# include # include # include # include # include # include # include using namespace std; # include "triangle_lyness_rule.hpp" //****************************************************************************80 int i4_max ( int i1, int i2 ) //****************************************************************************80 // // Purpose: // // I4_MAX returns the maximum of two I4's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 13 October 1998 // // Author: // // John Burkardt // // Parameters: // // Input, int I1, I2, are two integers to be compared. // // Output, int I4_MAX, the larger of I1 and I2. // { int value; if ( i2 < i1 ) { value = i1; } else { value = i2; } return value; } //****************************************************************************80 int i4_min ( int i1, int i2 ) //****************************************************************************80 // // Purpose: // // I4_MIN returns the minimum of two I4's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 13 October 1998 // // Author: // // John Burkardt // // Parameters: // // Input, int I1, I2, two integers to be compared. // // Output, int I4_MIN, the smaller of I1 and I2. // { int value; if ( i1 < i2 ) { value = i1; } else { value = i2; } return value; } //****************************************************************************80 int i4_modp ( int i, int j ) //****************************************************************************80 // // Purpose: // // I4_MODP returns the nonnegative remainder of I4 division. // // Discussion: // // If // NREM = I4_MODP ( I, J ) // NMULT = ( I - NREM ) / J // then // I = J * NMULT + NREM // where NREM is always nonnegative. // // The MOD function computes a result with the same sign as the // quantity being divided. Thus, suppose you had an angle A, // and you wanted to ensure that it was between 0 and 360. // Then mod(A,360) would do, if A was positive, but if A // was negative, your result would be between -360 and 0. // // On the other hand, I4_MODP(A,360) is between 0 and 360, always. // // I J MOD I4_MODP I4_MODP Factorization // // 107 50 7 7 107 = 2 * 50 + 7 // 107 -50 7 7 107 = -2 * -50 + 7 // -107 50 -7 43 -107 = -3 * 50 + 43 // -107 -50 -7 43 -107 = 3 * -50 + 43 // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 26 May 1999 // // Author: // // John Burkardt // // Parameters: // // Input, int I, the number to be divided. // // Input, int J, the number that divides I. // // Output, int I4_MODP, the nonnegative remainder when I is // divided by J. // { int value; if ( j == 0 ) { cerr << "\n"; cerr << "I4_MODP - Fatal error!\n"; cerr << " I4_MODP ( I, J ) called with J = " << j << "\n"; exit ( 1 ); } value = i % j; if ( value < 0 ) { value = value + abs ( j ); } return value; } //****************************************************************************80 int i4_wrap ( int ival, int ilo, int ihi ) //****************************************************************************80 // // Purpose: // // I4_WRAP forces an I4 to lie between given limits by wrapping. // // Example: // // ILO = 4, IHI = 8 // // I Value // // -2 8 // -1 4 // 0 5 // 1 6 // 2 7 // 3 8 // 4 4 // 5 5 // 6 6 // 7 7 // 8 8 // 9 4 // 10 5 // 11 6 // 12 7 // 13 8 // 14 4 // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 19 August 2003 // // Author: // // John Burkardt // // Parameters: // // Input, int IVAL, an integer value. // // Input, int ILO, IHI, the desired bounds for the integer value. // // Output, int I4_WRAP, a "wrapped" version of IVAL. // { int jhi; int jlo; int value; int wide; jlo = i4_min ( ilo, ihi ); jhi = i4_max ( ilo, ihi ); wide = jhi + 1 - jlo; if ( wide == 1 ) { value = jlo; } else { value = jlo + i4_modp ( ival - jlo, wide ); } return value; } //****************************************************************************80 int *i4vec_copy_new ( int n, int a1[] ) //****************************************************************************80 // // Purpose: // // I4VEC_COPY_NEW copies an I4VEC to a "new" I4VEC. // // Discussion: // // An