function tet_mesh_refine ( prefix ) %*****************************************************************************80 % %% TET_MESH_REFINE refines a tetrahedral mesh of order 4 (linear). % % Usage: % % tet_mesh_refine ( 'prefix' ) % % where % % * 'prefix'_nodes.txt contains nodal coordinates; % * 'prefix'_elements.txt contains the element definitions; % * 'prefix'_ref_nodes.txt contains the new node coordinates; % * 'prefix'_ref_elements.txt contains the new element definitions; % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 01 October 2009 % % Author: % % John Burkardt % % Parameters: % % Input, string PREFIX, the common filename prefix. % fprintf ( 1, '\n' ); timestamp ( ); fprintf ( 1, '\n' ); fprintf ( 1, 'TET_MESH_REFINE:\n' ); fprintf ( 1, ' MATLAB version:\n' ); fprintf ( 1, ' READ a tet mesh, REFINE it, and WRITE the new data.\n' ); fprintf ( 1, '\n' ); fprintf ( 1, ' READ:\n' ); fprintf ( 1, ' a node dataset of NODE_NUM1 points in 3 dimensions.\n' ); fprintf ( 1, ' a tet mesh of TETRA_NUM1 tets of order TET_ORDER.\n' ); fprintf ( 1, '\n' ); fprintf ( 1, ' REFINE:\n' ); fprintf ( 1, ' compute a new set of nodes and tets, which is an\n' ); fprintf ( 1, ' eightfold refinement of the input mesh.\n' ); fprintf ( 1, '\n' ); fprintf ( 1, ' WRITE:\n' ); fprintf ( 1, ' a node dataset of NODE_NUM2 points in 3 dimensions.\n' ); fprintf ( 1, ' a tet mesh of 8*TETRA_NUM1 tets of order TET_ORDER.\n' ); fprintf ( 1, '\n' ); fprintf ( 1, ' At the moment, this program only works for a linear\n' ); fprintf ( 1, ' mesh (TET_ORDER=4).\n' ); % % Argument 1 is the common file prefix. % if ( 1 <= nargin ) else fprintf ( 1, '\n' ); fprintf ( 1, 'TET_MESH_REFINE:\n' ); prefix = input ( ' Please enter the filename prefix:' ); end % % Create the filenames. % input_node_filename = strcat ( prefix, '_nodes.txt' ); input_element_filename = strcat ( prefix, '_elements.txt' ); output_node_filename = strcat ( prefix, '_ref_nodes.txt' ); output_element_filename = strcat ( prefix, '_ref_elements.txt' ); % % Read the node data. % [ dim_num, node_num1 ] = r8mat_header_read ( input_node_filename ); fprintf ( 1, '\n' ); fprintf ( 1, ' Read the header of "%s".\n', input_node_filename ); fprintf ( 1, '\n' ); fprintf ( 1, ' Spatial dimension DIM_NUM = %d\n', dim_num ); fprintf ( 1, ' Number of points NODE_NUM1 = %d\n', node_num1 ); node_xyz1 = r8mat_data_read ( input_node_filename, dim_num, node_num1 ); fprintf ( 1, '\n' ); fprintf ( 1, ' Read the data in "%s".\n', input_node_filename ); r8mat_transpose_print_some ( dim_num, node_num1, node_xyz1, ... 1, 1, dim_num, 5, ' First 5 input nodes:' ); % % Read the tetra data. % [ tetra_order, tetra_num1 ] = i4mat_header_read ( input_element_filename ); if ( tetra_order == 4 ) elseif ( tetra_order == 10 ) fprintf ( 1, '\n' ); fprintf ( 1, 'TET_MESH_REFINE - Fatal error!\n' ); fprintf ( 1, ' This program cannot yet handle the 10-node case.\n' ); fprintf ( 1, ' Try using the sequence:\n' ); fprintf ( 1, ' TET_MESH_Q2L --> TET_MESH_REFINE --> TET_MESH_L2Q.\n' ); error ( 'TET_MESH_REFINE - Fatal error!' ); else fprintf ( 1, '\n' ); fprintf ( 1, 'TET_MESH_REFINE - Fatal error!\n' ); fprintf ( 1, ' Data is not for a 4-node or 10-node tet mesh.\n' ); error ( 'TET_MESH_REFINE - Fatal error!' ); end fprintf ( 1, '\n' ); fprintf ( 1, ' Read the header of "%s".\n', input_element_filename ); fprintf ( 1, '\n' ); fprintf ( 1, ' Tetrahedron order = %d\n', tetra_order ); fprintf ( 1, ' Number of tetras = %d\n', tetra_num1 ); tetra_node1 = i4mat_data_read ( input_element_filename, tetra_order, ... tetra_num1 ); fprintf ( 1, '\n' ); fprintf ( 1, ' Read the data in "%s".\n', input_element_filename ); i4mat_transpose_print_some ( tetra_order, tetra_num1, ... tetra_node1, 1, 1, tetra_order, 5, ' First 5 input tetrahedrons:' ); % % Detect and correct 0-based indexing. % tetra_node1 = mesh_base_one ( node_num1, tetra_order, tetra_num1, ... tetra_node1 ); % % Compute the refined mesh. % [ node_num2, tetra_num2, edge_data ] = tet_mesh_order4_refine_size ( ... node_num1, tetra_num1, tetra_node1 ); fprintf ( 1, ' Number of refined nodes = %d\n', node_num2 ); fprintf ( 1, ' Number of refined tetras = %d\n', tetra_num2 ); [ node_xyz2, tetra_node2 ] = tet_mesh_order4_refine_compute ( ... node_num1, tetra_num1, node_xyz1, tetra_node1, node_num2, tetra_num2, ... edge_data ); % % Print a small amount of the quadratic data. % r8mat_transpose_print_some ( dim_num, node_num2, node_xyz2, ... 1, 1, dim_num, 5, ' First 5 refined nodes:' ); i4mat_transpose_print_some ( tetra_order, tetra_num2, tetra_node2, ... 