM_NUM ); n = 11; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); base[0] = 2; halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 11; step = 6; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 6; step = 0; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 5; step = 100; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } return; # undef DIM_NUM # undef NMAX } //****************************************************************************80 void test04 ( ) //****************************************************************************80 // // Purpose: // // TEST04 tests HALTON, HALTON_BASE_GET, HALTON_BASE_SET. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 1 int *base; int i; int j; int n; double r[DIM_NUM]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST04\n"; cout << " HALTON_BASE_GET gets the current Halton bases.\n"; cout << " HALTON_BASE_SET sets the current Halton bases.\n"; cout << "\n"; cout << " In this test, we compute a Halton sequence\n"; cout << " with the default base, then change the base,\n"; cout << " reset the seed, and recompute the sequence.\n"; halton_dim_num_set ( DIM_NUM ); n = 10; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); base = halton_base_get ( ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( r ); cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i] << " "; } cout << "\n"; } n = 10; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); for ( i = 0; i < DIM_NUM; i++ ) { base[i] = 3; } halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( r ); cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i] << " "; } cout << "\n"; } n = 10; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); for ( i = 0; i < DIM_NUM; i++ ) { base[i] = 4; } halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( r ); cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i] << " "; } cout << "\n"; } return; # undef DIM_NUM } //****************************************************************************80 void test045 ( ) //****************************************************************************80 // // Purpose: // // TEST045 tests HALTON_SEQUENCE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define N 101 # define DIM_NUM 2 int base[DIM_NUM] = { 2, 3 }; int i; int j; double r[DIM_NUM*N]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST045\n"; cout << " HALTON_SEQUENCE computes N elements of\n"; cout << " a Halton sequence on a single call.\n"; halton_dim_num_set ( DIM_NUM ); step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << N << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); halton_sequence ( N, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(7) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } return; # undef N # undef DIM_NUM } //****************************************************************************80 void test05 ( ) //****************************************************************************80 // // Purpose: // // TEST05 tests HALTON. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 4 int base[DIM_NUM]; int i; int j; int n; double r[DIM_NUM]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST05\n"; cout << " HALTON computes the elements of a vector Halton sequence.\n"; cout << "\n"; cout << " Each call produces the next value.\n"; cout << "\n"; cout << " In this test, we call HALTON several times.\n"; halton_dim_num_set ( DIM_NUM ); n = 11; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( r ); cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << r[i] << " "; } cout << "\n"; } return; # undef DIM_NUM } //****************************************************************************80 void test06 ( ) //****************************************************************************80 // // Purpose: // // TEST06 tests HALTON_SEQUENCE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define N 11 # define DIM_NUM 4 int i; int j; double r[DIM_NUM*N]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST06\n"; cout << " HALTON_SEQUENCE computes the next N elements\n"; cout << " of a vector Halton sequence.\n"; cout << "\n"; cout << " Each call produces the next value. By default,\n"; cout << " the bases are the first DIM_NUM primes.\n"; cout << "\n"; cout << " In this test, we demonstrate how one call can compute\n"; cout << " many successive vector elements of the sequence.\n"; halton_dim_num_set ( DIM_NUM ); step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << N << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); halton_sequence ( N, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } return; # undef N # undef DIM_NUM } //****************************************************************************80 void test07 ( ) //****************************************************************************80 // // Purpose: // // TEST07 tests HALTON_STEP_SET, HALTON_SEQUENCE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 4 # define NMAX 10 int *base; int i; int j; int *leap; int n; double r[DIM_NUM*NMAX]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST07\n"; cout << " HALTON_STEP_SET specifies which element of the\n"; cout << " Halton subsequence to compute.