I4VEC is a vector of I4's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 04 July 2008 // // Author: // // John Burkardt // // Parameters: // // Input, int N, the number of entries in the vectors. // // Input, int A1[N], the vector to be copied. // // Output, int I4VEC_COPY_NEW[N], the copy of A1. // { int *a2; int i; a2 = new int[n]; for ( i = 0; i < n; i++ ) { a2[i] = a1[i]; } return a2; } //****************************************************************************80 int lyness_order ( int rule ) //****************************************************************************80 // // Purpose: // // LYNESS_ORDER returns the order of a Lyness quadrature rule. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 29 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Input, int RULE, the index of the rule. // // Output, int LYNESS_ORDER, the order of the rule. // { int order; if ( rule == 0 ) { order = 1; } else if ( rule == 1 ) { order = 3; } else if ( rule == 2 ) { order = 4; } else if ( rule == 3 ) { order = 4; } else if ( rule == 4 ) { order = 7; } else if ( rule == 5 ) { order = 6; } else if ( rule == 6 ) { order = 10; } else if ( rule == 7 ) { order = 9; } else if ( rule == 8 ) { order = 7; } else if ( rule == 9 ) { order = 10; } else if ( rule == 10 ) { order = 12; } else if ( rule == 11 ) { order = 16; } else if ( rule == 12 ) { order = 13; } else if ( rule == 13 ) { order = 13; } else if ( rule == 14 ) { order = 16; } else if ( rule == 15 ) { order = 16; } else if ( rule == 16 ) { order = 21; } else if ( rule == 17 ) { order = 16; } else if ( rule == 18 ) { order = 19; } else if ( rule == 19 ) { order = 22; } else if ( rule == 20 ) { order = 27; } else if ( rule == 21 ) { order = 28; } else { cerr << "\n"; cerr << "LYNESS_ORDER - Fatal error!\n"; cerr << " Unrecognized rule index.\n"; exit ( 1 ); } return order; } //****************************************************************************80 int lyness_precision ( int rule ) //****************************************************************************80 // // Purpose: // // LYNESS_PRECISION returns the precision of a Lyness quadrature rule. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 29 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Input, int RULE, the index of the rule. // // Output, int LYNESS_PRECISION, the precision of the rule. // { int precision; if ( rule == 0 ) { precision = 1; } else if ( rule == 1 ) { precision = 2; } else if ( rule == 2 ) { precision = 2; } else if ( rule == 3 ) { precision = 3; } else if ( rule == 4 ) { precision = 3; } else if ( rule == 5 ) { precision = 4; } else if ( rule == 6 ) { precision = 4; } else if ( rule == 7 ) { precision = 4; } else if ( rule == 8 ) { precision = 5; } else if ( rule == 9 ) { precision = 5; } else if ( rule == 10 ) { precision = 6; } else if ( rule == 11 ) { precision = 6; } else if ( rule == 12 ) { precision = 6; } else if ( rule == 13 ) { precision = 7; } else if ( rule == 14 ) { precision = 7; } else if ( rule == 15 ) { precision = 8; } else if ( rule == 16 ) { precision = 8; } else if ( rule == 17 ) { precision = 8; } else if ( rule == 18 ) { precision = 9; } else if ( rule == 19 ) { precision = 9; } else if ( rule == 20 ) { precision = 11; } else if ( rule == 21 ) { precision = 11; } else { cout << "\n"; cout << "LYNESS_PRECISION - Fatal error!\n"; cout << " Unrecognized rule index.\n"; exit ( 1 ); } return precision; } //****************************************************************************80 void lyness_rule ( int rule, int order, double w[], double x[] ) //****************************************************************************80 // // Purpose: // // LYNESS_RULE returns the points and weights of a Lyness quadrature rule. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Input, int RULE, the index of the rule. // // Input, int ORDER, the order of the rule. // // Output, double W[ORDER], the weights. // // Output, double X[2*ORDER], the points. // { int k; int o; int s; int *suborder; int suborder_num; double *sub_w; double *sub_xyz; // // Get the suborder information. // suborder_num = lyness_suborder_num ( rule ); suborder = lyness_suborder ( rule, suborder_num ); sub_xyz = new double[3*suborder_num]; sub_w = new double[suborder_num]; lyness_subrule ( rule, suborder_num, sub_xyz, sub_w ); // // Expand the suborder information to a full order rule. // o = 0; for ( s = 0; s < suborder_num; s++ ) { if ( suborder[s] == 1 ) { x[0+o*2] = sub_xyz[0+s*3]; x[1+o*2] = sub_xyz[1+s*3]; w[o] = sub_w[s]; o = o + 1; } else if ( suborder[s] == 3 ) { for ( k = 0; k < 3; k++ ) { x[0+o*2] = sub_xyz [ i4_wrap(k, 0,2) + s*3]; x[1+o*2] = sub_xyz [ i4_wrap(k+1,0,2) + s*3]; w[o] = sub_w[s] / 3.0; o = o + 1; } } else if ( suborder[s] == 6 ) { for ( k = 0; k < 3; k++ ) { x[0+o*2] = sub_xyz [ i4_wrap(k, 0,2) + s*3]; x[1+o*2] = sub_xyz [ i4_wrap(k+1,0,2) + s*3]; w[o] = sub_w[s] / 6.0; o = o + 1; } for ( k = 0; k < 3; k++ ) { x[0+o*2] = sub_xyz [ i4_wrap(k+1,0,2) + s*3]; x[1+o*2] = sub_xyz [ i4_wrap(k, 0,2) + s*3]; w[o] = sub_w[s] / 6.0; o = o + 1; } } else { cout << "\n"; cout << "LYNESS_RULE - Fatal error!\n"; cout << " Illegal SUBORDER[" << s << "] = " << suborder[2] << "\n"; exit ( 1 ); } } delete [] suborder; delete [] sub_xyz; delete [] sub_w; return; } //****************************************************************************80 int lyness_rule_num ( ) //****************************************************************************80 // // Purpose: // // LYNESS_RULE_NUM returns the number of Lyness quadrature rules. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Output, int LYNESS_RULE_NUM, the number of rules. // { int rule_num; rule_num = 21; return rule_num; } //****************************************************************************80 int *lyness_suborder ( int rule, int suborder_num ) //****************************************************************************80 // // Purpose: // // LYNESS_SUBORDER returns the suborders for a Lyness rule. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 28 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Input, int RULE, the index of the rule. // // Input, int SUBORDER_NUM, the number of suborders // of the rule. // // Output, int LYNESS_SUBORDER[SUBORDER_NUM], the suborders // of the rule. // { int *suborder; int suborder_00[1] = { 1 }; int suborder_01[1] = { 3 }; int suborder_02[2] = { 1, 3 }; int suborder_03[2] = { 1, 3 }; int suborder_04[3] = { 1, 3, 3 }; int suborder_05[2] = { 3, 3 }; int suborder_06[3] = { 1, 3, 6 }; int suborder_07[3] = { 3, 3, 3 }; int suborder_08[3] = { 1, 3, 3 }; int suborder_09[4] = { 1, 3, 3, 3 }; int suborder_10[3] = { 3, 3, 6 }; int suborder_11[5] = { 1, 3, 3, 3, 6 }; int suborder_12[4] = { 1, 3, 3, 6 }; int suborder_13[4] = { 1, 3, 3, 6 }; int suborder_14[5] = { 1, 3, 3, 3, 6 }; int suborder_15[5] = { 1, 3, 3, 3, 6 }; int suborder_16[6] = { 3, 3, 3, 3, 3, 6 }; int suborder_17[5] = { 1, 3, 3, 3, 6 }; int suborder_18[6] = { 1, 3, 3, 3, 3, 6 }; int suborder_19[7] = { 1, 3, 3, 3, 3, 3, 6 }; int suborder_20[7] = { 3, 3, 3, 3, 3, 6, 6 }; int suborder_21[8] = { 1, 3, 3, 3, 3, 3, 6, 6 }; suborder = new int[suborder_num]; if ( rule == 0 ) { suborder = i4vec_copy_new ( suborder_num, suborder_00 ); } else if ( rule == 1 ) { suborder = i4vec_copy_new ( suborder_num, suborder_01 ); } else if ( rule == 2 ) { suborder = i4vec_copy_new ( suborder_num, suborder_02 ); } else if ( rule == 3 ) { suborder = i4vec_copy_new ( suborder_num, suborder_03 ); } else if ( rule == 4 ) { suborder = i4vec_copy_new ( suborder_num, suborder_04 ); } else if ( rule == 5 ) { suborder = i4vec_copy_new ( suborder_num, suborder_05 ); } else if ( rule == 6 ) { suborder = i4vec_copy_new ( suborder_num, suborder_06 ); } else if ( rule == 7 ) { suborder = i4vec_copy_new ( suborder_num, suborder_07 ); } else if ( rule == 8 ) { suborder = i4vec_copy_new ( suborder_num, suborder_08 ); } else if ( rule == 9 ) { suborder = i4vec_copy_new ( suborder_num, suborder_09 ); } else if ( rule == 10 ) { suborder = i4vec_copy_new ( suborder_num, suborder_10 ); } else