1, 1, tetra_order, 5, ' First 5 refined tetrahedrons' ); % % Write out the node and tetra data for the refined mesh % r8mat_write ( output_node_filename, dim_num, node_num2, node_xyz2 ); fprintf ( 1, ' Wrote the refined nodes to "%s".\n', ... output_node_filename ); i4mat_write ( output_element_filename, tetra_order, tetra_num2, tetra_node2 ); fprintf ( 1, ' Wrote the refined tetrahedrons to "%s".\n', ... output_element_filename ); % % Terminate. % fprintf ( 1, '\n' ); fprintf ( 1, 'TET_MESH_REFINE:\n' ); fprintf ( 1, ' Normal end of execution.\n' ); fprintf ( 1, '\n' ); timestamp ( ); return end function column_num = file_column_count ( input_file_name ) %*****************************************************************************80 % %% 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: % % 21 February 2004 % % Author: % % John Burkardt % % Parameters: % % Input, string INPUT_FILE_NAME, the name of the file. % % Output, integer COLUMN_NUM, the number of columns in the file. % FALSE = 0; TRUE = 1; % % Open the file. % input_unit = fopen ( input_file_name ); if ( input_unit < 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'FILE_COLUMN_COUNT - Error!\n' ); fprintf ( 1, ' Could not open the file "%s".\n', input_file_name ); error ( 'FILE_COLUMN_COUNT - Error!' ); end % % Read one line, but skip blank lines and comment lines. % Use FGETL so we drop the newline character! % got_one = FALSE; while ( 1 ) line = fgetl ( input_unit ); if ( line == -1 ) break; end if ( s_len_trim ( line ) == 0 ) elseif ( line(1) == '#' ) else got_one = TRUE; break; end end fclose ( input_unit ); if ( got_one == FALSE ) fprintf ( 1, '\n' ); fprintf ( 1, 'FILE_COLUMN_COUNT - Warning!\n' ); fprintf ( 1, ' The file does not seem to contain any data.\n' ); column_num = -1; return; end column_num = s_word_count ( line ); return end function row_num = file_row_count ( input_file_name ) %*****************************************************************************80 % %% FILE_ROW_COUNT counts the number of row records in a file. % % Discussion: % % Each input line is a "RECORD". % % The records are divided into three groups: % % * BLANK LINES (nothing but blanks) % * COMMENT LINES (begin with a '#') % * DATA RECORDS (anything else) % % The value returned by the function is the number of data records. % % By the way, if the MATLAB routine FGETS is used, instead of % FGETL, then the variable LINE will include line termination % characters, which means that a blank line would not actually % have zero characters. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 31 December 2006 % % Author: % % John Burkardt % % Parameters: % % Input, string INPUT_FILE_NAME, the name of the input file. % % Output, integer ROW_NUM, the number of rows found. % input_unit = fopen ( input_file_name ); if ( input_unit < 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'FILE_ROW_COUNT - Error!\n' ); fprintf ( 1, ' Could not open the file "%s".\n', input_file_name ); error ( 'FILE_ROW_COUNT - Error!' ); end blank_num = 0; comment_num = 0; row_num = 0; record_num = 0; while ( 1 ) line = fgetl ( input_unit ); if ( line == -1 ) break; end record_num = record_num + 1; record_length = s_len_trim ( line ); if ( record_length <= 0 ) blank_num = blank_num + 1; elseif ( line(1) == '#' ) comment_num = comment_num + 1; else row_num = row_num + 1; end end fclose ( input_unit ); return end function isgn = i4col_compare ( m, n, a, i, j ) %*****************************************************************************80 % %% I4COL_COMPARE compares columns I and J of a integer array. % % Example: % % Input: % % M = 3, N = 4, I = 2, J = 4 % % A = ( % 1 2 3 4 % 5 6 7 8 % 9 10 11 12 ) % % Output: % % ISGN = -1 % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 12 June 2005 % % Author: % % John Burkardt % % Parameters: % % Input, integer M, N, the number of rows and columns. % % Input, integer A(M,N), an array of N columns of vectors of length M. % % Input, integer I, J, the columns to be compared. % I and J must be between 1 and N. % % Output, integer ISGN, the results of the comparison: % -1, column I < column J, % 0, column I = column J, % +1, column J < column I. % % % Check. % if ( i < 1) fprintf ( 1, '\n' ); fprintf ( 1, 'I4COL_COMPARE - Fatal error!\n' ); fprintf ( 1, ' Column index I = %d < 1.\n', i ); error ( 'I4COL_COMPARE - Fatal error!' ); end if ( n < i ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4COL_COMPARE - Fatal error!