\n"; cout << "\n"; cout << " In this test, we show how STEP chooses the next element.\n"; halton_dim_num_set ( DIM_NUM ); n = 10; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); leap = halton_leap_get ( ); base = halton_base_get ( ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, leap, " LEAP = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 10; step = 6; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 6; step = 0; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 5; step = 100; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; halton_sequence ( n, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } return; # undef DIM_NUM # undef NMAX } //****************************************************************************80 void test08 ( ) //****************************************************************************80 // // Purpose: // // TEST08 tests HALTON_BASE_GET, HALTON_BASE_SET, HALTON_SEQUENCE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define N 10 # define DIM_NUM 4 int base[DIM_NUM]; int i; int j; int n; double r[DIM_NUM*N]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST08\n"; cout << " HALTON_BASE_GET gets the current bases.\n"; cout << " HALTON_BASE_SET sets the current bases.\n"; cout << " HALTON_SEQUENCE computes the next N elements\n"; cout << " of a vector Halton sequence.\n"; cout << "\n"; cout << " In this test, we compute the first 10 elements of a\n"; cout << " sequence, then change bases, reset the seed\n"; cout << " and recompute.\n"; halton_dim_num_set ( DIM_NUM ); step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } halton_base_set ( base ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << N << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); halton_sequence ( N, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } n = 10; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( 2 * ( i + 1 ) ); } halton_base_set ( base ); cout << "\n"; i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); halton_sequence ( N, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } return; # undef N # undef DIM_NUM } //****************************************************************************80 void test09 ( ) //****************************************************************************80 // // Purpose: // // TEST09 tests U1_TO_SPHERE_UNIT_2D. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 1 # define DIM_NUM2 2 double average[DIM_NUM2]; double average_dot; double dot_average; int i; int i2; int j; int j2; int n; int seed[DIM_NUM]; int step; double u[DIM_NUM]; double v[DIM_NUM2]; double x[DIM_NUM2]; cout << "\n"; cout << "TEST09\n"; cout << " For the unit sphere in 2 dimensions (the circle):\n"; cout << " HALTON generates \"U1\" points,\n"; cout << " U1_TO_SPHERE_UNIT_2D maps U2 points to the circle;\n"; halton_dim_num_set ( DIM_NUM ); n = 5; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; cout << "\n"; cout << " A few sample values:\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( u ); u1_to_sphere_unit_2d ( u, x ); cout << " "; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { cout << setw(10) << x[i2] << " "; } cout << "\n"; } n = 1000; step = 0; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { average[i2] = 0.0; } for ( j = 0; j < n; j++ ) { halton ( u ); u1_to_sphere_unit_2d ( u, x ); for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { average[i2] = average[i2] + x[i2]; } } for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { average[i2] = average[i2] / ( ( double ) n ); } cout << "\n"; cout << " Average the points, which should get a value\n"; cout << " close to zero, and closer as N increases.\n"; cout << "\n"; cout << " Average: "; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { cout << setw(10) << average[i2] << " "; } cout << "\n"; cout << "\n"; cout << " Now choose a random direction, sample the same\n"; cout << " number of points, and compute the dot product with\n"; cout << " the direction.\n"; cout << " Take the absolute value of each dot product\n"; cout << " and sum and average.\n"; cout << "\n"; cout << " We expect a value near 2 / PI = 0.6366...\n"; for ( j2 = 0; j2 < 5; j2++ ) { step = get_seed ( ) + 111 * j2; halton_step_set ( step ); halton ( u ); u1_to_sphere_unit_2d ( u, v ); step = 0; halton_step_set ( step ); dot_average = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u1_to_sphere_unit_2d ( u, x ); dot_average = dot_average + fabs ( r8vec_dot_product ( DIM_NUM2, x, v ) ); } dot_average = dot_average / ( ( double ) n ); cout << "\n"; cout << " Random V: "; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { cout << setw(10) << v[i2] << " "; } cout << "\n"; cout << " Average |(XdotV)| " << setw(10) << dot_average << "\n"; } return; # undef DIM_NUM # undef DIM_NUM2 } //****************************************************************************80 void test10 ( ) //****************************************************************************80 // // Purpose: // // TEST10 tests U2_TO_BALL_UNIT_2D. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 2 double average[DIM_NUM]; double average_r; double average_theta; int i; int j; int n = 1000; double r; int seed[DIM_NUM]; int step; double theta; double u[DIM_NUM]; double v[DIM_NUM]; double x[DIM_NUM]; cout << "\n"; cout << "TEST10\n"; cout << " For the unit ball in 2 dimensions (the disk):\n"; cout << " U2_TO_BALL_UNIT_2D samples;\n"; halton_dim_num_set ( DIM_NUM ); n = 5; step = 0; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; cout << "\n"; cout << " A few sample values:\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_ball_unit_2d ( u, x ); cout << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << x[i] << " "; } cout << "\n"; } n = 1000; step = 0; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; for ( i = 0; i < DIM_NUM; i++ ) { average[i] = 0.0; } for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_ball_unit_2d ( u, x ); for ( i = 0; i < DIM_NUM; i++ ) { average[i] = average[i] + x[i]; } } for ( i = 0; i < DIM_NUM; i++ ) { average[i] = average[i] / ( ( double ) n ); } cout << "\n"; cout << " Average the points, which should get a value\n"; cout << " close to zero, and closer as N increases.\n"; cout << "\n"; cout << " Average: "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << average[i] << " "; } cout << "\n"; step = 0; halton_step_set ( step ); average_r = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_ball_unit_2d ( u, x ); r = r8vec_norm_l2 ( DIM_NUM, x ); average_r = average_r + r; } average_r = average_r / ( ( double ) n ); cout << "\n"; cout << " Average the distance of the points from\n"; cout << " the center, which should be \n"; cout << " DIM_NUM / ( DIM_NUM + 1 ) = " << ( ( double ) DIM_NUM ) / ( ( double ) ( DIM_NUM + 1 ) ) << "\n"; cout << "\n"; cout << " Average: " << average_r << "\n"; step = 0; halton_step_set ( step ); average_theta = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_ball_unit_2d ( u, x ); theta = atan4 ( x[1], x[0] ); average_theta = average_theta + theta; } average_theta = average_theta / ( ( double ) n ); cout << "\n"; cout << " Average the angle THETA, which should approach PI.\n"; cout << "\n"; cout << " Average: " << average_theta << "\n"; return; # undef DIM_NUM } //****************************************************************************80 void test11 ( ) //****************************************************************************80 // // Purpose: // // TEST11 tests U2_TO_SPHERE_UNIT_3D. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 2 # define DIM_NUM2 3 double average[DIM_NUM2]; double dot_average; int i; int i2; int j; int j2; int n; int seed[DIM_NUM]; int step; double u[DIM_NUM]; double v[DIM_NUM2]; double x[DIM_NUM2]; cout << "\n"; cout << "TEST11\n"; cout << " For the unit sphere in 3 dimensions:\n"; cout << " U2_TO_SPHERE_UNIT_3D samples;\n"; halton_dim_num_set ( DIM_NUM ); n = 5; step = 123456789; halton_step_set ( step ); for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } halton_seed_set ( seed ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; cout << "\n"; cout << " A few sample values:\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_sphere_unit_3d ( u, x ); cout << " "; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { cout << setw(10) << x[i2] << " "; } cout << "\n"; } n = 1000; step = 0; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; for ( i = 0; i < DIM_NUM2; i++ ) { average[i] = 0.0; } for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_sphere_unit_3d ( u, x ); for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { average[i2] = average[i2] + x[i2]; } } for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { average[i2] = average[i2] / ( ( double ) n ); } cout << "\n"; cout << " Average the points, which should get a value\n"; cout << " close to zero, and closer as N increases.\n"; cout << "\n"; cout << " Average: "; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { cout << setw(10) << average[i2] << " "; } cout << "\n"; cout << "\n"; cout << " Now choose a random direction, sample the same\n"; cout << " number of points, and compute the dot product with\n"; cout << " the direction.\n"; cout << " Take the absolute value of each dot product\n"; cout << " and sum and average.