if ( rule == 11 ) { suborder = i4vec_copy_new ( suborder_num, suborder_11 ); } else if ( rule == 12 ) { suborder = i4vec_copy_new ( suborder_num, suborder_12 ); } else if ( rule == 13 ) { suborder = i4vec_copy_new ( suborder_num, suborder_13 ); } else if ( rule == 14 ) { suborder = i4vec_copy_new ( suborder_num, suborder_14 ); } else if ( rule == 15 ) { suborder = i4vec_copy_new ( suborder_num, suborder_15 ); } else if ( rule == 16 ) { suborder = i4vec_copy_new ( suborder_num, suborder_16 ); } else if ( rule == 17 ) { suborder = i4vec_copy_new ( suborder_num, suborder_17 ); } else if ( rule == 18 ) { suborder = i4vec_copy_new ( suborder_num, suborder_18 ); } else if ( rule == 19 ) { suborder = i4vec_copy_new ( suborder_num, suborder_19 ); } else if ( rule == 20 ) { suborder = i4vec_copy_new ( suborder_num, suborder_20 ); } else if ( rule == 21 ) { suborder = i4vec_copy_new ( suborder_num, suborder_21 ); } else { cout << "\n"; cout << "LYNESS_SUBORDER - Fatal error!\n"; cout << " Illegal RULE = " << rule << "\n"; exit ( 1 ); } return suborder; } //****************************************************************************80 int lyness_suborder_num ( int rule ) //****************************************************************************80 // // Purpose: // // LYNESS_SUBORDER_NUM returns the number of suborders for a Lyness rule. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 29 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Input, int RULE, the index of the rule. // // Output, int LYNESS_SUBORDER_NUM, the number of suborders // of the rule. // { int suborder_num; if ( rule == 0 ) { suborder_num = 1; } else if ( rule == 1 ) { suborder_num = 1; } else if ( rule == 2 ) { suborder_num = 2; } else if ( rule == 3 ) { suborder_num = 2; } else if ( rule == 4 ) { suborder_num = 3; } else if ( rule == 5 ) { suborder_num = 2; } else if ( rule == 6 ) { suborder_num = 3; } else if ( rule == 7 ) { suborder_num = 3; } else if ( rule == 8 ) { suborder_num = 3; } else if ( rule == 9 ) { suborder_num = 4; } else if ( rule == 10 ) { suborder_num = 3; } else if ( rule == 11 ) { suborder_num = 5; } else if ( rule == 12 ) { suborder_num = 4; } else if ( rule == 13 ) { suborder_num = 4; } else if ( rule == 14 ) { suborder_num = 5; } else if ( rule == 15 ) { suborder_num = 5; } else if ( rule == 16 ) { suborder_num = 6; } else if ( rule == 17 ) { suborder_num = 5; } else if ( rule == 18 ) { suborder_num = 6; } else if ( rule == 19 ) { suborder_num = 7; } else if ( rule == 20 ) { suborder_num = 7; } else if ( rule == 21 ) { suborder_num = 8; } else { cout << "\n"; cout << "LYNESS_SUBORDER_NUM - Fatal error!\n"; cout << " Illegal RULE = " << rule << "\n"; exit ( 1 ); } return suborder_num; } //****************************************************************************80 void lyness_subrule ( int rule, int suborder_num, double sub_xyz[], double sub_w[] ) //****************************************************************************80 // // Purpose: // // LYNESS_SUBRULE returns a compressed Lyness rule. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 30 September 2010 // // Author: // // John Burkardt // // Reference: // // James Lyness, Dennis Jespersen, // Moderate Degree Symmetric Quadrature Rules for the Triangle, // Journal of the Institute of Mathematics and its Applications, // Volume 15, Number 1, February 1975, pages 19-32. // // Parameters: // // Input, int RULE, the index of the rule. // // Input, int SUB_ORDER_NUM, the number of suborders // of the rule. // // Output, double SUBORDER_XYZ[3*SUBORDER_NUM], // the barycentric coordinates of the abscissas. // // Output, double SUBORDER_W[SUBORDER_NUM], the // suborder weights. // { double sub_w_00[1] = { 1.0000000000E+00 }; double sub_w_01[1] = { 1.0000000000E+00 }; double sub_w_02[2] = { 0.7500000000E+00, 0.2500000000E+00 }; double sub_w_03[2] = { - 0.5625000000E+00, 1.5625000000E+00 }; double sub_w_04[3] = { 0.45E+00, 0.15E+00, 0.40E+00 }; double sub_w_05[2] = { 3.298552309659655E-01, 6.701447690340345E-01 }; double