\n' ); fprintf ( 1, ' N = %d < column index I = %d.\n', n, i ); error ( 'I4COL_COMPARE - Fatal error!' ); end if ( j < 1 ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4COL_COMPARE - Fatal error!\n' ); fprintf ( 1, ' Column index J = %d < 1.\n', j ); error ( 'I4COL_COMPARE - Fatal error!' ); end if ( n < j ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4COL_COMPARE - Fatal error!\n' ); fprintf ( 1, ' N = %d < column index J = %d.\n', n, j ); error ( 'I4COL_COMPARE - Fatal error!' ); end isgn = 0; if ( i == j ) return end k = 1; while ( k <= m ) if ( a(k,i) < a(k,j) ) isgn = -1; return elseif ( a(k,j) < a(k,i) ) isgn = +1; return end k = k + 1; end return end function a = i4col_sort_a ( m, n, a ) %*****************************************************************************80 % %% I4COL_SORT_A ascending sorts an I4COL. % % Discussion: % % In lexicographic order, the statement "X < Y", applied to two real % 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, the first time they differ, X is smaller. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 20 February 2005 % % Author: % % John Burkardt % % Parameters: % % Input, integer M, the number of rows of A, and the length of % a vector of data. % % Input, integer N, the number of columns of A. % % Input, integer A(M,N), the array of N columns of M-vectors. % % Output, integer A(M,N), the columns of A have been sorted in ascending % lexicographic order. % if ( m <= 0 ) return end if ( n <= 1 ) return end % % Initialize. % indx = 0; isgn = 0; % % Call the external heap sorter. % while ( 1 ) [ indx, i, j ] = sort_heap_external ( n, indx, isgn ); % % Interchange the I and J objects. % if ( 0 < indx ) a = i4col_swap ( m, n, a, i, j ); % % Compare the I and J objects. % elseif ( indx < 0 ) isgn = i4col_compare ( m, n, a, i, j ); elseif ( indx == 0 ) break end end return end function a = i4col_swap ( m, n, a, i, j ) %*****************************************************************************80 % %% I4COL_SWAP swaps columns I and J of a integer array of column data. % % Example: % % Input: % % M = 3, N = 4, I = 2, J = 4 % % A = ( % 1 2 3 4 % 5 6 7 8 % 9 10 11 12 ) % % Output: % % A = ( % 1 4 3 2 % 5 8 7 6 % 9 12 11 10 ) % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 19 February 2005 % % Author: % % John Burkardt % % Parameters: % % Input, integer M, N, the number of rows and columns in the array. % % Input, integer A(M,N), an array of N columns of length M. % % Input, integer I, J, the columns to be swapped. % % Output, integer A(M,N), the array, with columns I and J swapped. % if ( i < 1 || n < i || j < 1 || n < j ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4COL_SWAP - Fatal error!\n' ); fprintf ( 1, ' I or J is out of bounds.\n' ); fprintf ( 1, ' I = %d\n', i ); fprintf ( 1, ' J = %d\n', j ); fprintf ( 1, ' N = %d\n', n ); error ( 'I4COL_SWAP - Fatal error!' ); end if ( i == j ) return end col(1:m) = a(1:m,i)'; a(1:m,i) = a(1:m,j); a(1:m,j) = col(1:m)'; return end function [ j1, j2 ] = i4i4_sort_a ( i1, i2 ) %*****************************************************************************80 % %% I4I4_SORT_A ascending sorts a pair of integers. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 11 October 2005 % % Author: % % John Burkardt % % Parameters: % % Input, integer I1, I2, the values to sort. % % Output, integer J1, J2, the sorted values. % j1 = min ( i1, i2 ); j2 = max ( i1, i2 ); return end function table = i4mat_data_read ( input_filename, m, n ) %*****************************************************************************80 % %% I4MAT_DATA_READ reads data from an I4MAT file. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 27 January 2006 % % Author: % % John Burkardt % % Parameters: % % Input, string INPUT_FILENAME, the name of the input file. % % Input, integer M, N, the number of rows and columns in the data. % % Output, integer TABLE(M,N), the point coordinates. % table = zeros ( m, n ); % % Build up the format string for reading M real numbers. % string = ' '; for i = 0 : m string = strcat ( string, ' %d' ); end input_unit = fopen ( input_filename ); if ( input_unit < 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4MAT_DATA_READ - Error!\n' ); fprintf ( 1, ' Could not open the input file.\n' ); error ( 'I4MAT_DATA_READ - Error!' ); end i = 0; while ( i < n ) line = fgets ( input_unit ); if ( line == -1 ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4MAT_DATA_READ - Error!\n' ); fprintf ( 1, ' End of input while reading data.