\n"; for ( j2 = 0; j2 < 5; j2++ ) { step = get_seed ( ) + 111 * j2; halton_step_set ( step ); halton ( u ); u2_to_sphere_unit_3d ( u, v ); step = 0; halton_step_set ( step ); dot_average = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u2_to_sphere_unit_3d ( u, x ); dot_average = dot_average + fabs ( r8vec_dot_product ( DIM_NUM2, x, v ) ); } dot_average = dot_average / ( ( double ) n ); cout << "\n"; cout << " Random V: "; for ( i2 = 0; i2 < DIM_NUM2; i2++ ) { cout << setw(10) << v[i2] << " "; } cout << "\n"; cout << " Average |(XdotV)| " << setw(10) << dot_average << "\n"; } return; # undef DIM_NUM # undef DIM_NUM2 } //****************************************************************************80 void test12 ( ) //****************************************************************************80 // // Purpose: // // TEST12 tests U3_TO_BALL_UNIT_3D. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define DIM_NUM 3 double average[DIM_NUM]; double average_phi; double average_r; double average_theta; int i; int j; int n; double phi; double r; int seed[DIM_NUM]; int step; double theta; double u[DIM_NUM]; double v[DIM_NUM]; double x[DIM_NUM]; cout << "\n"; cout << "TEST12\n"; cout << " For the unit ball in 3 dimensions:\n"; cout << " U3_TO_BALL_UNIT_3D samples;\n"; halton_dim_num_set ( DIM_NUM ); n = 5; step = 0; halton_step_set ( step ); cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; cout << "\n"; cout << " A few sample values:\n"; cout << "\n"; for ( j = 0; j < n; j++ ) { halton ( u ); u3_to_ball_unit_3d ( u, x ); cout << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << x[i] << " "; } cout << "\n"; } n = 1000; step = 0; halton_step_set ( step ); cout << "\n"; cout << " N = " << setw(12) << n << "\n"; cout << " STEP = " << setw(12) << step << "\n"; for ( i = 0; i < DIM_NUM; i++ ) { average[i] = 0.0; } for ( j = 0; j < n; j++ ) { halton ( u ); u3_to_ball_unit_3d ( u, x ); for ( i = 0; i < DIM_NUM; i++ ) { average[i] = average[i] + x[i]; } } for ( i = 0; i < DIM_NUM; i++ ) { average[i] = average[i] / ( ( double ) n ); } cout << "\n"; cout << " Average the points, which should get a value\n"; cout << " close to zero, and closer as N increases.\n"; cout << "\n"; cout << " Average: "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(10) << average[i] << " "; } cout << "\n"; step = 0; halton_step_set ( step ); average_r = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u3_to_ball_unit_3d ( u, x ); r = r8vec_norm_l2 ( DIM_NUM, x ); average_r = average_r + r; } average_r = average_r / ( ( double ) n ); cout << "\n"; cout << " Average the distance of the points from\n"; cout << " the center, which should be \n"; cout << " DIM_NUM / ( DIM_NUM + 1 ) = " << ( ( double ) DIM_NUM ) / ( ( double ) ( DIM_NUM + 1 ) ) << "\n"; cout << "\n"; cout << " Average: " << average_r << "\n"; step = 0; halton_step_set ( step ); average_theta = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u3_to_ball_unit_3d ( u, x ); theta = atan4 ( x[1], x[0] ); average_theta = average_theta + theta; } average_theta = average_theta / ( ( double ) n ); cout << "\n"; cout << " Average the angle THETA,\n"; cout << " which should approach PI.\n"; cout << "\n"; cout << " Average: " << average_theta << "\n"; step = 0; halton_step_set ( step ); average_phi = 0.0; for ( j = 0; j < n; j++ ) { halton ( u ); u3_to_ball_unit_3d ( u, x ); r = r8vec_norm_l2 ( DIM_NUM, x ); if ( r == 0.0 ) { phi = 0.0; } else { phi = acos ( x[2] / r ); } average_phi = average_phi + phi; } average_phi = average_phi / ( ( double ) n ); cout << "\n"; cout << " Average the angle PHI,\n"; cout << " which should approach PI/2.\n"; cout << "\n"; cout << " Average: " << average_phi << "\n"; return; # undef DIM_NUM } //****************************************************************************80 void test13 ( ) //****************************************************************************80 // // Purpose: // // TEST13 tests HALHAM_WRITE. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 June 2008 // // Author: // // John Burkardt // { # define N 10 # define DIM_NUM 3 int base[DIM_NUM]; char file_name[81] = "halton_03_00010.txt"; int i; int j; int leap[DIM_NUM]; double r[DIM_NUM*N]; int seed[DIM_NUM]; int step; cout << "\n"; cout << "TEST13\n"; cout << " HALHAM_WRITE writes a Halton or Hammersley dataset to a file\n"; step = 0; for ( i = 0; i < DIM_NUM; i++ ) { seed[i] = 0; } for ( i = 0; i < DIM_NUM; i++ ) { leap[i] = 1; } for ( i = 0; i < DIM_NUM; i++ ) { base[i] = prime ( i + 1 ); } cout << "\n"; cout << " DIM_NUM = " << setw(12) << DIM_NUM << "\n"; cout << " N = " << setw(12) << N << "\n"; cout << " STEP = " << setw(12) << step << "\n"; i4vec_transpose_print ( DIM_NUM, seed, " SEED = " ); i4vec_transpose_print ( DIM_NUM, leap, " LEAP = " ); i4vec_transpose_print ( DIM_NUM, base, " BASE = " ); i4_to_halton_sequence ( DIM_NUM, N, step, seed, leap, base, r ); cout << "\n"; cout << " STEP Halton\n"; cout << "\n"; for ( j = 0; j < N; j++ ) { cout << " " << setw(6) << step + j << " "; for ( i = 0; i < DIM_NUM; i++ ) { cout << setw(12) << r[i+j*DIM_NUM] << " "; } cout << "\n"; } halham_write ( DIM_NUM, N, step, seed, leap, base, r, file_name ); cout << "\n"; cout << " The data was written to \"" << file_name << "\".\n"; return; # undef N # undef DIM_NUM }