sub_w_06[3] = { 0.45E+00, - 0.05E+00, 0.60E+00 }; double sub_w_07[3] = { 6.16204060378000851E-02, 0.18592649660480146E+00, 0.75245309735739840E+00 }; double sub_w_08[3] = { 0.22500000000000000E+00, 0.37781754163448150E+00, 0.39718245836551852E+00 }; double sub_w_09[4] = { 0.25312500000000000E+00, 0.03333333333333333E+00, 0.21333333333333333E+00, 0.50020833333333333E+00 }; double sub_w_10[3] = { 3.503588271790222E-01, 1.525347191106164E-01, 4.971064537103575E-01 }; double sub_w_11[5] = { -0.57857142857142863E+00, -5.95238095238095205E-02, 0.16190476190476191E+00, 1.2190476190476192E+00, 0.25714285714285712E+00 }; double sub_w_12[4] = { 1.527089667883523E-01, 2.944076042366762E-01, 3.887052878418766E-01, 1.641781411330949E-01 }; double sub_w_13[4] = { - 1.495700444677495E-01, 5.268457722996828E-01, 1.600417068265167E-01, 4.626825653415500E-01 }; double sub_w_14[5] = { 1.763126156005252E-01, 1.210901532768310E-02, 3.499561757697094E-01, 3.195119754425220E-01, 1.421102178595603E-01 }; double sub_w_15[5] = { 1.443156076777862E-01, 2.852749028018549E-01, 9.737549286959440E-02, 3.096521116041552E-01, 1.633818850466092E-01 }; double sub_w_16[6] = { 1.207273935292775E-02, -8.491579879151455E-01, 1.042367468891334E+00, 1.947229791412260E-01, 4.511852767201322E-01, 1.488095238095238E-01 }; double sub_w_17[5] = { - 2.834183851113958E-01, 2.097208857979572E-01, 5.127273801480265E-02, 6.564896469913506E-01, 3.659351143072855E-01 }; double sub_w_18[6] = { 9.713579628279610E-02, 9.400410068141950E-02, 2.334826230143263E-01, 2.389432167816273E-01, 7.673302697609430E-02, 2.597012362637364E-01 }; double sub_w_19[7] = { 1.133624844599192E-01, 1.062573789846380E-03, 4.803411513859279E-02, 2.524243006337300E-01, 7.819254371487040E-02, 2.472227459993048E-01, 2.597012362637364E-01 }; double sub_w_20[7] = { 4.097919300803106E-02, 1.085536215102866E-01, 2.781018986881812E-03, 1.779689321422668E-01, 2.314486047444677E-01, 3.140226717732234E-01, 1.242459578348437E-01 }; double sub_w_21[8] = { 8.797730116222190E-02, 2.623293466120857E-02, 1.142447159818060E-01, 5.656634416839376E-02, 2.164790926342230E-01, 2.079874161166116E-01, 4.417430269980344E-02, 2.463378925757316E-01 }; double sub_xyz_00[3*1] = { 0.3333333333E+00, 0.3333333333E+00, 0.3333333334E+00 }; double sub_xyz_01[3*1] = { 0.0000000000E+00, 0.5000000000E+00, 0.5000000000E+00 }; double sub_xyz_02[3*2] = { 0.3333333333E+00, 0.3333333333E+00, 0.3333333334E+00, 1.0000000000E+00, 0.0000000000E+00, 0.0000000000E+00 }; double sub_xyz_03[3*2] = { 0.3333333333E+00, 0.3333333333E+00, 0.3333333334E+00, 0.6000000000E+00, 0.2000000000E+00, 0.2000000000E+00 }; double sub_xyz_04[3*3] = { 0.33333333333333333E+00, 0.33333333333333333E+00, 0.33333333333333333E+00, 1.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.50000000000000000E+00, 0.50000000000000000E+00 }; double sub_xyz_05[3*2] = { 8.168475729804585E-01, 9.157621350977073E-02, 9.15762135097707569E-02, 1.081030181680702E-01, 4.459484909159649E-01, 0.44594849091596489E+00 }; double sub_xyz_06[3*3] = { 0.33333333333333333E+00, 0.33333333333333333E+00, 0.33333333333333333E+00, 1.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.78867513459481281E+00, 0.21132486540518719E+00 }; double sub_xyz_07[3*3] = { 1.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.50000000000000000E+00, 0.50000000000000000E+00, 0.62283903060710999E+00, 0.18858048469644506E+00, 0.18858048469644506E+00 }; double sub_xyz_08[3*3] = { 0.33333333333333333E+00, 0.33333333333333333E+00, 0.33333333333333333E+00, 0.79742698535308720E+00, 0.10128650732345633E+00, 0.10128650732345633E+00, 5.97158717897698088E-02, 0.47014206410511505E+00, 0.47014206410511505E+00 }; double sub_xyz_09[3*4] = { 0.33333333333333333E+00, 0.33333333333333333E+00, 0.33333333333333333E+00, 1.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.50000000000000000E+00, 0.50000000000000000E+00, 0.71428571428571430E-00, 0.14285714285714285E+00, 0.14285714285714285E+00 }; double sub_xyz_10[3*3] = { 5.014265096581342E-01, 2.492867451709329E-01, 0.24928674517093291E+00, 8.738219710169965E-01, 6.308901449150177E-02, 6.30890144915016854E-02, 6.365024991213939E-01, 5.314504984483216E-02, 0.31035245103377396E+00 }; double sub_xyz_11[3*5] = { 0.33333333333333333E+00, 0.33333333333333333E+00, 0.33333333333333333E+00, 1.