\n' ); error ( 'I4MAT_DATA_READ - Error!' ); end if ( line(1) == '#' ) elseif ( s_len_trim ( line ) == 0 ) else [ x, count ] = sscanf ( line, string ); if ( count == m ) i = i + 1; table(1:m,i) = x(1:m); end end end fclose ( input_unit ); return end function [ m, n ] = i4mat_header_read ( input_filename ) %*****************************************************************************80 % %% I4MAT_HEADER_READ reads the header from an I4MAT file. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 22 October 2004 % % Author: % % John Burkardt % % Parameters: % % Input, string INPUT_FILENAME, the name of the input file. % % Output, integer M, the spatial dimension. % % Output, integer N, the number of points. % m = file_column_count ( input_filename ); if ( m <= 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4MAT_HEADER_READ - Fatal error!\n' ); fprintf ( 1, ' There was some kind of I/O problem while trying\n' ); fprintf ( 1, ' to count the number of data columns in\n' ); fprintf ( 1, ' the file %s.\n', input_filename ); end n = file_row_count ( input_filename ); if ( n <= 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4MAT_HEADER_READ - Fatal error!\n' ); fprintf ( 1, ' There was some kind of I/O problem while trying\n' ); fprintf ( 1, ' to count the number of data rows in\n' ); fprintf ( 1, ' the file %s\n', input_filename ); end return end function i4mat_transpose_print_some ( m, n, a, ilo, jlo, ihi, jhi, title ) %*****************************************************************************80 % %% I4MAT_TRANSPOSE_PRINT_SOME prints some of an I4MAT, transposed. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 21 June 2005 % % Author: % % John Burkardt % % Parameters: % % Input, integer M, N, the number of rows and columns. % % Input, integer A(M,N), an M by N matrix to be printed. % % Input, integer ILO, JLO, the first row and column to print. % % Input, integer IHI, JHI, the last row and column to print. % % Input, string TITLE, an optional title. % incx = 10; if ( 0 < s_len_trim ( title ) ) fprintf ( 1, '\n' ); fprintf ( 1, '%s\n', title ); end for i2lo = max ( ilo, 1 ) : incx : min ( ihi, m ) i2hi = i2lo + incx - 1; i2hi = min ( i2hi, m ); i2hi = min ( i2hi, ihi ); inc = i2hi + 1 - i2lo; fprintf ( 1, '\n' ); fprintf ( 1, ' Row: ' ); for i = i2lo : i2hi fprintf ( 1, '%7d ', i ); end fprintf ( 1, '\n' ); fprintf ( 1, ' Col\n' ); fprintf ( 1, '\n' ); j2lo = max ( jlo, 1 ); j2hi = min ( jhi, n ); for j = j2lo : j2hi fprintf ( 1, '%5d ', j ); for i2 = 1 : inc i = i2lo - 1 + i2; fprintf ( 1, '%7d ', a(i,j) ); end fprintf ( 1, '\n' ); end end return end function i4mat_write ( output_filename, m, n, table ) %*****************************************************************************80 % %% I4MAT_WRITE writes an I4MAT file. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 20 July 2005 % % Author: % % John Burkardt % % Parameters: % % Input, string OUTPUT_FILENAME, the output filename. % % Input, integer M, the spatial dimension. % % Input, integer N, the number of points. % % Input, integer TABLE(M,N), the points. % % Input, logical HEADER, is TRUE if the header is to be included. % % % Open the file. % output_unit = fopen ( output_filename, 'wt' ); if ( output_unit < 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'I4MAT_WRITE - Error!\n' ); fprintf ( 1, ' Could not open the output file.\n' ); error ( 'I4MAT_WRITE - Error!' ); end % % Write the data. % for j = 1 : n for i = 1 : m fprintf ( output_unit, ' %12d', round ( table(i,j) ) ); end fprintf ( output_unit, '\n' ); end % % Close the file. % fclose ( output_unit ); return end function element_node = mesh_base_one ( node_num, element_order, ... element_num, element_node ) %*****************************************************************************80 % %% MESH_BASE_ONE ensures that the element definition is one-based. % % Discussion: % % The ELEMENT_NODE array contains nodes indices that form elements. % The convention for node indexing might start at 0 or at 1. % Since a MATLAB program will naturally assume a 1-based indexing, it is % necessary to check a given element definition and, if it is actually % 0-based, to convert it. % % This function attempts to detect 0-based node indexing and correct it. % % Thanks to Feifei Xu for pointing out that I was subtracting 1 when I % should have been adding 1! 29 November 2012. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 29 November 2012 % % Author: % % John Burkardt % % Parameters: % % Input, integer NODE_NUM, the number of nodes. % % Input, integer ELEMENT_ORDER, the order of the elements. % % Input, integer ELEMENT_NUM, the number of elements. % % Input/output, integer ELEMENT_NODE(ELEMENT_ORDE,ELEMENT_NUM), the element % definitions. % node_min = min ( min ( element_node(1:element_order,1:element_num) ) ); node_max = max ( max ( element_node(1:element_order,1:element_num) ) ); if ( node_min == 0 && node_max == node_num - 1 ) fprintf ( 1, '\n' ); fprintf ( 1, 'MESH_BASE_ONE:\n' ); fprintf ( 1, ' The element indexing appears to be 0-based!\n' ); fprintf ( 1, ' This will be converted to 1-based.\n' ); element_node(1:element_order,1:element_num) = ... element_node(1:element_order,1:element_num) + 1; elseif ( node_min == 1 && node_max == node_num ) fprintf ( 1, '\n' ); fprintf ( 1, 'MESH_BASE_ONE:\n' ); fprintf ( 1, ' The element indexing appears to be 1-based!\n' ); fprintf ( 1, ' No conversion is necessary.\n' ); else fprintf ( 1, '\n' ); fprintf ( 1, 'MESH_BASE_ONE - Warning!\n' ); fprintf ( 1, ' The element indexing is not of a recognized type.\n' ); end return end function table = r8mat_data_read ( input_filename, m, n ) %*****************************************************************************80 % %% R8MAT_DATA_READ reads data from an R8MAT file. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 27 January 2006 % % Author: % % John Burkardt % % Parameters: % % Input, string INPUT_FILENAME, the name of the input file. % % Input, integer M, N, the number of rows and columns of data. % % Output, real TABLE(M,N), the point coordinates. % table = zeros ( m, n ); % % Build up the format string for reading M real numbers. % string = ' '; for i = 0 : m string = strcat ( string, ' %f' ); end input_unit = fopen ( input_filename ); if ( input_unit < 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'R8MAT_DATA_READ - Error!\n' ); fprintf ( 1, ' Could not open the file.\n' ); error ( 'R8MAT_DATA_READ - Error!' ); end i = 0; while ( i < n ) line = fgets ( input_unit ); if ( line == -1 ) break; end if ( line(1) == '#' ) elseif ( s_len_trim ( line ) == 0 ) else [ x, count ] = sscanf ( line, string ); if ( count == m ) i = i + 1; table(1:m,i) = x(1:m); end end end fclose ( input_unit ); return end function [ m, n ] = r8mat_header_read ( input_filename ) %*****************************************************************************80 % %% R8MAT_HEADER_READ reads the header from an R8MAT file. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 22 October 2004 % % Author: % % John Burkardt % % Parameters: % % Input, string INPUT_FILENAME, the name of the input file. % % Output, integer M, the spatial dimension. % % Output, integer N, the number of points. % m = file_column_count ( input_filename ); if ( m <= 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'R8MAT_HEADER_READ - Fatal error!\n' ); fprintf ( 1, ' There was some kind of I/O problem while trying\n' ); fprintf ( 1, ' to count the number of data columns in\n' ); fprintf ( 1, ' the file %s.\n', input_filename ); end n = file_row_count ( input_filename ); if ( n <= 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'R8MAT_HEADER_READ - Fatal error!\n' ); fprintf ( 1, ' There was some kind of I/O problem while trying\n' ); fprintf ( 1, ' to count the number of data rows in\n' ); fprintf ( 1, ' the file %s\n', input_filename ); end return end function r8mat_transpose_print_some ( m, n, a, ilo, jlo, ihi, jhi, title ) %*****************************************************************************80 % %% R8MAT_TRANSPOSE_PRINT_SOME prints some of an R8MAT, transposed. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 23 May 2005 % % Author: % % John Burkardt % % Parameters: % % Input, integer M, N, the number of rows and columns. % % Input, real A(M,N), an M by N matrix to be printed. % % Input, integer ILO, JLO, the first row and column to print. % % Input, integer IHI, JHI, the last row and column to print. % % Input, string TITLE, an optional title. % incx = 5; if ( 0 < s_len_trim ( title ) ) fprintf ( 1, '\n' ); fprintf ( 1, '%s\n', title ); end for i2lo = max ( ilo, 1 ) : incx : min ( ihi, m ) i2hi = i2lo + incx - 1; i2hi = min ( i2hi, m ); i2hi = min ( i2hi, ihi ); inc = i2hi + 1 - i2lo; fprintf ( 1, '\n' ); fprintf ( 1, ' Row: ' ); for i = i2lo : i2hi fprintf ( 1, '%7d ', i ); end fprintf ( 1, '\n' ); fprintf ( 1, ' Col\n' ); j2lo = max ( jlo, 1 ); j2hi = min ( jhi, n ); for j = j2lo : j2hi fprintf ( 1, '%5d ', j ); for i2 = 1 : inc i = i2lo - 1 + i2; fprintf ( 1, '%12f', a(i,j) ); end fprintf ( 1, '\n' ); end end return end function r8mat_write ( output_filename, m, n, table ) %*****************************************************************************80 % %% R8MAT_WRITE writes an R8MAT file. % % 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, integer M, the spatial dimension. % % Input, integer N, the number of points. % % Input, real TABLE(M,N), the points. % % % Open the file. % output_unit = fopen ( output_filename, 'wt' ); if ( output_unit < 0 ) fprintf ( 1, '\n' ); fprintf ( 1, 'R8MAT_WRITE - Error!