# include # include # include # include # include # include # include using namespace std; int main ( int argc, char *argv[] ); void assemble_backward_euler ( int node_num, double node_xy[], int element_order, int element_num, int element_node[], int quad_num, int ib, double time, double time_step_size, double u_old[], double a[], double f[] ); void assemble_boundary ( int node_num, double node_xy[], int node_condition[], int ib, double time, double a[], double f[] ); void assemble_heat ( int node_num, double node_xy[], int node_condition[], int element_order, int element_num, int element_node[], int quad_num, int ib, double time, double a[], double f[] ); int bandwidth ( int element_order, int element_num, int element_node[] ); void basis_11_t6 ( double t[2*3], int i, double p[2], double *qi, double *dqidx, double *dqidy ); char ch_cap ( char c ); bool ch_eqi ( char c1, char c2 ); int ch_to_digit ( char c ); int dgb_fa ( int n, int ml, int mu, double abd[], int ipvt[] ); void dgb_print_some ( int m, int n, int ml, int mu, double a[], int ilo, int jlo, int ihi, int jhi, string title ); double *dgb_sl ( int n, int ml, int mu, double a_lu[], int pivot[], double b[], int job ); double *dirichlet_condition ( int node_num, double node_xy[], double time ); int file_column_count ( string input_filename ); void file_name_inc ( string *file_name ); void file_name_specification ( int argc, char *argv[], char *node_file_name, char *element_file_name ); int file_row_count ( string input_filename ); int i4_max ( int i1, int i2 ); int i4_min ( int i1, int i2 ); int i4_modp ( int i, int j ); int i4_wrap ( int ival, int ilo, int ihi ); int i4col_compare ( int m, int n, int a[], int i, int j ); void i4col_sort_a ( int m, int n, int a[] ); void i4col_swap ( int m, int n, int a[], int icol1, int icol2 ); int *i4mat_data_read ( string input_filename, int m, int n ); void i4mat_header_read ( string input_filename, int *m, int *n ); void i4mat_transpose_print_some ( int m, int n, int a[], int ilo, int jlo, int ihi, int jhi, string title ); double *initial_condition ( int node_num, double node_xy[], double time ); void i4vec_print_some ( int n, int a[], int max_print, string title ); double k_coef ( int n, double node_xy[], double time ); void lvec_print ( int n, bool a[], string title ); void quad_rule ( int quad_num, double quad_w[], double quad_xy[] ); double r8_abs ( double x ); double r8_huge ( ); int r8_nint ( double x ); double *r8mat_data_read ( string input_filename, int m, int n ); void r8mat_header_read ( string input_filename, int *m, int *n ); void r8mat_transpose_print_some ( int m, int n, double a[], int ilo, int jlo, int ihi, int jhi, string title ); void r8mat_write ( string output_filename, int m, int n, double table[] ); void r8vec_print_some ( int n, double a[], int i_lo, int i_hi, string title ); double rhs ( int n, double node_xy[], double time ); void reference_to_physical_t3 ( double t[2*3], int n, double ref[], double phy[] ); int s_len_trim ( string s ); int s_to_i4 ( string s, int *last, bool *error ); bool s_to_i4vec ( string s, int n, int ivec[] ); double s_to_r8 ( string s, int *lchar, bool *error ); bool s_to_r8vec ( string s, int n, double rvec[] ); int s_word_count ( string s ); void sort_heap_external ( int n, int *indx, int *i, int *j, int isgn ); void timestamp ( ); double triangle_area_2d ( double t[2*3] ); bool *triangulation_order6_boundary_node ( int node_num, int triangle_num, int triangle_node[] ); //****************************************************************************80 int main ( int argc, char *argv[] ) //****************************************************************************80 // // Purpose: // // MAIN is the main program for FEM2D_HEAT. // // Discussion: // // FEM2D_HEAT solves the heat equation // // dUdT - Laplacian U(X,Y,T) + K(X,Y,T) * U(X,Y,T) = F(X,Y,T) // // in a triangulated region in the plane. // // Along the boundary of the region, Dirichlet conditions // are imposed: // // U(X,Y,T) = G(X,Y,T) // // At the initial time T_INIT, the value of U is given // at all points in the region: // // U(X,Y,T_INIT) = H(X,Y) // // The code uses continuous piecewise linear basis functions on // triangles. // // The backward Euler approximation is used for the time derivatives. // // Problem specification: // // The user defines the geometry by supplying two data files // which list the node coordinates, and list the nodes that make up // each triangular element.. // // The user specifies the coefficient function K(X,Y,T) // by supplying a routine of the form // // double k_coef ( int node_num, double node_xy[], double time ) // // The user specifies the right hand side // by supplying a routine of the form // // double rhs ( int node_num, double node_xy[], double time ) // // The user specifies the right hand side of the Dirichlet boundary // conditions by supplying a function // // double *dirichlet_condition ( int node_num, double node_xy[], // double time ) // // The user specifies the initial condition by supplying a function // // double initial_condition ( int node_num, double node_xy[], double time ) // // Usage: // // fem2d_heat prefix // // invokes the program: // // * "prefix"_nodes.txt contains the coordinates of the nodes; // * "prefix"_elements.txt contains the indices of nodes that make up each // triangular element. // // Files created include: // // * "prefix"_u0000.txt, the initial value of the solution; // * "prefix"_u0001.txt and so on, the computed solution at later times; // * "prefix"_times.txt, the value of time at each step, from the initial to // final times. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 19 May 2011 // // Author: // // John Burkardt // // Local parameters: // // Local, double A(3*IB+1,NODE_NUM), the coefficient matrix. // // Local, int DIM_NUM, the spatial dimension, which is 2. // // Local, string ELEMENT_FILE_NAME, the name of the // input file containing the element information. // // Local, int ELEMENT_NODE[ELEMENT_ORDER*ELEMENT_NUM]; // ELEMENT_NODE(I,J) is the global index of local node I in element J. // // Local, int ELEMENT_NUM, the number of elements. // // Local, int ELEMENT_ORDER, the order of each element. // // Local, double F[NODE_NUM], the right hand side. // // Local, int IB, the half-bandwidth of the matrix. // // Local, int NODE_NUM, the number of nodes. // // Local, logical NODE_BOUNDARY[NODE_NUM], is TRUE if a given // node is on the boundary. // // Local, int NODE_CONDITION[NODE_NUM], indicates the type of // boundary condition being applied to nodes on the boundary. // // Local, string NODE_FILE_NAME, the name of the // input file containing the node coordinate information. // // Local, double NODE_XY[2*NODE_NUM], the coordinates of nodes. // // Local, integer QUAD_NUM, the number of quadrature points used for // assembly. This is currently set to 3, the lowest reasonable value. // Legal values are 1, 3, 4, 6, 7, 9, 13, and for some problems, a value // of QUAD_NUM greater than 3 may be appropriate. // // Local, double U[NODE_NUM], the finite element coefficients // defining the solution at the current time. // // Local, double U_OLD[NODE_NUM], the finite element coefficients // defining the solution at the previous time. // { double *a; bool debug = false; int dim_num; string element_filename; int *element_node; int element_num; int element_order; double *f; int i; int ib; int ierr; int job; int node; bool *node_boundary; int *node_condition; string node_filename; int node_num; double *node_xy; int *pivot; string prefix; int quad_num = 7; string solution_filename; double temp; double time; string time_filename; double time_final; double time_init; double time_old; int time_step; int time_step_num; double time_step_size; ofstream time_unit; double *u; double *u_old; timestamp ( ); cout << "\n"; cout << "FEM2D_HEAT\n"; cout << " C++ version:\n"; cout << "\n"; cout << " Compiled on " << __DATE__ << " at " << __TIME__ << ".\n"; cout << "\n"; cout << " Solution of the time dependent heat equation\n"; cout << " on an arbitrary triangulated region D in 2 dimensions.\n"; cout << "\n"; cout << " Ut - Uxx - Uyy + K(x,y,t) * U = F(x,y,t) in D\n"; cout << " U = G(x,y,t) on the boundary.\n"; cout << " U = H(x,y,t) at initial time.\n"; cout << "\n"; cout << " The finite element method is used with\n"; cout << " 6 node quadratic triangular elements (\"T6\").\n"; cout << "\n"; cout << " The time derivative is approximated using the\n"; cout << " backward Euler method.\n"; // // Get the filename prefix. // if ( 1 < argc ) { prefix = argv[1]; } else { cout << "\n"; cout << " Please enter the filename prefix:\n"; cin >> prefix; } // // Create the file names. // node_filename = prefix + "_nodes.txt"; element_filename = prefix + "_elements.txt"; solution_filename = prefix + "_u0000.txt"; time_filename = prefix + "_times.txt"; cout << "\n"; cout << " Node file is \"" << node_filename << "\".\n"; cout << " Element file is \"" << element_filename << "\".\n"; // // Read the node coordinate file. // r8mat_header_read ( node_filename, &dim_num, &node_num ); cout << " Number of nodes = " << node_num << "\n"; node_condition = new int[node_num]; node_xy = r8mat_data_read ( node_filename, dim_num, node_num ); r8mat_transpose_print_some ( dim_num, node_num, node_xy, 1, 1, 2, 10, " First 10 nodes" ); // // Read the element description file. // i4mat_header_read ( element_filename, &element_order, &element_num ); cout << "\n"; cout << " Element order = " << element_order << "\n"; cout << " Number of elements = " << element_num << "\n"; if ( element_order != 6 ) { cout << "\n"; cout << "FEM2D_HEAT - Fatal error!\n"; cout << " The input triangulation has order " << element_order << "\n"; cout << " However, a triangulation of order 6 is required.\n"; exit ( 1 ); } element_node = i4mat_data_read ( element_filename, element_order, element_num ); i4mat_transpose_print_some ( element_order, element_num, element_node, 1, 1, element_order, 10, " First 10 elements" ); cout << "\n"; cout << " Quadrature order = " << quad_num << "\n"; // // Determine which nodes are boundary nodes and which have a // finite element unknown. Then set the boundary values. // node_boundary = triangulation_order6_boundary_node ( node_num, element_num, element_node ); if ( debug ) { lvec_print ( node_num, node_boundary, " Node Boundary?" ); } // // Determine the node conditions. // For now, we'll just assume all boundary nodes are Dirichlet. // for ( node = 0; node < node_num; node++ ) { if ( node_boundary[node] ) { node_condition[node] = 2; } else { node_condition[node] = 1; } } // // Determine the bandwidth of the coefficient matrix. // ib = bandwidth ( element_order, element_num, element_node ); cout << "\n"; cout << " The matrix half bandwidth is " << ib << "\n"; cout << " The matrix bandwidth is " << 2 * ib + 1 << "\n"; cout << " The storage bandwidth is " << 3 * ib + 1 << "\n"; // // Set time stepping quantities. // time_init = 0.0; time_final = 0.5; time_step_num = 10; time_step_size = ( time_final - time_init ) / ( double ) ( time_step_num ); cout << "\n"; cout << " Initial time = " << time_init << "\n"; cout << " Final time = " << time_final << "\n"; cout << " Step size = " << time_step_size << "\n"; cout << " Number of steps = " << time_step_num << "\n"; // // Allocate space for the coefficient matrix A and right hand side F. // a = new double[(3*ib+1)*node_num]; f = new double[node_num]; pivot = new int[node_num]; u_old = new double[node_num]; // // Set the value of U at the initial time. // time = time_init; u = initial_condition ( node_num, node_xy, time ); time_unit.open ( time_filename.c_str ( ) ); if ( !time_unit ) { cout << "\n"; cout << "FEM2D_HEAT - Fatal error!