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.00000000000000000E+00, 0.50000000000000000E+00, 0.50000000000000000E+00, 0.50000000000000000E+00, 0.25000000000000000E+00, 0.25000000000000000E+00, 0.00000000000000000E+00, 0.90824829046386302E+00, 9.17517095361370244E-02 }; double sub_xyz_12[3*4] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 5.233837209269747E-02, 4.738308139536513E-01, 0.47383081395365129E+00, 6.557646607383649E-01, 1.721176696308175E-01, 0.17211766963081757E+00, 0.000000000000000E+00, 8.653073540834571E-01, 0.13469264591654295E+00 }; double sub_xyz_13[3*4] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 4.793080678419067E-01, 2.603459660790466E-01, 0.26034596607904670E+00, 8.697397941955675E-01, 6.513010290221623E-02, 6.51301029022163108E-02, 6.384441885698096E-01, 4.869031542531756E-02, 0.31286549600487290E+00 }; double sub_xyz_14[3*5] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 1.000000000000000E+00, 0.000000000000000E+00, 0.00000000000000000E+00, 6.901278795524791E-01, 1.549360602237604E-01, 0.15493606022376047E+00, 6.169850771237593E-02, 4.691507461438120E-01, 0.46915074614381203E+00, 0.000000000000000E+00, 8.392991722729236E-01, 0.16070082772707639E+00 }; double sub_xyz_15[3*5] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 8.141482341455413E-02, 4.592925882927229E-01, 0.45929258829272301E+00, 8.989055433659379E-01, 5.054722831703103E-02, 5.05472283170311024E-02, 6.588613844964797E-01, 1.705693077517601E-01, 0.17056930775176021E+00, 8.394777409957211E-03, 7.284923929554041E-01, 0.26311282963463867E+00 }; double sub_xyz_16[3*6] = { 1.000000000000000E+00, 0.000000000000000E+00, 0.00000000000000000E+00, 0.000000000000000E+00, 0.500000000000000E+00, 0.50000000000000000E+00, 8.637211648883667E-03, 4.956813941755582E-01, 0.49568139417555818E+00, 8.193444849714693E-01, 9.032775751426533E-02, 9.03277575142653888E-02, 5.316905005853895E-01, 2.341547497073052E-01, 0.23415474970730532E+00, 0.000000000000000E-01, 7.236067977499790E-01, 0.27639320225002095E+00 }; double sub_xyz_17[3*5] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 4.666912123569507E-02, 4.766654393821525E-01, 0.47666543938215239E+00, 9.324563118910393E-01, 3.377184405448033E-02, 3.37718440544803877E-02, 4.593042216691921E-01, 2.703478891654040E-01, 0.27034788916540398E+00, 5.146433548666149E-02, 7.458294907672514E-01, 0.20270617374608713E+00 }; double sub_xyz_18[3*6] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 2.063496160252593E-02, 4.896825191987370E-01, 0.48968251919873701E+00, 1.258208170141290E-01, 4.370895914929355E-01, 0.43708959149293541E+00, 6.235929287619356E-01, 1.882035356190322E-01, 0.18820353561903219E+00, 9.105409732110941E-01, 4.472951339445297E-02, 4.47295133944529688E-02, 3.683841205473626E-02, 7.411985987844980E-01, 0.22196298916076573E+00 }; double sub_xyz_19[3*7] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 1.000000000000000E+00, 0.000000000000000E+00, 0.00000000000000000E+00, 0.000000000000000E+00, 0.500000000000000E+00, 0.50000000000000000E+00, 1.004413236259677E-01, 4.497793381870162E-01, 0.44977933818701610E+00, 9.061051136018193E-01, 4.694744319909033E-02, 4.69474431990903329E-02, 6.162561745251021E-01, 1.918719127374489E-01, 0.19187191273744902E+00, 3.683841205473626E-02, 7.411985987844980E-01, 0.22196298916076573E+00 }; double sub_xyz_20[3*7] = { 9.352701037774565E-01, 3.236494811127173E-02, 3.23649481112718157E-02, 7.612981754348137E-01, 1.193509122825931E-01, 0.11935091228259319E+00, - 6.922209654151433E-02, 5.346110482707572E-01, 0.53461104827075701E+00, 5.933801991374367E-01, 2.033099004312816E-01, 0.20330990043128172E+00, 2.020613940682885E-01, 3.989693029658558E-01, 0.39896930296585570E+00, 5.017813831049474E-02, 5.932012134282132E-01, 0.35662064826129203E+00, 