\n' ); fprintf ( 1, ' Could not open the output file.\n' ); error ( 'R8MAT_WRITE - Error!' ); end % % Write the data. % % For greater precision, try: % % fprintf ( output_unit, ' %24,16f', table(i,j) ); % for j = 1 : n for i = 1 : m fprintf ( output_unit, ' %14f', table(i,j) ); end fprintf ( output_unit, '\n' ); end % % Close the file. % fclose ( output_unit ); return end function len = s_len_trim ( s ) %*****************************************************************************80 % %% S_LEN_TRIM returns the length of a character string to the last nonblank. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 14 June 2003 % % Author: % % John Burkardt % % Parameters: % % Input, string S, the string to be measured. % % Output, integer LEN, the length of the string up to the last nonblank. % len = length ( s ); while ( 0 < len ) if ( s(len) ~= ' ' ) return end len = len - 1; end return end function word_num = s_word_count ( s ) %*****************************************************************************80 % %% S_WORD_COUNT counts the number of "words" in a string. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 30 January 2006 % % Author: % % John Burkardt % % Parameters: % % Input, string S, the string to be examined. % % Output, integer WORD_NUM, the number of "words" in the string. % Words are presumed to be separated by one or more blanks. % FALSE = 0; TRUE = 1; word_num = 0; s_length = length ( s ); if ( s_length <= 0 ) return; end blank = TRUE; for i = 1 : s_length if ( s(i) == ' ' ) blank = TRUE; elseif ( blank == TRUE ) word_num = word_num + 1; blank = FALSE; end end return end function [ indx, i, j ] = sort_heap_external ( n, indx, isgn ) %*****************************************************************************80 % %% SORT_HEAP_EXTERNAL externally sorts a list of items into ascending order. % % Discussion: % % The actual list of data is not passed to the routine. Hence this % routine may be used to sort integers, reals, numbers, names, % dates, shoe sizes, and so on. After each call, the routine asks % the user to compare or interchange two items, until a special % return value signals that the sorting is completed. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 05 February 2004 % % Author: % % Original FORTRAN77 version by Albert Nijenhuis, Herbert Wilf. % MATLAB version by John Burkardt % % Reference: % % Albert Nijenhuis, Herbert Wilf. % Combinatorial Algorithms, % Academic Press, 1978, second edition, % ISBN 0-12-519260-6. % % Parameters: % % Input, integer N, the number of items to be sorted. % % Input, integer INDX, the main communication signal. % The user must set INDX to 0 before the first call. % Thereafter, the user should set the input value of INDX % to the output value from the previous call. % % Input, integer ISGN, results of comparison of elements I and J. % (Used only when the previous call returned INDX less than 0). % ISGN <= 0 means I is less than or equal to J; % 0 <= ISGN means I is greater than or equal to J. % % Output, integer INDX, the main communication signal. % If INDX is % % greater than 0, the user should: % * interchange items I and J; % * call again. % % less than 0, the user should: % * compare items I and J; % * set ISGN = -1 if I < J, ISGN = +1 if J < I; % * call again. % % equal to 0, the sorting is done. % % Output, integer I, J, the indices of two items. % On return with INDX positive, elements I and J should be interchanged. % On return with INDX negative, elements I and J should be compared, and % the result reported in ISGN on the next call. % persistent i_save; persistent j_save; persistent k; persistent k1; persistent n1; % % INDX = 0: This is the first call. % if ( indx == 0 ) i_save = -1; j_save = -1; k = floor ( n / 2 ); k1 = k; n1 = n; % % INDX < 0: The user is returning the results of a comparison. % elseif ( indx < 0 ) if ( indx == -2 ) if ( isgn < 0 ) i_save = i_save + 1; end j_save = k1; k1 = i_save; indx = -1; i = i_save; j = j_save; return; end if ( 0 < isgn ) indx = 