\n"; cout << " Could not open the output time file.\n"; exit ( 1 ); } time_unit << setw(14) << time << "\n"; r8mat_write ( solution_filename, 1, node_num, u ); // // Time looping. // for ( time_step = 1; time_step <= time_step_num; time_step++ ) { time_old = time; for ( node = 0; node < node_num; node++ ) { u_old[node] = u[node]; } time = ( ( double ) ( time_step_num - time_step ) * time_init + ( double ) ( time_step ) * time_final ) / ( double ) ( time_step_num ); // // Assemble the finite element coefficient matrix A and the right-hand side F. // assemble_heat ( node_num, node_xy, node_condition, element_order, element_num, element_node, quad_num, ib, time, a, f ); if ( debug ) { dgb_print_some ( node_num, node_num, ib, ib, a, 1, 1, 10, 10, " Initial block of Finite Element matrix A:" ); r8vec_print_some ( node_num, f, 1, 10, " Part of right hand side vector:" ); } // // Adjust the linear system for the dU/dT term, which we are treating // using the backward Euler formula. // assemble_backward_euler ( node_num, node_xy, element_order, element_num, element_node, quad_num, ib, time, time_step_size, u_old, a, f ); if ( debug ) { dgb_print_some ( node_num, node_num, ib, ib, a, 1, 1, 10, 10, " A after DT adjustment:" ); r8vec_print_some ( node_num, f, 1, 10, " F after DT adjustment:" ); } // // Adjust the linear system to account for Dirichlet boundary conditions. // assemble_boundary ( node_num, node_xy, node_condition, ib, time, a, f ); if ( debug ) { dgb_print_some ( node_num, node_num, ib, ib, a, 1, 1, 10, 10, " Finite Element matrix A after boundary condition adjustment:" ); r8vec_print_some ( node_num, f, 1, 10, " Part of right hand side vector:" ); } // // Solve the linear system using a banded solver. // ierr = dgb_fa ( node_num, ib, ib, a, pivot ); if ( ierr != 0 ) { cout << "\n"; cout << "FEM2D_HEAT - Fatal error!\n"; cout << " DGB_FA returned the error condition IERR = " << ierr << ".\n"; cout << "\n"; cout << " The linear system was not factored, and the\n"; cout << " algorithm cannot proceed.\n"; exit ( 1 ); } job = 0; delete [] u; u = dgb_sl ( node_num, ib, ib, a, pivot, f, job ); if ( debug ) { r8vec_print_some ( node_num, u, 1, 10, " Part of the solution vector:" ); } // // Increment the file name, and write the new solution. // time_unit << setw(14) << time << "\n"; file_name_inc ( &solution_filename ); r8mat_write ( solution_filename, 1, node_num, u ); } time_unit.close ( ); // // Free memory. // delete [] a; delete [] element_node; delete [] f; delete [] node_boundary; delete [] node_condition; delete [] node_xy; delete [] pivot; delete [] u; delete [] u_old; // // Terminate. // cout << "\n"; cout << "FEM2D_HEAT:\n"; cout << " Normal end of execution.\n"; cout << "\n"; timestamp ( ); return 0; } //****************************************************************************80 void assemble_backward_euler ( int node_num, double node_xy[], int element_order, int element_num, int element_node[], int quad_num, int ib, double time, double time_step_size, double u_old[], double a[], double f[] ) //****************************************************************************80 // // Purpose: // // ASSEMBLE_BACKWARD_EULER adjusts the system for the backward Euler term. // // Discussion: // // The input linear system // // A * U = F // // is appropriate for the equation // // -Uxx - Uyy - K * U = RHS // // We need to modify the matrix A and the right hand side F to // account for the approximation of the time derivative in // // Ut - Uxx - Uyy - K * U = RHS // // by the backward Euler approximation: // // Ut approximately equal to ( U - Uold ) / dT // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 22 July 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int NODE_NUM, the number of nodes. // // Input, double NODE_XY(2,NODE_NUM), the coordinates of nodes. // // Input, int ELEMENT_ORDER, the number of nodes used to form one element. // // Input, int ELEMENT_NUM, the number of elements. // // Input, int ELEMENT_NODE(ELEMENT_ORDER,ELEMENT_NUM); // ELEMENT_NODE(I,J) is the global index of local node I in element J. // // Input, int QUAD_NUM, the number of quadrature points used in assembly. // // Input, int IB, the half-bandwidth of the matrix. // // Input, double TIME, the current time. // // Input, double TIME_STEP_SIZE, the size of the time step. // // Input, double U_OLD(NODE_NUM), the finite element // coefficients for the solution at the previous time. // // Input/output, double A(3*IB+1,NODE_NUM), the NODE_NUM // by NODE_NUM coefficient matrix, stored in a compressed format. // // Input/output, double F(NODE_NUM), the right hand side. // { double area; int basis; double bi; double bj; double dbidx; double dbidy; double dbjdx; double dbjdy; int element; int i; int j; int node; double p[2]; double *phys_xy; int quad; double *quad_w; double *quad_xy; double t3[2*3]; double t6[2*6]; int test; double *w; phys_xy = new double[2*quad_num]; quad_w = new double[quad_num]; quad_xy = new double[2*quad_num]; w = new double[quad_num]; // // Get the quadrature rule weights and nodes. // quad_rule ( quad_num, quad_w, quad_xy ); for ( element = 0; element < element_num; element++ ) { // // Make two copies of the triangle. // for ( j = 0; j < 3; j++ ) { for ( i = 0; i < 2; i++ ) { t3[i+j*2] = node_xy[i+(element_node[j+element*element_order]-1)*2]; } } for ( j = 0; j < 6; j++ ) { for ( i = 0; i < 2; i++ ) { t6[i+j*2] = node_xy[i+(element_node[j+element*element_order]-1)*2]; } } // // Map the quadrature points QUAD_XY to points PHYS_XY in the physical triangle. // reference_to_physical_t3 ( t3, quad_num, quad_xy, phys_xy ); area = r8_abs ( triangle_area_2d ( t3 ) ); for ( quad = 0; quad < quad_num; quad++ ) { w[quad] = quad_w[quad] * area; } for ( quad = 0; quad < quad_num; quad++ ) { p[0] = phys_xy[0+quad*2]; p[1] = phys_xy[1+quad*2]; for ( test = 1; test <= element_order; test++ ) { node = element_node[test-1+element*element_order]; basis_11_t6 ( t6, test, p, &bi, &dbidx, &dbidy ); // // Carry the U_OLD term to the right hand side. // f[node-1] = f[node-1] + w[quad] * bi * u_old[node-1] / time_step_size; // // Modify the diagonal entries of A. // for ( basis = 1; basis <= element_order; basis++ ) { j = element_node[basis-1+element*element_order]; basis_11_t6 ( t6, basis, p, &bj, &dbjdx, &dbjdy ); a[node-j+2*ib+(j-1)*(3*ib+1)] = a[node-j+2*ib+(j-1)*(3*ib+1)] + w[quad] * bi * bj / time_step_size; } } } } delete [] phys_xy; delete [] quad_w; delete [] quad_xy; delete [] w; return; } //****************************************************************************80 void assemble_boundary ( int node_num, double node_xy[], int node_condition[], int ib, double time, double a[], double f[] ) //****************************************************************************80 // // Purpose: // // ASSEMBLE_BOUNDARY modifies the linear system for the boundary conditions. // // Discussion: // // For now, we are only working with Dirichlet boundary conditions. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 08 January 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int NODE_NUM, the number of nodes. // // Input, double NODE_XY[2*NODE_NUM], the coordinates of nodes. // // Input, int NODE_CONDITION[NODE_NUM], reports the condition // used to set the unknown associated with the node. // 0, unknown. // 1, finite element equation. // 2, Dirichlet condition; // 3, Neumann condition. // // Input, int IB, the half-bandwidth of the matrix. // // Input, double TIME, the current time. // // Input/output, double A[(3*IB+1)*NODE_NUM], the NODE_NUM by // NODE_NUM coefficient matrix, stored in a compressed format; on output, // the matrix has been adjusted for Dirichlet boundary conditions. // // Input/output, double F[NODE_NUM], the right hand side. // On output, the right hand side has been adjusted for Dirichlet // boundary conditions. // { double *bc_value; int column; int column_high; int column_low; int DIRICHLET = 2; int node; bc_value = dirichlet_condition ( node_num, node_xy, time ); for ( node = 1; node <= node_num; node++ ) { if ( node_condition[node-1] == DIRICHLET ) { column_low = i4_max ( node - ib, 1 ); column_high = i4_min ( node + ib, node_num ); for ( column = column_low; column <= column_high; column++ ) { a[node-column+2*ib+(column-1)*(3*ib+1)] = 0.0; } a[2*ib+(node-1)*(3*ib+1)] = 1.0; f[node-1] = bc_value[node-1]; } } delete [] bc_value; return; } //****************************************************************************80 void assemble_heat ( int node_num, double node_xy[], int node_condition[], int element_order, int element_num, int element_node[], int quad_num, int ib, double time, double a[], double f[] ) //****************************************************************************80 // // Purpose: // // ASSEMBLE_HEAT assembles the finite element system for the heat equation. // // Discussion: // // The matrix is known to be banded. A special matrix storage format // is used to reduce the space required. Details of this format are // discussed in the routine DGB_FA. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 22 July 2007 // // Author: // // John Burkardt // // Parameters: // // Input, int NODE_NUM, the number of nodes. // // Input, double NODE_XY[2*NODE_NUM], the coordinates of nodes. // // Input, int NODE_CONDITION(NODE_NUM), reports the condition // used to set the unknown associated with the node. // 0, unknown. // 1, finite element equation. // 2, Dirichlet condition; // 3, Neumann condition. // // Input, int ELEMENT_NUM, the number of element. // // Input, int ELEMENT_NODE[ELEMENT_ORDER*ELEMENT_NUM]; // ELEMENT_NODE(I,J) is the global index of local node I in element J. // // Input, int QUAD_NUM, the number of quadrature points used in assembly. // // Input, int IB, the half-bandwidth of the matrix. // // Input, double TIME, the current time. // // Output, double A(3*IB+1,NODE_NUM), the NODE_NUM by NODE_NUM // coefficient matrix, stored in a compressed format. // // Output, double F(NODE_NUM), the right hand side. // // Local parameters: // // Local, double BI, DBIDX, DBIDY, the value of some basis function // and its first derivatives at a quadrature point. // // Local, double BJ, DBJDX, DBJDY, the value of another basis // function and its first derivatives at a quadrature point. // { double area; int basis; double bi; double bj; double dbidx; double dbidy; double dbjdx; double dbjdy; int element; int i; int j; int node; double k_value; double *phys_xy; int quad; double *quad_w; double *quad_xy; double rhs_value; double t3[2*3]; double t6[2*6]; int test; double *w; phys_xy = new double[2*quad_num]; quad_w = new double[quad_num]; quad_xy = new double[2*quad_num]; w = new double[quad_num]; // // Initialize the arrays to zero. // for ( node = 0; node < node_num; node++ ) { f[node] = 0.0; } for ( node = 0; node < node_num; node++ ) { for ( i = 0; i < 3*ib+1; i++ ) { a[i+node*(3*ib+1)] = 0.0; } } // // Get the quadrature weights and nodes. // quad_rule ( quad_num, quad_w, quad_xy ); // // Add up all quantities associated with the ELEMENT-th element. // for ( element = 0; element < element_num; element++ ) { // // Make two copies of the triangle. // for ( j = 0; j < 3; j++ ) { for ( i = 0; i < 2; i++ ) { t3[i+j*2] = node_xy[i+(element_node[j+element*element_order]-1)*2]; } } for ( j = 0; j < 6; j++ ) { for ( i = 0; i < 2; i++ ) { t6[i+j*2] = node_xy[i+(element_node[j+element*element_order]-1)*2]; } } // // Map the quadrature points QUAD_XY to points PHYS_XY in the physical triangle. // reference_to_physical_t3 ( t3, quad_num, quad_xy, phys_xy ); area = r8_abs ( triangle_area_2d ( t3 ) ); for ( quad = 0; quad < quad_num; quad++ ) { w[quad] = quad_w[quad] * area; } // // Consider the QUAD-th quadrature point. // for ( quad = 0; quad < quad_num; quad++ ) { k_value = k_coef ( 1, phys_xy+quad*2, time ); rhs_value = rhs ( 1, phys_xy+quad*2, time ); // // Consider the TEST-th test function. // // We generate an integral for every node associated with an unknown. // But if a node is associated with a boundary condition, we do nothing. // for ( test = 1; test <= element_order; test++ ) { i = element_node[test-1+element*element_order]; basis_11_t6 ( t6, test, phys_xy+quad*2, &bi, &dbidx, &dbidy ); f[i-1] = f[i-1] + w[quad] * rhs_value * bi; // // Consider the BASIS-th basis function, which is used to form the // value of the solution function. // for ( basis = 1; basis <= element_order; basis++ ) { j = element_node[basis-1+element*element_order]; basis_11_t6 ( t6, basis, phys_xy+quad*2, &bj, &dbjdx, &dbjdy ); a[i-j+2*ib+(j-1)*(3*ib+1)] = a[i-j+2*ib+(j-1)*(3*ib+1)] + w[quad] * ( dbidx * dbjdx + dbidy * dbjdy + k_value * bj * bi ); } } } } delete [] phys_xy; delete [] quad_w; delete [] quad_xy; delete [] w; return; } //****************************************************************************80 int bandwidth ( int element_order, int element_num, int element_node[] ) //****************************************************************************80 // // Purpose: // // BANDWIDTH determines the bandwidth of the coefficient matrix. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 02 September 2006 // // Author: // // John Burkardt // // Parameters: // // Input, int ELEMENT_ORDER, the order of the elements. // // Input, int ELEMENT_NUM, the number of elements. // // Input, int ELEMENT_NODE[ELEMENT_ORDER*ELEMENT_NUM]; // ELEMENT_NODE(I,J) is the global index of local node I in element J. // // Output, int BANDWIDTH, the half bandwidth of the matrix. // { int element; int global_i; int global_j; int local_i; int local_j; int nhba; nhba = 0; for ( element = 1; element <= element_num; element++ ) { for ( local_i = 1; local_i <= element_order; local_i++ ) { global_i = element_node[local_i-1+(element-1)*element_order]; for ( local_j = 1; local_j <= element_order; local_j++ ) { global_j = element_node[local_j-1+(element-1)*element_order]; nhba = i4_max ( nhba, abs ( global_j - global_i ) ); } } } return nhba; } //****************************************************************************80 void basis_11_t6 ( double t[2*6], int i, double p[], double *bi, double *dbidx, double *dbidy ) //****************************************************************************80 // // Purpose: // // BASIS_11_T6: one basis at one point for the T6 element. // // Discussion: // // The routine is given the coordinates of the nodes of a triangle. // // 3 // / \ // 6 5 // / \ // 1---4---2 // // It evaluates the quadratic basis function B(I)(X,Y) associated with // node I, which has the property that it is a quadratic function // which is 1 at node I and zero at the other five nodes. // // This routine assumes that the sides of the triangle are straight, // so that the midside nodes fall on the line between two vertices. // // This routine relies on the fact that each basis function can be // written as the product of two linear factors, which are easily // computed and normalized. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 02 February 2006 // // Author: // // John Burkardt // // Parameters: // // Input, double T[2*6], the coordinates of the nodes. // // Input, int I, the index of the desired basis function. // I should be between 1 and 6. // // Input, double P[2], the coordinates of a point at which the basis // function is to be evaluated. // // Output, double *BI, *DBIDX, *DBIDY, the values of the basis function // and its X and Y derivatives. // { double gf; double gn; double hf; double hn; int j1; int j2; int k1; int k2; if ( i < 1 || 6 < i ) { cout << "\n"; cout << "BASIS_11_T6 - Fatal error!\n"; cout << " Basis index I is not between 1 and 6.\n"; cout << " I = " << i << "\n"; exit ( 1 ); } // // Determine the pairs of nodes. // if ( i <= 3 ) { j1 = i4_wrap ( i + 1, 1, 3 ); j2 = i4_wrap ( i + 2, 1, 3 ); k1 = i + 3; k2 = i4_wrap ( i + 5, 4, 6 ); } else { j1 = i - 3; j2 = i4_wrap ( i - 3 + 2, 1, 3 ); k1 = i4_wrap ( i - 3 + 1, 1, 3 ); k2 = i4_wrap ( i - 3 + 2, 1, 3 ); } // // For C++ indexing, it is helpful to knock the indices down by one. // i = i - 1; j1 = j1 - 1; j2 = j2 - 1; k1 = k1 - 1; k2 = k2 - 1; // // Evaluate the two linear factors GF and HF, // and their normalizers GN and HN. // gf = ( p[0] - t[0+j1*2] ) * ( t[1+j2*2] - t[1+j1*2] ) - ( t[0+j2*2] - t[0+j1*2] ) * ( p[1] - t[1+j1*2] ); gn = ( t[0+i*2] - t[0+j1*2] ) * ( t[1+j2*2] - t[1+j1*2] ) - ( t[0+j2*2] - t[0+j1*2] ) * ( t[1+i*2] - t[1+j1*2] ); hf = ( p[0] - t[0+k1*2] ) * ( t[1+k2*2] - t[1+k1*2] ) - ( t[0+k2*2] - t[0+k1*2] ) * ( p[1] - t[1+k1*2] ); hn = ( t[0+i*2] - t[0+k1*2] ) * ( t[1+k2*2] - t[1+k1*2] ) - ( t[0+k2*2] - t[0+k1*2] ) * ( t[1+i*2] - t[1+k1*2] ); // // Construct the basis function and its derivatives. // *bi = ( gf / gn ) * ( hf / hn ); *dbidx = ( ( t[1+j2*2] - t[1+j1*2] ) / gn ) * ( hf / hn ) + ( gf / gn ) * ( ( t[1+k2*2] - t[1+k1*2] ) / hn ); *dbidy = - ( ( t[0+j2*2] - t[0+j1*2] ) / gn ) * ( hf / hn ) - ( gf / gn ) * ( ( t[0+k2*2] - t[0+k1*2] ) / hn ); return; } //****************************************************************************80 char ch_cap ( char c ) //****************************************************************************80 // // Purpose: // // CH_CAP capitalizes a single character. // // Discussion: // // This routine should be equivalent to the library "toupper" function. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 19 July 1998 // // Author: // // John Burkardt // // Parameters: // // Input, char C, the character to capitalize. // // Output, char CH_CAP, the capitalized character. // { if ( 97 <= c && c <= 122 ) { c = c - 32; } return c; } //****************************************************************************80* bool ch_eqi ( char c1, char c2 ) //****************************************************************************80* // // Purpose: // // CH_EQI is true if two characters are equal, disregarding case. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 13 June 2003 // // Author: // // John Burkardt // // Parameters: // // Input, char C1, char C2, the characters to compare. // // Output, bool CH_EQI, is true if the two characters are equal, // disregarding case. // { if ( 97 <= c1 && c1 <= 122 ) { c1 = c1 - 32; } if ( 97 <= c2 && c2 <= 122 ) { c2 = c2 - 32; } return ( c1 == c2 ); } //****************************************************************************80 int ch_to_digit ( char c ) //****************************************************************************80 // // Purpose: // // CH_TO_DIGIT returns the integer value of a base 10 digit. // // Example: // // C DIGIT // --- ----- // '0' 0 // '1' 1 // ... ... // '9' 9 // ' ' 0 // 'X' -1 // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 13 June 2003 // // Author: // // John Burkardt // // Parameters: // // Input, char C, the decimal digit, '0' through '9' or blank are legal. // // Output, int CH_TO_DIGIT, the corresponding integer value. If C was // 'illegal', then DIGIT is -1. // { int digit; if ( '0' <= c && c <= '9' ) { digit = c - '0'; } else if ( c == ' ' ) { digit = 0; } else { digit = -1; } return digit; } //****************************************************************************80 int dgb_fa ( int n, int ml, int mu, double a[], int pivot[] ) //****************************************************************************80 // // Purpose: // // DGB_FA performs a LINPACK-style PLU factorization of a DGB matrix. // // Discussion: // // The DGB storage format is used for an M by N banded matrix, with lower bandwidth ML // and upper bandwidth MU. Storage includes room for ML extra superdiagonals, // which may be required to store nonzero entries generated during Gaussian // elimination. // // The original M by N matrix is "collapsed" downward, so that diagonals // become rows of the storage array, while columns are preserved. The // collapsed array is logically 2*ML+MU+1 by N. // // The two dimensional array can be further reduced to a one dimensional // array, stored by columns. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 16 September 2003 // // Author: // // FORTRAN77 original version by Dongarra, Bunch, Moler, Stewart. // C++ version by John Burkardt. // // Parameters: // // Input, int N, the order of the matrix. // N must be positive. // // Input, int ML, MU, the lower and upper bandwidths. // ML and MU must be nonnegative, and no greater than N-1. // // Input/output, double A[(2*ML+MU+1)*N], the matrix in band storage. // On output, A has been overwritten by the LU factors. // // Output, int PIVOT[N], the pivot vector. // // Output, int DGB_FA, singularity flag. // 0, no singularity detected. // nonzero, the factorization failed on the INFO-th step. // { int col = 2 * ml + mu + 1; int i; int i0; int j; int j0; int j1; int ju; int jz; int k; int l; int lm; int m; int mm; double t; m = ml + mu + 1; // // Zero out the initial fill-in columns. // j0 = mu + 2; j1 = i4_min ( n, m ) - 1; for ( jz = j0; jz <= j1; jz++ ) { i0 = m + 1 - jz; for ( i = i0; i <= ml; i++ ) { a[i-1+(jz-1)*col] = 0.0; } } jz = j1; ju = 0; for ( k = 1; k <= n-1; k++ ) { // // Zero out the next fill-in column. // jz = jz + 1; if ( jz <= n ) { for ( i = 1; i <= ml; i++ ) { a[i-1+(jz-1)*col] = 0.0; } } // // Find L = pivot index. // lm = i4_min ( ml, n-k ); l = m; for ( j = m+1; j <= m + lm; j++ ) { if ( fabs ( a[l-1+(k-1)*col] ) < fabs ( a[j-1+(k-1)*col] ) ) { l = j; } } pivot[k-1] = l + k - m; // // Zero pivot implies this column already triangularized. // if ( a[l-1+(k-1)*col] == 0.0 ) { cout << "\n"; cout << "DGB_FA - Fatal error!