2.102201653616613E-02, 8.074890031597923E-01, 0.17148898030404158E+00 }; double sub_xyz_21[3*8] = { 3.333333333333333E-01, 3.333333333333333E-01, 0.33333333333333333E+00, 9.480217181434233E-01, 2.598914092828833E-02, 2.59891409282883845E-02, 8.114249947041546E-01, 9.428750264792270E-02, 9.42875026479226691E-02, 1.072644996557060E-02, 4.946367750172147E-01, 0.49463677501721470E+00, 5.853132347709715E-01, 2.073433826145142E-01, 0.20734338261451427E+00, 1.221843885990187E-01, 4.389078057004907E-01, 0.43890780570049059E+00, 0.000000000000000E+00, 8.588702812826364E-01, 0.14112971871736357E+00, 4.484167758913055E-02, 6.779376548825902E-01, 0.27722066752827923E+00 }; if ( rule == 0 ) { r8mat_copy ( 3, suborder_num, sub_xyz_00, sub_xyz ); r8vec_copy ( suborder_num, sub_w_00, sub_w ); } else if ( rule == 1 ) { r8mat_copy ( 3, suborder_num, sub_xyz_01, sub_xyz ); r8vec_copy ( suborder_num, sub_w_01, sub_w ); } else if ( rule == 2 ) { r8mat_copy ( 3, suborder_num, sub_xyz_02, sub_xyz ); r8vec_copy ( suborder_num, sub_w_02, sub_w ); } else if ( rule == 3 ) { r8mat_copy ( 3, suborder_num, sub_xyz_03, sub_xyz ); r8vec_copy ( suborder_num, sub_w_03, sub_w ); } else if ( rule == 4 ) { r8mat_copy ( 3, suborder_num, sub_xyz_04, sub_xyz ); r8vec_copy ( suborder_num, sub_w_04, sub_w ); } else if ( rule == 5 ) { r8mat_copy ( 3, suborder_num, sub_xyz_05, sub_xyz ); r8vec_copy ( suborder_num, sub_w_05, sub_w ); } else if ( rule == 6 ) { r8mat_copy ( 3, suborder_num, sub_xyz_06, sub_xyz ); r8vec_copy ( suborder_num, sub_w_06, sub_w ); } else if ( rule == 7 ) { r8mat_copy ( 3, suborder_num, sub_xyz_07, sub_xyz ); r8vec_copy ( suborder_num, sub_w_07, sub_w ); } else if ( rule == 8 ) { r8mat_copy ( 3, suborder_num, sub_xyz_08, sub_xyz ); r8vec_copy ( suborder_num, sub_w_08, sub_w ); } else if ( rule == 9 ) { r8mat_copy ( 3, suborder_num, sub_xyz_09, sub_xyz ); r8vec_copy ( suborder_num, sub_w_09, sub_w ); } else if ( rule == 10 ) { r8mat_copy ( 3, suborder_num, sub_xyz_10, sub_xyz ); r8vec_copy ( suborder_num, sub_w_10, sub_w ); } else if ( rule == 11 ) { r8mat_copy ( 3, suborder_num, sub_xyz_11, sub_xyz ); r8vec_copy ( suborder_num, sub_w_11, sub_w ); } else if ( rule == 12 ) { r8mat_copy ( 3, suborder_num, sub_xyz_12, sub_xyz ); r8vec_copy ( suborder_num, sub_w_12, sub_w ); } else if ( rule == 13 ) { r8mat_copy ( 3, suborder_num, sub_xyz_13, sub_xyz ); r8vec_copy ( suborder_num, sub_w_13, sub_w ); } else if ( rule == 14 ) { r8mat_copy ( 3, suborder_num, sub_xyz_14, sub_xyz ); r8vec_copy ( suborder_num, sub_w_14, sub_w ); } else if ( rule == 15 ) { r8mat_copy ( 3, suborder_num, sub_xyz_15, sub_xyz ); r8vec_copy ( suborder_num, sub_w_15, sub_w ); } else if ( rule == 16 ) { r8mat_copy ( 3, suborder_num, sub_xyz_16, sub_xyz ); r8vec_copy ( suborder_num, sub_w_16, sub_w ); } else if ( rule == 17 ) { r8mat_copy ( 3, suborder_num, sub_xyz_17, sub_xyz ); r8vec_copy ( suborder_num, sub_w_17, sub_w ); } else if ( rule == 18 ) { r8mat_copy ( 3, suborder_num, sub_xyz_18, sub_xyz ); r8vec_copy ( suborder_num, sub_w_18, sub_w ); } else if ( rule == 19 ) { r8mat_copy ( 3, suborder_num, sub_xyz_19, sub_xyz ); r8vec_copy ( suborder_num, sub_w_19, sub_w ); } else if ( rule == 20 ) { r8mat_copy ( 3, suborder_num, sub_xyz_20, sub_xyz ); r8vec_copy ( suborder_num, sub_w_20, sub_w ); } else if ( rule == 21 ) { r8mat_copy ( 3, suborder_num, sub_xyz_21, sub_xyz ); r8vec_copy ( suborder_num, sub_w_21, sub_w ); } else { cout << "\n"; cout << "LYNESS_SUBRULE - Fatal error!\n"; cout << " Illegal RULE = " << rule << "\n"; exit ( 1 ); } return; } //****************************************************************************80 double r8_abs ( double x ) //****************************************************************************80 // // Purpose: // // R8_ABS returns the absolute value of an R8. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 14 November 2006 // // Author: // // John Burkardt // // Parameters: // // Input, double X, the quantity whose absolute value is desired. // // Output, double R8_ABS, the absolute value of X. // { double value; if ( 0.0 <= x ) { value = + x; } else { value = - x; } return value; } //****************************************************************************80 void r8mat_copy ( int m, int n, double a1[], double a2[] ) //****************************************************************************80 // // Purpose: // // R8MAT_COPY copies one R8MAT to another. // // Discussion: // // An R8MAT is a doubly dimensioned array of R8 values, stored as a vector // in column-major order. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 16 October 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int M, N, the number of rows and columns. // // Input, double A1[M*N], the matrix to be copied. // // Output, double A2[M*N], the copy of A1. // { int i; int j; for ( j = 0; j < n; j++ ) { for ( i = 0; i < m; i++ ) { a2[i+j*m] = a1[i+j*m]; } } return; } //****************************************************************************80 void r8mat_write ( string output_filename, int m, int n, double table[] ) //****************************************************************************80 // // Purpose: // // R8MAT_WRITE writes an R8MAT file. // // Discussion: // // An R8MAT is an array of R8's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 29 June 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string OUTPUT_FILENAME, the output filename. // // Input, int M, the spatial dimension. // // Input, int N, the number of points. // // Input, double TABLE[M*N], the table data. // { int i; int j; ofstream output; // // Open the file. // output.open ( output_filename.c_str ( ) ); if ( !output ) { cerr << "\n"; cerr << "R8MAT_WRITE - Fatal error!\n"; cerr << " Could not open the output file.\n"; return; } // // Write the data. // for ( j = 0; j < n; j++ ) { for ( i = 0; i < m; i++ ) { output << " " << setw(24) << setprecision(16) << table[i+j*m]; } output << "\n"; } // // Close the file. // output.close ( ); return; } //****************************************************************************80 void r8vec_copy ( int n, double a1[], double a2[] ) //****************************************************************************80 // // Purpose: // // R8VEC_COPY copies an R8VEC. // // Discussion: // // An R8VEC is a vector of R8's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 03 July 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int N, the number of entries in the vectors. // // Input, double A1[N], the vector to be copied. // // Output, double A2[N], the copy of A1. // { int i; for ( i = 0; i < n; i++ ) { a2[i] = a1[i]; } return; } //****************************************************************************80 double r8vec_sum ( int n, double a[] ) //****************************************************************************80 // // Purpose: // // R8VEC_SUM returns the sum of an R8VEC. // // Discussion: // // An R8VEC is a vector of R8's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 15 October 2004 // // Author: // // John Burkardt // // Parameters: // // Input, int N, the number of entries in the vector. // // Input, double A[N], the vector. // // Output, double R8VEC_SUM, the sum of the vector. // { int i; double value; value = 0.0; for ( i = 0; i < n; i++ ) { value = value + a[i]; } return value; } //****************************************************************************80 void timestamp ( ) //****************************************************************************80 // // Purpose: // // TIMESTAMP prints the current YMDHMS date as a time stamp. // // Example: // // 31 May 2001 09:45:54 AM // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 08 July 2009 // // Author: // // John Burkardt // // Parameters: // // None // { # define TIME_SIZE 40 static char time_buffer[TIME_SIZE]; const struct std::tm *tm_ptr; std::time_t now; now = std::time ( NULL ); tm_ptr = std::localtime ( &now ); std::strftime ( time_buffer, TIME_SIZE, "%d %B %Y %I:%M:%S %p", tm_ptr ); std::cout << time_buffer << "\n"; return; # undef TIME_SIZE }