2; i = i_save; j = j_save; return; end if ( k <= 1 ) if ( n1 == 1 ) i_save = 0; j_save = 0; indx = 0; else i_save = n1; n1 = n1 - 1; j_save = 1; indx = 1; end i = i_save; j = j_save; return; end k = k - 1; k1 = k; % % 0 < INDX, the user was asked to make an interchange. % elseif ( indx == 1 ) k1 = k; end while ( 1 ) i_save = 2 * k1; if ( i_save == n1 ) j_save = k1; k1 = i_save; indx = -1; i = i_save; j = j_save; return; elseif ( i_save <= n1 ) j_save = i_save + 1; indx = -2; i = i_save; j = j_save; return; end if ( k <= 1 ) break; end k = k - 1; k1 = k; end if ( n1 == 1 ) i_save = 0; j_save = 0; indx = 0; i = i_save; j = j_save; else i_save = n1; n1 = n1 - 1; j_save = 1; indx = 1; i = i_save; j = j_save; end return end function [ node_xyz2, tetra_node2 ] = tet_mesh_order4_refine_compute ( ... node_num1, tetra_num1, node_xyz1, tetra_node1, node_num2, tetra_num2, ... edge_data ) %*****************************************************************************80 % %% TET_MESH_ORDER4_REFINE_COMPUTE computes a refined order4 tet mesh. % % Discussion: % % A refined 4-node tet mesh can be derived from a given % 4-node tet mesh by interpolating nodes at the midpoint of % every edge of the mesh. % % The mesh is described indirectly, as the sum of individual % tetrahedrons. A single physical edge may be a logical edge of % any number of tetrahedrons. It is important, however, that a % new node be created exactly once for each edge, assigned an index, % and associated with every tetrahedron that shares this edge. % % This routine handles that problem. % % The primary amount of work occurs in sorting a list of 6 * TETRA_NUM % data items, one item for every edge of every tetrahedron. Each % data item records, for a given tetrahedron edge, the global indices % of the two endpoints, the local indices of the two endpoints, % and the index of the tetrahedron. % % Through careful sorting, it is possible to arrange this data in % a way that allows the proper generation of the interpolated nodes. % % Let us add the new nodes and temporarily assign them local indices % 5 through X, based on the following ordering: % % 1, 2, 3, 4, (1+2), (1+3), (1+4), (2+3), (2+4), (3+4). % % Then let us assign these nodes to eight subtetrahedrons as follows: % % 1, 5, 6, 7 % 2, 5, 8, 9 % 3, 6, 8, 9 % 4, 7, 9, X % 5, 6, 7, 9 % 5, 6, 8, 9 % 6, 7, 9, X % 6, 8, 9, X % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 25 January 2007 % % Author: % % John Burkardt % % Reference: % % Anwei Liu, Barry Joe, % Quality Local Refinement of Tetrahedral Meshes Based % on 8-Subtetrahedron Subdivision, % Mathematics of Computation, % Volume 65, Number 215, July 1996, pages 1183-1200. % % Parameters: % % Input, integer NODE_NUM1, the number of nodes in the input mesh. % % Input, integer TETRA_NUM1, the number of tetrahedrons in the % input mesh. % % Input, real NODE_XYZ1(3,NODE_NUM1), the coordinates of % the nodes that make up the input mesh. % % Input, integer TETRA_NODE1(4,TETRA_NUM1), the indices of the nodes % in the input mesh. % % Input, integer NODE_NUM2, the number of nodes for the refined mesh. % % Input, integer TETRA_NUM2, the number of tetrahedrons in the % refined mesh. % % Input, integer EDGE_DATA(5,6*TETRA_NUM), edge data. % % Output, real NODE_XYZ2(3,NODE_NUM2), the coordinates of % the nodes that make up the output mesh. % % Output, integer TETRA_NODE2(4,TETRA_NUM2), the indices of the nodes % in the output mesh. % % % Generate the index and coordinates of the new midside nodes, % and update the tetradehron-node data. % node_xyz2(1:3,1:node_num1) = node_xyz1(1:3,1:node_num1); tetra_node2(1:4,1:tetra_num2) = -1; % % The vertices of the input tetrahedron can be assigned now. % for tetra1 = 1 : tetra_num1 tetra_node2(1,(tetra1-1)*8+1) = tetra_node1(1,tetra1); tetra_node2(1,(tetra1-1)*8+2) = tetra_node1(2,tetra1); tetra_node2(1,(tetra1-1)*8+3) = tetra_node1(3,tetra1); tetra_node2(1,(tetra1-1)*8+4) = tetra_node1(4,tetra1); end node = node_num1; n1_old = -1; n2_old = -1; for edge = 1 : 6 * tetra_num1 % % Read the data defining the edge. % n1 = edge_data(1,edge); n2 = edge_data(2,edge); % % If this edge is new, create the coordinates and index. % if ( n1 ~= n1_old || n2 ~= n2_old ) node = node + 1; if ( node_num2 < node ) fprintf ( 1, '\n' ); fprintf ( 1, 'TET_MESH_ORDER4_REFINE_COMPUTE - Fatal error!\n' ); fprintf ( 1, ' Node index exceeds NODE_NUM2.