\n"; cout << " Zero pivot on step " << k << "\n"; return k; } // // Interchange if necessary. // t = a[l-1+(k-1)*col]; a[l-1+(k-1)*col] = a[m-1+(k-1)*col]; a[m-1+(k-1)*col] = t; // // Compute multipliers. // for ( i = m+1; i <= m+lm; i++ ) { a[i-1+(k-1)*col] = - a[i-1+(k-1)*col] / a[m-1+(k-1)*col]; } // // Row elimination with column indexing. // ju = i4_max ( ju, mu + pivot[k-1] ); ju = i4_min ( ju, n ); mm = m; for ( j = k+1; j <= ju; j++ ) { l = l - 1; mm = mm - 1; if ( l != mm ) { t = a[l-1+(j-1)*col]; a[l-1+(j-1)*col] = a[mm-1+(j-1)*col]; a[mm-1+(j-1)*col] = t; } for ( i = 1; i <= lm; i++ ) { a[mm+i-1+(j-1)*col] = a[mm+i-1+(j-1)*col] + a[mm-1+(j-1)*col] * a[m+i-1+(k-1)*col]; } } } pivot[n-1] = n; if ( a[m-1+(n-1)*col] == 0.0 ) { cout << "\n"; cout << "DGB_FA - Fatal error!\n"; cout << " Zero pivot on step " << n << "\n"; return n; } return 0; } //****************************************************************************80 void dgb_print_some ( int m, int n, int ml, int mu, double a[], int ilo, int jlo, int ihi, int jhi, string title ) //****************************************************************************80 // // Purpose: // // DGB_PRINT_SOME prints some of a DGB matrix. // // Discussion: // // The DGB storage format is used for an M by N banded matrix, with lower bandwidth ML // and upper bandwidth MU. Storage includes room for ML extra superdiagonals, // which may be required to store nonzero entries generated during Gaussian // elimination. // // The original M by N matrix is "collapsed" downward, so that diagonals // become rows of the storage array, while columns are preserved. The // collapsed array is logically 2*ML+MU+1 by N. // // The two dimensional array can be further reduced to a one dimensional // array, stored by columns. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 06 April 2006 // // Author: // // John Burkardt // // Parameters: // // Input, int M, the number of rows of the matrix. // M must be positive. // // Input, int N, the number of columns of the matrix. // N must be positive. // // Input, int ML, MU, the lower and upper bandwidths. // ML and MU must be nonnegative, and no greater than min(M,N)-1.. // // Input, double A[(2*ML+MU+1)*N], the DGB matrix. // // Input, int ILO, JLO, IHI, JHI, designate the first row and // column, and the last row and column to be printed. // // Input, string TITLE, a title to print. // { # define INCX 5 int col = 2 * ml + mu + 1; int i; int i2hi; int i2lo; int j; int j2hi; int j2lo; cout << "\n"; cout << title << "\n"; // // Print the columns of the matrix, in strips of 5. // for ( j2lo = jlo; j2lo <= jhi; j2lo = j2lo + INCX ) { j2hi = j2lo + INCX - 1; j2hi = i4_min ( j2hi, n ); j2hi = i4_min ( j2hi, jhi ); cout << "\n"; cout << " Col: "; for ( j = j2lo; j <= j2hi; j++ ) { cout << setw(7) << j << " "; } cout << "\n"; cout << " Row\n"; cout << " ---\n"; // // Determine the range of the rows in this strip. // i2lo = i4_max ( ilo, 1 ); i2lo = i4_max ( i2lo, j2lo - mu - ml ); i2hi = i4_min ( ihi, m ); i2hi = i4_min ( i2hi, j2hi + ml ); for ( i = i2lo; i <= i2hi; i++ ) { // // Print out (up to) 5 entries in row I, that lie in the current strip. // cout << setw(6) << i << " "; for ( j = j2lo; j <= j2hi; j++ ) { if ( i < j - mu - ml || j + ml < i ) { cout << " "; } else { cout << setw(10) << a[i-j+ml+mu+(j-1)*col] << " "; } } cout << "\n"; } } cout << "\n"; return; # undef INCX } //****************************************************************************80 double *dgb_sl ( int n, int ml, int mu, double a_lu[], int pivot[], double b[], int job ) //****************************************************************************80 // // Purpose: // // DGB_SL solves a system factored by DGB_FA. // // Discussion: // // The DGB storage format is used for an M by N banded matrix, with lower bandwidth ML // and upper bandwidth MU. Storage includes room for ML extra superdiagonals, // which may be required to store nonzero entries generated during Gaussian // elimination. // // The original M by N matrix is "collapsed" downward, so that diagonals // become rows of the storage array, while columns are preserved. The // collapsed array is logically 2*ML+MU+1 by N. // // The two dimensional array can be further reduced to a one dimensional // array, stored by columns. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 16 September 2003 // // Author: // // FORTRAN77 original version by Dongarra, Bunch, Moler, Stewart. // C++ version by John Burkardt. // // Parameters: // // Input, int N, the order of the matrix. // N must be positive. // // Input, int ML, MU, the lower and upper bandwidths. // ML and MU must be nonnegative, and no greater than N-1. // // Input, double A_LU[(2*ML+MU+1)*N], the LU factors from DGB_FA. // // Input, int PIVOT[N], the pivot vector from DGB_FA. // // Input, double B[N], the right hand side vector. // // Input, int JOB. // 0, solve A * x = b. // nonzero, solve A' * x = b. // // Output, double DGB_SL[N], the solution. // { int col = 2 * ml + mu + 1; int i; int k; int l; int la; int lb; int lm; int m; double t; double *x; x = new double[n]; for ( i = 0; i < n; i++ ) { x[i] = b[i]; } // m = mu + ml + 1; // // Solve A * x = b. // if ( job == 0 ) { // // Solve L * Y = B. // if ( 1 <= ml ) { for ( k = 1; k <= n-1; k++ ) { lm = i4_min ( ml, n-k ); l = pivot[k-1]; if ( l != k ) { t = x[l-1]; x[l-1] = x[k-1]; x[k-1] = t; } for ( i = 1; i <= lm; i++ ) { x[k+i-1] = x[k+i-1] + x[k-1] * a_lu[m+i-1+(k-1)*col]; } } } // // Solve U * X = Y. // for ( k = n; 1 <= k; k-- ) { x[k-1] = x[k-1] / a_lu[m-1+(k-1)*col]; lm = i4_min ( k, m ) - 1; la = m - lm; lb = k - lm; for ( i = 0; i <= lm-1; i++ ) { x[lb+i-1] = x[lb+i-1] - x[k-1] * a_lu[la+i-1+(k-1)*col]; } } } // // Solve A' * X = B. // else { // // Solve U' * Y = B. // for ( k = 1; k <= n; k++ ) { lm = i4_min ( k, m ) - 1; la = m - lm; lb = k - lm; for ( i = 0; i <= lm-1; i++ ) { x[k-1] = x[k-1] - x[lb+i-1] * a_lu[la+i-1+(k-1)*col]; } x[k-1] = x[k-1] / a_lu[m-1+(k-1)*col]; } // // Solve L' * X = Y. // if ( 1 <= ml ) { for ( k = n-1; 1 <= k; k-- ) { lm = i4_min ( ml, n-k ); for ( i = 1; i <= lm; i++ ) { x[k-1] = x[k-1] + x[k+i-1] * a_lu[m+i-1+(k-1)*col]; } l = pivot[k-1]; if ( l != k ) { t = x[l-1]; x[l-1] = x[k-1]; x[k-1] = t; } } } } return x; } //****************************************************************************80 int file_column_count ( string filename ) //****************************************************************************80 // // Purpose: // // FILE_COLUMN_COUNT counts the columns in the first line of a file. // // Discussion: // // The file is assumed to be a simple text file. // // Most lines of the file are presumed to consist of COLUMN_NUM words, // separated by spaces. There may also be some blank lines, and some // comment lines, which have a "#" in column 1. // // The routine tries to find the first non-comment non-blank line and // counts the number of words in that line. // // If all lines are blanks or comments, it goes back and tries to analyze // a comment line. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 July 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string FILENAME, the name of the file. // // Output, int FILE_COLUMN_COUNT, the number of columns assumed // to be in the file. // { int column_num; ifstream input; bool got_one; string text; // // Open the file. // input.open ( filename.c_str ( ) ); if ( !input ) { column_num = -1; cerr << "\n"; cerr << "FILE_COLUMN_COUNT - Fatal error!\n"; cerr << " Could not open the file:\n"; cerr << " \"" << filename << "\"\n"; return column_num; } // // Read one line, but skip blank lines and comment lines. // got_one = false; for ( ; ; ) { getline ( input, text ); if ( input.eof ( ) ) { break; } if ( s_len_trim ( text ) <= 0 ) { continue; } if ( text[0] == '#' ) { continue; } got_one = true; break; } if ( !got_one ) { input.close ( ); input.open ( filename.c_str ( ) ); for ( ; ; ) { input >> text; if ( input.eof ( ) ) { break; } if ( s_len_trim ( text ) == 0 ) { continue; } got_one = true; break; } } input.close ( ); if ( !got_one ) { cerr << "\n"; cerr << "FILE_COLUMN_COUNT - Warning!\n"; cerr << " The file does not seem to contain any data.\n"; return -1; } column_num = s_word_count ( text ); return column_num; } //****************************************************************************80 void file_name_inc ( string *filename ) //****************************************************************************80 // // Purpose: // // FILE_NAME_INC increments a partially numeric file name. // // Discussion: // // It is assumed that the digits in the name, whether scattered or // connected, represent a number that is to be increased by 1 on // each call. If this number is all 9's on input, the output number // is all 0's. Non-numeric letters of the name are unaffected. // // If the input string contains no digits or is empty, // an error condition results. // // Example: // // Input Output // ----- ------ // "a7to11.txt" "a7to12.txt" (typical case. Last digit incremented) // "a7to99.txt" "a8to00.txt" (last digit incremented, with carry.) // "a9to99.txt" "a0to00.txt" (wrap around) // "cat.txt" " " (no digits to increment) // " " STOP! (error) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 02 February 2009 // // Author: // // John Burkardt // // Parameters: // // Input/output, string *FILENAME, the filename to be incremented. // { char c; int change; int i; int lens; lens = (*filename).length ( ); if ( lens <= 0 ) { cerr << "\n"; cerr << "FILE_NAME_INC - Fatal error!\n"; cerr << " Input file name is empty string.\n"; exit ( 1 ); } change = 0; for ( i = lens-1; 0 <= i; i-- ) { c = (*filename)[i]; if ( '0' <= c && c <= '9' ) { change = change + 1; if ( c == '9' ) { c = '0'; (*filename)[i] = c; } else { c = c + 1; (*filename)[i] = c; return; } } } if ( change == 0 ) { cerr << "\n"; cerr << "FILE_NAME_INC - Fatal error!\n"; cerr << " Filename contained no digits.\n"; exit ( 1 ); } return; } //****************************************************************************80 void file_name_specification ( int argc, char *argv[], char *node_file_name, char *element_file_name ) //****************************************************************************80 // // Purpose: // // FILE_NAME_SPECIFICATION determines the names of the input files. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 06 January 2006 // // Author: // // John Burkardt // // Parameters: // // Output, char *NODE_FILE_NAME, the name of the node file. // // Output, char *ELEMENT_FILE_NAME, the name of the element file. // { // // Get the number of command line arguments. // if ( 1 <= argc ) { strcpy ( node_file_name, argv[1] ); } else { cout << "\n"; cout << "FILE_NAME_SPECIFICATION:\n"; cout << " Please enter the name of the node file.\n"; cin.getline ( node_file_name, sizeof ( node_file_name ) ); } // // If at least two command line arguments, the second is the element file. // if ( 2 <= argc ) { strcpy ( element_file_name, argv[2] ); } else { cout << "\n"; cout << "FILE_NAME_SPECIFICATION:\n"; cout << " Please enter the name of the element file.\n"; cin.getline ( element_file_name, sizeof ( element_file_name ) ); } return; } //****************************************************************************80 int file_row_count ( string filename ) //****************************************************************************80 // // Purpose: // // FILE_ROW_COUNT counts the number of row records in a file. // // Discussion: // // It does not count lines that are blank, or that begin with a // comment symbol '#'. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 30 January 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string FILENAME, the name of the input file. // // Output, int FILE_ROW_COUNT, the number of rows found. // { int bad_num; int comment_num; ifstream input; int record_num; int row_num; string text; row_num = 0; comment_num = 0; record_num = 0; bad_num = 0; input.open ( filename.c_str ( ) ); if ( !input ) { cerr << "\n"; cerr << "FILE_ROW_COUNT - Fatal error!\n"; cerr << " Could not open the file: \"" << filename << "\"\n"; exit ( 1 ); } for ( ; ; ) { getline ( input, text ); if ( input.eof ( ) ) { break; } record_num = record_num + 1; if ( text[0] == '#' ) { comment_num = comment_num + 1; continue; } if ( s_len_trim ( text ) == 0 ) { comment_num = comment_num + 1; continue; } row_num = row_num + 1; } input.close ( ); return row_num; } //****************************************************************************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. // // { if ( i2 < i1 ) { return i1; } else { return i2; } } //****************************************************************************80 int i4_min ( int i1, int i2 ) //****************************************************************************80 // // Purpose: // // I4_MIN returns the smaller 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. // // { if ( i1 < i2 ) { return i1; } else { return i2; } } //****************************************************************************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. // // Example: // // I J MOD I_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 ) { cout << "\n"; cout << "I4_MODP - Fatal error!\n"; cout << " 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 integer to lie between given limits by wrapping. // // Example: // // ILO = 4, IHI = 8 // // I I4_WRAP // // -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 i4col_compare ( int m, int n, int a[], int i, int j ) //****************************************************************************80 // // Purpose: // // I4COL_COMPARE compares columns I and J of an I4COL. // // Example: // // Input: // // M = 3, N = 4, I = 2, J = 4 // // A = ( // 1 2 3 4 // 5 6 7 8 // 9 10 11 12 ) // // Output: // // I4COL_COMPARE = -1 // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 12 June 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int M, N, the number of rows and columns. // // Input, int A[M*N], an array of N columns of vectors of length M. // // Input, int I, J, the columns to be compared. // I and J must be between 1 and N. // // Output, int I4COL_COMPARE, the results of the comparison: // -1, column I < column J, // 0, column I = column J, // +1, column J < column I. // { int k; // // Check. // if ( i < 1 ) { cout << "\n"; cout << "I4COL_COMPARE - Fatal error!\n"; cout << " Column index I = " << i << " is less than 1.\n"; exit ( 1 ); } if ( n < i ) { cout << "\n"; cout << "I4COL_COMPARE - Fatal error!\n"; cout << " N = " << n << " is less than column index I = " << i << ".\n"; exit ( 1 ); } if ( j < 1 ) { cout << "\n"; cout << "I4COL_COMPARE - Fatal error!\n"; cout << " Column index J = " << j << " is less than 1.\n"; exit ( 1 ); } if ( n < j ) { cout << "\n"; cout << "I4COL_COMPARE - Fatal error!\n"; cout << " N = " << n << " is less than column index J = " << j << ".\n"; exit ( 1 ); } if ( i == j ) { return 0; } k = 1; while ( k <= m ) { if ( a[k-1+(i-1)*m] < a[k-1+(j-1)*m] ) { return (-1); } else if ( a[k-1+(j-1)*m] < a[k-1+(i-1)*m] ) { return 1; } k = k + 1; } return 0; } //****************************************************************************80 void i4col_sort_a ( int m, int n, int a[] ) //****************************************************************************80 // // Purpose: // // I4COL_SORT_A ascending sorts the columns of an I4COL. // // Discussion: // // In lexicographic order, the statement "X < Y", applied to two // vectors X and Y of length M, means that there is some index I, with // 1 <= I <= M, with the property that // // X(J) = Y(J) for J < I, // and // X(I) < Y(I). // // In other words, X is less than Y if, at the first index where they // differ, the X value is less than the Y value. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 12 June 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int M, the number of rows of A. // // Input, int N, the number of columns of A. // // Input/output, int A[M*N]. // On input, the array of N columns of M vectors; // On output, the columns of A have been sorted in ascending // lexicographic order. // { int i; int indx; int isgn; int j; // // Initialize. // i = 0; indx = 0; isgn = 0; j = 0; // // Call the external heap sorter. // for ( ; ; ) { sort_heap_external ( n, &indx, &i, &j, isgn ); // // Interchange the I and J objects. // if ( 0 < indx ) { i4col_swap ( m, n, a, i, j ); } // // Compare the I and J objects. // else if ( indx < 0 ) { isgn = i4col_compare ( m, n, a, i, j ); } else if ( indx == 0 ) { break; } } return; } //****************************************************************************80 void i4col_swap ( int m, int n, int a[], int icol1, int icol2 ) //****************************************************************************80 // // Purpose: // // I4COL_SWAP swaps two columns of an integer array. // // Discussion: // // The two dimensional information is stored as a one dimensional // array, by columns. // // The row indices are 1 based, NOT 0 based! However, a preprocessor // variable, called OFFSET, can be reset from 1 to 0 if you wish to // use 0-based indices. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 03 April 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int M, N, the number of rows and columns. // // Input/output, int A[M*N], an array of data. // // Input, int ICOL1, ICOL2, the two columns to swap. // These indices should be between 1 and N. // { # define OFFSET 1 int i; int t; // // Check. // if ( icol1 - OFFSET < 0 || n-1 < icol1 - OFFSET ) { cout << "\n"; cout << "I4COL_SWAP - Fatal error!\n"; cout << " ICOL1 is out of range.\n"; exit ( 1 ); } if ( icol2 - OFFSET < 0 || n-1 < icol2 - OFFSET ) { cout << "\n"; cout << "I4COL_SWAP - Fatal error!\n"; cout << " ICOL2 is out of range.\n"; exit ( 1 ); } if ( icol1 == icol2 ) { return; } for ( i = 0; i < m; i++ ) { t = a[i+(icol1-OFFSET)*m]; a[i+(icol1-OFFSET)*m] = a[i+(icol2-OFFSET)*m]; a[i+(icol2-OFFSET)*m] = t; } return; # undef OFFSET } //****************************************************************************80 int *i4mat_data_read ( string input_filename, int m, int n ) //****************************************************************************80 // // Purpose: // // I4MAT_DATA_READ reads data from an I4MAT file. // // Discussion: // // An I4MAT is an array of I4's. // // The file is assumed to contain one record per line. // // Records beginning with '#' are comments, and are ignored. // Blank lines are also ignored. // // Each line that is not ignored is assumed to contain exactly (or at least) // M real numbers, representing the coordinates of a point. // // There are assumed to be exactly (or at least) N such records. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 23 February 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string INPUT_FILENAME, the name of the input file. // // Input, int M, the number of spatial dimensions. // // Input, int N, the number of points. The program // will stop reading data once N values have been read. // // Output, int I4MAT_DATA_READ[M*N], the data. // { bool error; ifstream input; int i; int j; string line; int *table; int *x; input.open ( input_filename.c_str ( ) ); if ( !input ) { cerr << "\n"; cerr << "I4MAT_DATA_READ - Fatal error!\n"; cerr << " Could not open the input file: \"" << input_filename << "\"\n"; exit ( 1 ); } table = new int[m*n]; x = new int[m]; j = 0; while ( j < n ) { getline ( input, line ); if ( input.eof ( ) ) { break; } if ( line[0] == '#' || s_len_trim ( line ) == 0 ) { continue; } error = s_to_i4vec ( line, m, x ); if ( error ) { continue; } for ( i = 0; i < m; i++ ) { table[i+j*m] = x[i]; } j = j + 1; } input.close ( ); delete [] x; return table; } //****************************************************************************80 void i4mat_header_read ( string input_filename, int *m, int *n ) //****************************************************************************80 // // Purpose: // // I4MAT_HEADER_READ reads the header from an I4MAT file. // // Discussion: // // An I4MAT is an array of I4's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 23 February 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string INPUT_FILENAME, the name of the input file. // // Output, int *M, the number of spatial dimensions. // // Output, int *N, the number of points // { *m = file_column_count ( input_filename ); if ( *m <= 0 ) { cerr << "\n"; cerr << "I4MAT_HEADER_READ - Fatal error!\n"; cerr << " FILE_COLUMN_COUNT failed.\n"; exit ( 1 ); } *n = file_row_count ( input_filename ); if ( *n <= 0 ) { cerr << "\n"; cerr << "I4MAT_HEADER_READ - Fatal error!\n"; cerr << " FILE_ROW_COUNT failed.\n"; exit ( 1 ); } return; } //****************************************************************************80 void i4mat_transpose_print_some ( int m, int n, int a[], int ilo, int jlo, int ihi, int jhi, string title ) //****************************************************************************80 // // Purpose: // // I4MAT_TRANSPOSE_PRINT_SOME prints some of an I4MAT, transposed. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 14 June 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int M, the number of rows of the matrix. // M must be positive. // // Input, int N, the number of columns of the matrix. // N must be positive. // // Input, int A[M*N], the matrix. // // Input, int ILO, JLO, IHI, JHI, designate the first row and // column, and the last row and column to be printed. // // Input, string TITLE, a title for the matrix. { # define INCX 10 int i; int i2hi; int i2lo; int j; int j2hi; int j2lo; cout << "\n"; cout << title << "\n"; // // Print the columns of the matrix, in strips of INCX. // for ( i2lo = ilo; i2lo <= ihi; i2lo = i2lo + INCX ) { i2hi = i2lo + INCX - 1; i2hi = i4_min ( i2hi, m ); i2hi = i4_min ( i2hi, ihi ); cout << "\n"; // // For each row I in the current range... // // Write the header. // cout << " Row: "; for ( i = i2lo; i <= i2hi; i++ ) { cout << setw(6) << i << " "; } cout << "\n"; cout << " Col\n"; cout << "\n"; // // Determine the range of the rows in this strip. // j2lo = i4_max ( jlo, 1 ); j2hi = i4_min ( jhi, n ); for ( j = j2lo; j <= j2hi; j++ ) { // // Print out (up to INCX) entries in column J, that lie in the current strip. // cout << setw(5) << j << " "; for ( i = i2lo; i <= i2hi; i++ ) { cout << setw(6) << a[i-1+(j-1)*m] << " "; } cout << "\n"; } } cout << "\n"; return; # undef INCX } //****************************************************************************80 void i4vec_print_some ( int n, int a[], int i_lo, int i_hi, string title ) //****************************************************************************80 // // Purpose: // // I4VEC_PRINT_SOME prints "some" of an I4VEC. // // Discussion: // // An I4VEC is a vector of I4 values. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 10 September 2009 // // Author: // // John Burkardt // // Parameters: // // Input, int N, the number of entries of the vector. // // Input, int A[N], the vector to be printed. // // Input, int I_LO, I_HI, the first and last indices to print. // The routine expects 1 <= I_LO <= I_HI <= N. // // Input, string TITLE, a title. // { int i; cout << "\n"; cout << title << "\n"; cout << "\n"; for ( i = i4_max ( 1, i_lo ); i <= i4_min ( n, i_hi ); i++ ) { cout << " " << setw(8) << i << ": " << setw(12) << a[i-1] << "\n"; } return; } //****************************************************************************80 void lvec_print ( int n, bool a[], string title ) //****************************************************************************80 // // Purpose: // // LVEC_PRINT prints a logical vector. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 03 April 2005 // // Author: // // John Burkardt // // Parameters: // // Input, int N, the number of components of the vector. // // Input, bool A[N], the vector to be printed. // // Input, string TITLE, a title to be printed first. // TITLE may be blank. // { int i; cout << "\n"; cout << title << "\n"; cout << "\n"; for ( i = 0; i <= n-1; i++ ) { cout << setw(6) << i + 1 << " " << setw(1) << a[i] << "\n"; } return; } //****************************************************************************80 void quad_rule ( int quad_num, double quad_w[], double quad_xy[] ) //****************************************************************************80 // // Purpose: // // QUAD_RULE sets the quadrature rule for assembly. // // Discussion: // // The quadrature rule is given for a reference element. // // 0 <= X, // 0 <= Y, and // X + Y <= 1. // // ^ // 1 | * // | |. // Y | | . // | | . // 0 | *---* // +-------> // 0 X 1 // // The rules have the following precision: // // QUAD_NUM Precision // // 1 1 // 3 2 // 4 3 // 6 4 // 7 5 // 9 6 // 13 7 // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 06 January 2006 // // Author: // // John Burkardt // // Parameters: // // Input, int QUAD_NUM, the number of quadrature nodes. // // Output, double QUAD_W[QUAD_NUM], the quadrature weights. // // Output, double QUAD_XY[2*QUAD_NUM], // the coordinates of the quadrature nodes. // { double a; double b; double c; double d; double e; double f; double g; double h; double t; double u; double v; double w; if ( quad_num == 1 ) { quad_xy[0+0*2] = 1.0 / 3.0; quad_xy[1+0*2] = 1.0 / 3.0; quad_w[0] = 1.0; } else if ( quad_num == 3 ) { quad_xy[0+0*2] = 0.5; quad_xy[1+0*2] = 0.0; quad_xy[0+1*2] = 0.5; quad_xy[1+1*2] = 0.5; quad_xy[0+2*2] = 0.0; quad_xy[1+2*2] = 0.5; quad_w[0] = 1.0 / 3.0; quad_w[1] = 1.0 / 3.0; quad_w[2] = 1.0 / 3.0; } else if ( quad_num == 4 ) { a = 6.0 / 30.0; b = 10.0 / 30.0; c = 18.0 / 30.0; d = 25.0 / 48.0; e = -27.0 / 48.0; quad_xy[0+0*2] = b; quad_xy[1+0*2] = b; quad_xy[0+1*2] = c; quad_xy[1+1*2] = a; quad_xy[0+2*2] = a; quad_xy[1+2*2] = c; quad_xy[0+3*2] = a; quad_xy[1+3*2] = a; quad_w[0] = e; quad_w[1] = d; quad_w[2] = d; quad_w[3] = d; } else if ( quad_num == 6 ) { a = 0.816847572980459; b = 0.091576213509771; c = 0.108103018168070; d = 0.445948490915965; v = 0.109951743655322; w = 0.223381589678011; quad_xy[0+0*2] = a; quad_xy[1+0*2] = b; quad_xy[0+1*2] = b; quad_xy[1+1*2] = a; quad_xy[0+2*2] = b; quad_xy[1+2*2] = b; quad_xy[0+3*2] = c; quad_xy[1+3*2] = d; quad_xy[0+4*2] = d; quad_xy[1+4*2] = c; quad_xy[0+5*2] = d; quad_xy[1+5*2] = d; quad_w[0] = v; quad_w[1] = v; quad_w[2] = v; quad_w[3] = w; quad_w[4] = w; quad_w[5] = w; } else if ( quad_num == 7 ) { a = 1.0 / 3.0; b = ( 9.0 + 2.0 * sqrt ( 15.0 ) ) / 21.0; c = ( 6.0 - sqrt ( 15.0 ) ) / 21.0; d = ( 9.0 - 2.0 * sqrt ( 15.0 ) ) / 21.0; e = ( 6.0 + sqrt ( 15.0 ) ) / 21.0; u = 0.225; v = ( 155.0 - sqrt ( 15.0 ) ) / 1200.0; w = ( 155.0 + sqrt ( 15.0 ) ) / 1200.0; quad_xy[0+0*2] = a; quad_xy[1+0*2] = a; quad_xy[0+1*2] = b; quad_xy[1+1*2] = c; quad_xy[0+2*2] = c; quad_xy[1+2*2] = b; quad_xy[0+3*2] = c; quad_xy[1+3*2] = c; quad_xy[0+4*2] = d; quad_xy[1+4*2] = e; quad_xy[0+5*2] = e; quad_xy[1+5*2] = d; quad_xy[0+6*2] = e; quad_xy[1+6*2] = e; quad_w[0] = u; quad_w[1] = v; quad_w[2] = v; quad_w[3] = v; quad_w[4] = w; quad_w[5] = w; quad_w[6] = w; } else if ( quad_num == 9 ) { a = 0.124949503233232; b = 0.437525248383384; c = 0.797112651860071; d = 0.165409927389841; e = 0.037477420750088; u = 0.205950504760887; v = 0.063691414286223; quad_xy[0+0*2] = a; quad_xy[1+0*2] = b; quad_xy[0+1*2] = b; quad_xy[1+1*2] = a; quad_xy[0+2*2] = b; quad_xy[1+2*2] = b; quad_xy[0+3*2] = c; quad_xy[1+3*2] = d; quad_xy[0+4*2] = c; quad_xy[1+4*2] = e; quad_xy[0+5*2] = d; quad_xy[1+5*2] = c; quad_xy[0+6*2] = d; quad_xy[1+6*2] = e; quad_xy[0+7*2] = e; quad_xy[1+7*2] = c; quad_xy[0+8*2] = e; quad_xy[1+8*2] = d; quad_w[0] = u; quad_w[1] = u; quad_w[2] = u; quad_w[3] = v; quad_w[4] = v; quad_w[5] = v; quad_w[6] = v; quad_w[7] = v; quad_w[8] = v; } else if ( quad_num == 13 ) { h = 1.0 / 3.0; a = 0.479308067841923; b = 0.260345966079038; c = 0.869739794195568; d = 0.065130102902216; e = 0.638444188569809; f = 0.312865496004875; g = 0.048690315425316; w = -0.149570044467670; t = 0.175615257433204; u = 0.053347235608839; v = 0.077113760890257; quad_xy[0+ 0*2] = h; quad_xy[1+ 0*2] = h; quad_xy[0+ 1*2] = a; quad_xy[1+ 1*2] = b; quad_xy[0+ 2*2] = b; quad_xy[1+ 2*2] = a; quad_xy[0+ 3*2] = b; quad_xy[1+ 3*2] = b; quad_xy[0+ 4*2] = c; quad_xy[1+ 4*2] = d; quad_xy[0+ 5*2] = d; quad_xy[1+ 5*2] = c; quad_xy[0+ 6*2] = d; quad_xy[1+ 6*2] = d; quad_xy[0+ 7*2] = e; quad_xy[1+ 7*2] = f; quad_xy[0+ 8*2] = e; quad_xy[1+ 8*2] = g; quad_xy[0+ 9*2] = f; quad_xy[1+ 9*2] = e; quad_xy[0+10*2] = f; quad_xy[1+10*2] = g; quad_xy[0+11*2] = g; quad_xy[1+11*2] = e; quad_xy[0+12*2] = g; quad_xy[1+12*2] = f; quad_w[ 0] = w; quad_w[ 1] = t; quad_w[ 2] = t; quad_w[ 3] = t; quad_w[ 4] = u; quad_w[ 5] = u; quad_w[ 6] = u; quad_w[ 7] = v; quad_w[ 8] = v; quad_w[ 9] = v; quad_w[10] = v; quad_w[11] = v; quad_w[12] = v; } else { cout << "\n"; cout << "QUAD_RULE - Fatal error!\n"; cout << " No rule is available of order QUAD_NUM = " << quad_num << "\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: // // 02 April 2005 // // Author: // // John Burkardt // // Parameters: // // Input, double X, the quantity whose absolute value is desired. // // Output, double R8_ABS, the absolute value of X. // { if ( 0.0 <= x ) { return x; } else { return ( -x ); } } //****************************************************************************80 double r8_huge ( ) //****************************************************************************80 // // Purpose: // // R8_HUGE returns a "huge" R8. // // Discussion: // // HUGE_VAL is the largest representable legal double precision number, and is usually // defined in math.h, or sometimes in stdlib.h. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 31 August 2004 // // Author: // // John Burkardt // // Parameters: // // Output, double R8_HUGE, a "huge" R8. // { return HUGE_VAL; } //****************************************************************************80 int r8_nint ( double x ) //****************************************************************************80 // // Purpose: // // R8_NINT returns the nearest integer to an R8. // // Example: // // X R8_NINT // // 1.3 1 // 1.4 1 // 1.5 1 or 2 // 1.6 2 // 0.0 0 // -0.7 -1 // -1.1 -1 // -1.6 -2 // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 26 August 2004 // // Author: // // John Burkardt // // Parameters: // // Input, double X, the value. // // Output, int R8_NINT, the nearest integer to X. // { int s; int value; if ( x < 0.0 ) { s = -1; } else { s = 1; } value = s * ( int ) ( fabs ( x ) + 0.5 ); return value; } //****************************************************************************80 void r8mat_transpose_print_some ( int m, int n, double a[], int ilo, int jlo, int ihi, int jhi, string title ) //****************************************************************************80 // // Purpose: // // R8MAT_TRANSPOSE_PRINT_SOME prints some of an R8MAT, transposed. // // 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: // // 20 August 2010 // // Author: // // John Burkardt // // Parameters: // // Input, int M, N, the number of rows and columns. // // Input, double A[M*N], an M by N matrix to be printed. // // Input, int ILO, JLO, the first row and column to print. // // Input, int IHI, JHI, the last row and column to print. // // Input, string TITLE, a title. // { # define INCX 5 int i; int i2; int i2hi; int i2lo; int inc; int j; int j2hi; int j2lo; cout << "\n"; cout << title << "\n"; if ( m <= 0 || n <= 0 ) { cout << "\n"; cout << " (None)\n"; return; } for ( i2lo = i4_max ( ilo, 1 ); i2lo <= i4_min ( ihi, m ); i2lo = i2lo + INCX ) { i2hi = i2lo + INCX - 1; i2hi = i4_min ( i2hi, m ); i2hi = i4_min ( i2hi, ihi ); inc = i2hi + 1 - i2lo; cout << "\n"; cout << " Row: "; for ( i = i2lo; i <= i2hi; i++ ) { cout << setw(7) << i - 1 << " "; } cout << "\n"; cout << " Col\n"; cout << "\n"; j2lo = i4_max ( jlo, 1 ); j2hi = i4_min ( jhi, n ); for ( j = j2lo; j <= j2hi; j++ ) { cout << setw(5) << j - 1 << ":"; for ( i2 = 1; i2 <= inc; i2++ ) { i = i2lo - 1 + i2; cout << setw(14) << a[(i-1)+(j-1)*m]; } cout << "\n"; } } return; # undef INCX } //****************************************************************************80 double *r8mat_data_read ( string input_filename, int m, int n ) //****************************************************************************80 // // Purpose: // // R8MAT_DATA_READ reads the data from an R8MAT file. // // Discussion: // // An R8MAT is an array of R8's. // // The file is assumed to contain one record per line. // // Records beginning with '#' are comments, and are ignored. // Blank lines are also ignored. // // Each line that is not ignored is assumed to contain exactly (or at least) // M real numbers, representing the coordinates of a point. // // There are assumed to be exactly (or at least) N such records. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 23 February 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string INPUT_FILENAME, the name of the input file. // // Input, int M, the number of spatial dimensions. // // Input, int N, the number of points. The program // will stop reading data once N values have been read. // // Output, double R8MAT_DATA_READ[M*N], the data. // { bool error; ifstream input; int i; int j; string line; double *table; double *x; input.open ( input_filename.c_str ( ) ); if ( !input ) { cerr << "\n"; cerr << "R8MAT_DATA_READ - Fatal error!\n"; cerr << " Could not open the input file: \"" << input_filename << "\"\n"; exit ( 1 ); } table = new double[m*n]; x = new double[m]; j = 0; while ( j < n ) { getline ( input, line ); if ( input.eof ( ) ) { break; } if ( line[0] == '#' || s_len_trim ( line ) == 0 ) { continue; } error = s_to_r8vec ( line, m, x ); if ( error ) { continue; } for ( i = 0; i < m; i++ ) { table[i+j*m] = x[i]; } j = j + 1; } input.close ( ); delete [] x; return table; } //****************************************************************************80 void r8mat_header_read ( string input_filename, int *m, int *n ) //****************************************************************************80 // // Purpose: // // R8MAT_HEADER_READ reads the header from an R8MAT file. // // Discussion: // // An R8MAT is an array of R8's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 23 February 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string INPUT_FILENAME, the name of the input file. // // Output, int *M, the number of spatial dimensions. // // Output, int *N, the number of points. // { *m = file_column_count ( input_filename ); if ( *m <= 0 ) { cerr << "\n"; cerr << "R8MAT_HEADER_READ - Fatal error!\n"; cerr << " FILE_COLUMN_COUNT failed.\n"; exit ( 1 ); } *n = file_row_count ( input_filename ); if ( *n <= 0 ) { cerr << "\n"; cerr << "R8MAT_HEADER_READ - Fatal error!\n"; cerr << " FILE_ROW_COUNT failed.\n"; exit ( 1 ); } 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 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"; exit ( 1 ); } // // 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_print_some ( int n, double a[], int i_lo, int i_hi, string title ) //****************************************************************************80 // // Purpose: // // R8VEC_PRINT_SOME prints "some" of an R8VEC. // // Discussion: // // An R8VEC is a vector of R8's. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 16 October 2006 // // Author: // // John Burkardt // // Parameters: // // Input, int N, the number of entries of the vector. // // Input, double A[N], the vector to be printed. // // Input, integer I_LO, I_HI, the first and last indices to print. // The routine expects 1 <= I_LO <= I_HI <= N. // // Input, string TITLE, a title. // { int i; cout << "\n"; cout << title << "\n"; cout << "\n"; for ( i = i4_max ( 1, i_lo ); i <= i4_min ( n, i_hi ); i++ ) { cout << " " << setw(8) << i << ": " << setw(14) << a[i-1] << "\n"; } return; } //****************************************************************************80 void reference_to_physical_t3 ( double t[2*3], int n, double ref[], double phy[] ) //****************************************************************************80 // // Purpose: // // REFERENCE_TO_PHYSICAL_T3 maps reference points to physical points. // // Discussion: // // Given the vertices of an order 3 physical triangle and a point // (XSI,ETA) in the reference triangle, the routine computes the value // of the corresponding image point (X,Y) in physical space. // // Note that this routine may also be appropriate for an order 6 // triangle, if the mapping between reference and physical space // is linear. This implies, in particular, that the sides of the // image triangle are straight and that the "midside" nodes in the // physical triangle are literally halfway along the sides of // the physical triangle. // // Reference Element T3: // // | // 1 3 // | |. // | | . // S | . // | | . // | | . // 0 1-----2 // | // +--0--R--1--> // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 24 June 2005 // // Author: // // John Burkardt // // Parameters: // // Input, double T[2*3], the coordinates of the vertices. // The vertices are assumed to be the images of (0,0), (1,0) and // (0,1) respectively. // // Input, int N, the number of objects to transform. // // Input, double REF[2*N], points in the reference triangle. // // Output, double PHY[2*N], corresponding points in the // physical triangle. // { int i; int j; for ( i = 0; i < 2; i++ ) { for ( j = 0; j < n; j++ ) { phy[i+j*2] = t[i+0*2] * ( 1.0 - ref[0+j*2] - ref[1+j*2] ) + t[i+1*2] * + ref[0+j*2] + t[i+2*2] * + ref[1+j*2]; } } return; } //****************************************************************************80 int s_len_trim ( string s ) //****************************************************************************80 // // Purpose: // // S_LEN_TRIM returns the length of a string to the last nonblank. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 July 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string S, a string. // // Output, int S_LEN_TRIM, the length of the string to the last nonblank. // If S_LEN_TRIM is 0, then the string is entirely blank. // { int n; n = s.length ( ); while ( 0 < n ) { if ( s[n-1] != ' ' ) { return n; } n = n - 1; } return n; } //****************************************************************************80 int s_to_i4 ( string s, int *last, bool *error ) //****************************************************************************80 // // Purpose: // // S_TO_I4 reads an I4 from a string. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 July 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string S, a string to be examined. // // Output, int *LAST, the last character of S used to make IVAL. // // Output, bool *ERROR is TRUE if an error occurred. // // Output, int *S_TO_I4, the integer value read from the string. // If the string is blank, then IVAL will be returned 0. // { char c; int i; int isgn; int istate; int ival; *error = false; istate = 0; isgn = 1; i = 0; ival = 0; for ( ; ; ) { c = s[i]; i = i + 1; // // Haven't read anything. // if ( istate == 0 ) { if ( c == ' ' ) { } else if ( c == '-' ) { istate = 1; isgn = -1; } else if ( c == '+' ) { istate = 1; isgn = + 1; } else if ( '0' <= c && c <= '9' ) { istate = 2; ival = c - '0'; } else { *error = true; return ival; } } // // Have read the sign, expecting digits. // else if ( istate == 1 ) { if ( c == ' ' ) { } else if ( '0' <= c && c <= '9' ) { istate = 2; ival = c - '0'; } else { *error = true; return ival; } } // // Have read at least one digit, expecting more. // else if ( istate == 2 ) { if ( '0' <= c && c <= '9' ) { ival = 10 * (ival) + c - '0'; } else { ival = isgn * ival; *last = i - 1; return ival; } } } // // If we read all the characters in the string, see if we're OK. // if ( istate == 2 ) { ival = isgn * ival; *last = s_len_trim ( s ); } else { *error = true; *last = 0; } return ival; } //****************************************************************************80 bool s_to_i4vec ( string s, int n, int ivec[] ) //****************************************************************************80 // // Purpose: // // S_TO_I4VEC reads an I4VEC from a string. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 July 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string S, the string to be read. // // Input, int N, the number of values expected. // // Output, int IVEC[N], the values read from the string. // // Output, bool S_TO_I4VEC, is TRUE if an error occurred. // { int begin; bool error; int i; int lchar; int length; begin = 0; length = s.length ( ); error = 0; for ( i = 0; i < n; i++ ) { ivec[i] = s_to_i4 ( s.substr(begin,length), &lchar, &error ); if ( error ) { return error; } begin = begin + lchar; length = length - lchar; } return error; } //****************************************************************************80 double s_to_r8 ( string s, int *lchar, bool *error ) //****************************************************************************80 // // Purpose: // // S_TO_R8 reads an R8 from a string. // // Discussion: // // This routine will read as many characters as possible until it reaches // the end of the string, or encounters a character which cannot be // part of the real number. // // Legal input is: // // 1 blanks, // 2 '+' or '-' sign, // 2.5 spaces // 3 integer part, // 4 decimal point, // 5 fraction part, // 6 'E' or 'e' or 'D' or 'd', exponent marker, // 7 exponent sign, // 8 exponent integer part, // 9 exponent decimal point, // 10 exponent fraction part, // 11 blanks, // 12 final comma or semicolon. // // with most quantities optional. // // Example: // // S R // // '1' 1.0 // ' 1 ' 1.0 // '1A' 1.0 // '12,34,56' 12.0 // ' 34 7' 34.0 // '-1E2ABCD' -100.0 // '-1X2ABCD' -1.0 // ' 2E-1' 0.2 // '23.45' 23.45 // '-4.2E+2' -420.0 // '17d2' 1700.0 // '-14e-2' -0.14 // 'e2' 100.0 // '-12.73e-9.23' -12.73 * 10.0**(-9.23) // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 02 May 2011 // // Author: // // John Burkardt // // Parameters: // // Input, string S, the string containing the // data to be read. Reading will begin at position 1 and // terminate at the end of the string, or when no more // characters can be read to form a legal real. Blanks, // commas, or other nonnumeric data will, in particular, // cause the conversion to halt. // // Output, int *LCHAR, the number of characters read from // the string to form the number, including any terminating // characters such as a trailing comma or blanks. // // Output, bool *ERROR, is true if an error occurred. // // Output, double S_TO_R8, the real value that was read from the string. // { char c; int ihave; int isgn; int iterm; int jbot; int jsgn; int jtop; int nchar; int ndig; double r; double rbot; double rexp; double rtop; char TAB = 9; static double ten = 10.0; nchar = s_len_trim ( s ); *error = false; r = 0.0; *lchar = -1; isgn = 1; rtop = 0.0; rbot = 1.0; jsgn = 1; jtop = 0; jbot = 1; ihave = 1; iterm = 0; for ( ; ; ) { c = s[*lchar+1]; *lchar = *lchar + 1; // // Blank or TAB character. // if ( c == ' ' || c == TAB ) { if ( ihave == 2 ) { } else if ( ihave == 6 || ihave == 7 ) { iterm = 1; } else if ( 1 < ihave ) { ihave = 11; } } // // Comma. // else if ( c == ',' || c == ';' ) { if ( ihave != 1 ) { iterm = 1; ihave = 12; *lchar = *lchar + 1; } } // // Minus sign. // else if ( c == '-' ) { if ( ihave == 1 ) { ihave = 2; isgn = -1; } else if ( ihave == 6 ) { ihave = 7; jsgn = -1; } else { iterm = 1; } } // // Plus sign. // else if ( c == '+' ) { if ( ihave == 1 ) { ihave = 2; } else if ( ihave == 6 ) { ihave = 7; } else { iterm = 1; } } // // Decimal point. // else if ( c == '.' ) { if ( ihave < 4 ) { ihave = 4; } else if ( 6 <= ihave && ihave <= 8 ) { ihave = 9; } else { iterm = 1; } } // // Exponent marker. // else if ( ch_eqi ( c, 'E' ) || ch_eqi ( c, 'D' ) ) { if ( ihave < 6 ) { ihave = 6; } else { iterm = 1; } } // // Digit. // else if ( ihave < 11 && '0' <= c && c <= '9' ) { if ( ihave <= 2 ) { ihave = 3; } else if ( ihave == 4 ) { ihave = 5; } else if ( ihave == 6 || ihave == 7 ) { ihave = 8; } else if ( ihave == 9 ) { ihave = 10; } ndig = ch_to_digit ( c ); if ( ihave == 3 ) { rtop = 10.0 * rtop + ( double ) ndig; } else if ( ihave == 5 ) { rtop = 10.0 * rtop + ( double ) ndig; rbot = 10.0 * rbot; } else if ( ihave == 8 ) { jtop = 10 * jtop + ndig; } else if ( ihave == 10 ) { jtop = 10 * jtop + ndig; jbot = 10 * jbot; } } // // Anything else is regarded as a terminator. // else { iterm = 1; } // // If we haven't seen a terminator, and we haven't examined the // entire string, go get the next character. // if ( iterm == 1 || nchar <= *lchar + 1 ) { break; } } // // If we haven't seen a terminator, and we have examined the // entire string, then we're done, and LCHAR is equal to NCHAR. // if ( iterm != 1 && (*lchar) + 1 == nchar ) { *lchar = nchar; } // // Number seems to have terminated. Have we got a legal number? // Not if we terminated in states 1, 2, 6 or 7! // if ( ihave == 1 || ihave == 2 || ihave == 6 || ihave == 7 ) { *error = true; return r; } // // Number seems OK. Form it. // if ( jtop == 0 ) { rexp = 1.0; } else { if ( jbot == 1 ) { rexp = pow ( ten, jsgn * jtop ); } else { rexp = jsgn * jtop; rexp = rexp / jbot; rexp = pow ( ten, rexp ); } } r = isgn * rexp * rtop / rbot; return r; } //****************************************************************************80 bool s_to_r8vec ( string s, int n, double rvec[] ) //****************************************************************************80 // // Purpose: // // S_TO_R8VEC reads an R8VEC from a string. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 July 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string S, the string to be read. // // Input, int N, the number of values expected. // // Output, double RVEC[N], the values read from the string. // // Output, bool S_TO_R8VEC, is true if an error occurred. // { int begin; bool error; int i; int lchar; int length; begin = 0; length = s.length ( ); error = 0; for ( i = 0; i < n; i++ ) { rvec[i] = s_to_r8 ( s.substr(begin,length), &lchar, &error ); if ( error ) { return error; } begin = begin + lchar; length = length - lchar; } return error; } //****************************************************************************80 int s_word_count ( string s ) //****************************************************************************80 // // Purpose: // // S_WORD_COUNT counts the number of "words" in a string. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 July 2009 // // Author: // // John Burkardt // // Parameters: // // Input, string S, the string to be examined. // // Output, int S_WORD_COUNT, the number of "words" in the string. // Words are presumed to be separated by one or more blanks. // { bool blank; int char_count; int i; int word_count; word_count = 0; blank = true; char_count = s.length ( ); for ( i = 0; i < char_count; i++ ) { if ( isspace ( s[i] ) ) { blank = true; } else if ( blank ) { word_count = word_count + 1; blank = false; } } return word_count; } //****************************************************************************80 void sort_heap_external ( int n, int *indx, int *i, int *j, int isgn ) //****************************************************************************80 // // Purpose: // // SORT_HEAP_EXTERNAL externally sorts a list of items into ascending order. // // Discussion: // // The actual list is not passed to the routine. Hence it may // consist of integers, reals, numbers, names, etc. The user, // after each return from the routine, will be asked to compare or // interchange two items. // // The current version of this code mimics the FORTRAN version, // so the values of I and J, in particular, are FORTRAN indices. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 05 February 2004 // // Author: // // FORTRAN77 original by Nijenhuis and Wilf. // C++ version by John Burkardt. // // Reference: // // Albert Nijenhuis and Herbert Wilf, // Combinatorial Algorithms, // Academic Press, 1978, second edition, // ISBN 0-12-519260-6. // // Parameters: // // Input, int N, the length of the input list. // // Input/output, int *INDX. // The user must set INDX to 0 before the first call. // On return, // if INDX is greater than 0, the user must interchange // items I and J and recall the routine. // If INDX is less than 0, the user is to compare items I // and J and return in ISGN a negative value if I is to // precede J, and a positive value otherwise. // If INDX is 0, the sorting is done. // // Output, int *I, *J. On return with INDX positive, // elements I and J of the user's list should be // interchanged. On return with INDX negative, elements I // and J are to be compared by the user. // // Input, int ISGN. On return with INDX negative, the // user should compare elements I and J of the list. If // item I is to precede item J, set ISGN negative, // otherwise set ISGN positive. // { static int i_save = 0; static int j_save = 0; static int k = 0; static int k1 = 0; static int n1 = 0; // // INDX = 0: This is the first call. // if ( *indx == 0 ) { i_save = 0; j_save = 0; k = n / 2; k1 = k; n1 = n; } // // INDX < 0: The user is returning the results of a comparison. // else if ( *indx < 0 ) { if ( *indx == -2 ) { if ( isgn < 0 ) { i_save = i_save + 1; } j_save = k1; k1 = i_save; *indx = -1; *i = i_save; *j = j_save; return; } if ( 0 < isgn ) { *indx = 2; *i = i_save; *j = j_save; return; } if ( k <= 1 ) { if ( n1 == 1 ) { i_save = 0; j_save = 0; *indx = 0; } else { i_save = n1; j_save = 1; n1 = n1 - 1; *indx = 1; } *i = i_save; *j = j_save; return; } k = k - 1; k1 = k; } // // 0 < INDX: the user was asked to make an interchange. // else if ( *indx == 1 ) { k1 = k; } for ( ; ; ) { i_save = 2 * k1; if ( i_save == n1 ) { j_save = k1; k1 = i_save; *indx = -1; *i = i_save; *j = j_save; return; } else if ( i_save <= n1 ) { j_save = i_save + 1; *indx = -2; *i = i_save; *j = j_save; return; } if ( k <= 1 ) { break; } k = k - 1; k1 = k; } if ( n1 == 1 ) { i_save = 0; j_save = 0; *indx = 0; *i = i_save; *j = j_save; } else { i_save = n1; j_save = 1; n1 = n1 - 1; *indx = 1; *i = i_save; *j = j_save; } return; } //****************************************************************************80 void timestamp ( ) //****************************************************************************80 // // Purpose: // // TIMESTAMP prints the current YMDHMS date as a time stamp. // // Example: // // May 31 2001 09:45:54 AM // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 02 October 2003 // // Author: // // John Burkardt // // Parameters: // // None // { # define TIME_SIZE 40 static char time_buffer[TIME_SIZE]; const struct tm *tm; size_t len; time_t now; now = time ( NULL ); tm = localtime ( &now ); len = strftime ( time_buffer, TIME_SIZE, "%d %B %Y %I:%M:%S %p", tm ); cout << time_buffer << "\n"; return; # undef TIME_SIZE } //****************************************************************************80 double triangle_area_2d ( double t[2*3] ) //****************************************************************************80 // // Purpose: // // TRIANGLE_AREA_2D computes the area of a triangle in 2D. // // Discussion: // // If the triangle's vertices are given in counterclockwise order, // the area will be positive. If the triangle's vertices are given // in clockwise order, the area will be negative! // // An earlier version of this routine always returned the absolute // value of the computed area. I am convinced now that that is // a less useful result! For instance, by returning the signed // area of a triangle, it is possible to easily compute the area // of a nonconvex polygon as the sum of the (possibly negative) // areas of triangles formed by node 1 and successive pairs of vertices. // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 17 October 2005 // // Author: // // John Burkardt // // Parameters: // // Input, double T[2*3], the vertices of the triangle. // // Output, double TRIANGLE_AREA_2D, the area of the triangle. // { double area; area = 0.5 * ( t[0+0*2] * ( t[1+1*2] - t[1+2*2] ) + t[0+1*2] * ( t[1+2*2] - t[1+0*2] ) + t[0+2*2] * ( t[1+0*2] - t[1+1*2] ) ); return area; } //****************************************************************************80 bool *triangulation_order6_boundary_node ( int node_num, int triangle_num, int triangle_node[] ) //****************************************************************************80 // // Purpose: // // TRIANGULATION_ORDER6_BOUNDARY_NODE indicates nodes on the boundary. // // Discussion: // // This routine is given an order 6 triangulation, an abstract list of // sets of six nodes. The vertices are listed clockwise, then the // midside nodes. // // It is assumed that each edge of the triangulation is either // * an INTERIOR edge, which is listed twice, once with positive // orientation and once with negative orientation, or; // * a BOUNDARY edge, which will occur only once. // // This routine should work even if the region has holes - as long // as the boundary of the hole comprises more than 3 edges! // // Licensing: // // This code is distributed under the GNU LGPL license. // // Modified: // // 25 January 2013 // // Author: // // John Burkardt // // Parameters: // // Input, int NODE_NUM, the number of nodes. // // Input, int TRIANGLE_NUM, the number of triangles. // // Input, int TRIANGLE_NODE[6*TRIANGLE_NUM], the nodes that make up the // triangles. // // Output, bool TRIANGULATION_ORDER6_BOUNDARY_NODE[NODE_NUM], // is TRUE if the node is on a boundary edge. // { int e1; int e2; int *edge; bool equal; int i; int j; int m; int n; bool *node_boundary; m = 3; n = 3 * triangle_num; // // Set up the edge array. // edge = new int[m*n]; for ( j = 0; j < triangle_num; j++ ) { edge[0+(j )*m] = triangle_node[0+j*6]; edge[1+(j )*m] = triangle_node[3+j*6]; edge[2+(j )*m] = triangle_node[1+j*6]; edge[0+(j+ triangle_num)*m] = triangle_node[1+j*6]; edge[1+(j+ triangle_num)*m] = triangle_node[4+j*6]; edge[2+(j+ triangle_num)*m] = triangle_node[2+j*6]; edge[0+(j+2*triangle_num)*m] = triangle_node[2+j*6]; edge[1+(j+2*triangle_num)*m] = triangle_node[5+j*6]; edge[2+(j+2*triangle_num)*m] = triangle_node[0+j*6]; } // // In each column, force the smaller entry to appear first. // for ( j = 0; j < n; j++ ) { e1 = i4_min ( edge[0+j*m], edge[2+j*m] ); e2 = i4_max ( edge[0+j*m], edge[2+j*m] ); edge[0+j*m] = e1; edge[2+j*m] = e2; } // // Ascending sort the column array. // i4col_sort_a ( m, n, edge ); // // Records which appear twice are internal edges and can be ignored. // node_boundary = new bool[node_num]; for ( i = 0; i < node_num; i++ ) { node_boundary[i] = false; } j = 0; while ( j < 3 * triangle_num ) { j = j + 1; if ( j == 3 * triangle_num ) { for ( i = 0; i < m; i++ ) { node_boundary[edge[i+(j-1)*m]-1] = true; } break; } equal = true; for ( i = 0; i < m; i++ ) { if ( edge[i+(j-1)*m] != edge[i+j*m] ) { equal = false; } } if ( equal ) { j = j + 1; } else { for ( i = 0; i < m; i++ ) { node_boundary[edge[i+(j-1)*m]-1] = true; } } } delete [] edge; return node_boundary; }