\n' ); error ( 'TET_MESH_ORDER4_REFINE_COMPUTE - Fatal error!' ); end node_xyz2(1:3,node) = ( node_xyz2(1:3,n1) + node_xyz2(1:3,n2) ) / 2.0; n1_old = n1; n2_old = n2; end % % Assign the node to the tetrahedron. % v1 = edge_data(3,edge); v2 = edge_data(4,edge); tetra1 = edge_data(5,edge); % % We know the two vertices that bracket this new node. % This tells us whether it is new node number 5, 6, 7, 8, 9 or 10. % This tells us which of the new subtetrahedrons it belongs to, % and what position it occupies. % if ( v1 == 1 && v2 == 2 ) tetra_node2(2,(tetra1-1)*8+1) = node; tetra_node2(2,(tetra1-1)*8+2) = node; tetra_node2(1,(tetra1-1)*8+5) = node; tetra_node2(1,(tetra1-1)*8+6) = node; elseif ( v1 == 1 && v2 == 3 ) tetra_node2(3,(tetra1-1)*8+1) = node; tetra_node2(2,(tetra1-1)*8+3) = node; tetra_node2(2,(tetra1-1)*8+5) = node; tetra_node2(2,(tetra1-1)*8+6) = node; tetra_node2(1,(tetra1-1)*8+7) = node; tetra_node2(1,(tetra1-1)*8+8) = node; elseif ( v1 == 1 && v2 == 4 ) tetra_node2(4,(tetra1-1)*8+1) = node; tetra_node2(2,(tetra1-1)*8+4) = node; tetra_node2(3,(tetra1-1)*8+5) = node; tetra_node2(2,(tetra1-1)*8+7) = node; elseif ( v1 == 2 && v2 == 3 ) tetra_node2(3,(tetra1-1)*8+2) = node; tetra_node2(3,(tetra1-1)*8+3) = node; tetra_node2(3,(tetra1-1)*8+6) = node; tetra_node2(2,(tetra1-1)*8+8) = node; elseif ( v1 == 2 && v2 == 4 ) tetra_node2(4,(tetra1-1)*8+2) = node; tetra_node2(4,(tetra1-1)*8+3) = node; tetra_node2(3,(tetra1-1)*8+4) = node; tetra_node2(4,(tetra1-1)*8+5) = node; tetra_node2(4,(tetra1-1)*8+6) = node; tetra_node2(3,(tetra1-1)*8+7) = node; tetra_node2(3,(tetra1-1)*8+8) = node; elseif ( v1 == 3 && v2 == 4 ) tetra_node2(4,(tetra1-1)*8+4) = node; tetra_node2(4,(tetra1-1)*8+7) = node; tetra_node2(4,(tetra1-1)*8+8) = node; end end return end function [ node_num2, tetra_num2, edge_data ] = ... tet_mesh_order4_refine_size ( node_num1, tetra_num1, tetra_node1 ) %*****************************************************************************80 % %% TET_MESH_ORDER4_REFINE_SIZE sizes a refined order 4 tet mesh. % % Discussion: % % A refined tet mesh can be derived from an existing one by interpolating % nodes at the midpoint of every edge of the mesh. % % The mesh is described indirectly, as the sum of individual % tetrahedrons. A single physical edge may be a logical edge of % any number of tetrahedrons. It is important, however, that a % new node be created exactly once for each edge, assigned an index, % and associated with every tetrahedron that shares this edge. % % This routine handles that problem. % % The primary amount of work occurs in sorting a list of 6 * TETRA_NUM % data items, one item for every edge of every tetrahedron. Each % data item records, for a given tetrahedron edge, the global indices % of the two endpoints, the local indices of the two endpoints, % and the index of the tetrahedron. % % Through careful sorting, it is possible to arrange this data in % a way that allows the proper generation of the interpolated nodes. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 25 January 2007 % % Author: % % John Burkardt % % Parameters: % % Input, integer NODE_NUM1, the number of nodes in the original mesh. % % Input, integer TETRA_NUM1, the number of tetrahedrons in the % original mesh. % % Input, integer TETRA_NODE1(4,TETRA_NUM1), the indices of the nodes % that form the tetrahedrons in the input mesh. % % Output, integer NODE_NUM2, the number of nodes in the refined mesh. % % Output, integer TETRA_NUM2, the number of tetrahedrons in the % refined mesh. % % Output, integer EDGE_DATA(5,6*TETRA_NUM1), edge data. % % % Step 1. % From the list of nodes for tetrahedron T, of the form: (I,J,K,L) % construct the six edge relations: % % (I,J,1,2,T) % (I,K,1,3,T) % (I,L,1,4,T) % (J,K,2,3,T) % (J,L,2,4,T) % (K,L,3,4,T) % % In order to make matching easier, we reorder each pair of nodes % into ascending order. % edge_data = zeros ( 5, 6 * tetra_num1 ); for tetra = 1 : tetra_num1 i = tetra_node1(1,tetra); j = tetra_node1(2,tetra); k = tetra_node1(3,tetra); l = tetra_node1(4,tetra); [ a, b ] = i4i4_sort_a ( i, j ); edge_data(1:5,6*(tetra-1)+1) = [ a, b, 1, 2, tetra ]'; [ a, b ] = i4i4_sort_a ( i, k ); edge_data(1:5,6*(tetra-1)+2) = [ a, b, 1, 3, tetra ]'; [ a, b ] = i4i4_sort_a ( i, l ); edge_data(1:5,6*(tetra-1)+3) = [ a, b, 1, 4, tetra ]'; [ a, b ] = i4i4_sort_a ( j, k ); edge_data(1:5,6*(tetra-1)+4) = [ a, b, 2, 3, tetra ]'; [ a, b ] = i4i4_sort_a ( j, l ); edge_data(1:5,6*(tetra-1)+5) = [ a, b, 2, 4, tetra ]'; [ a, b ] = i4i4_sort_a ( k, l ); edge_data(1:5,6*(tetra-1)+6) = [ a, b, 3, 4, tetra ]'; end % % Step 2. Perform an ascending dictionary sort on the neighbor relations. % We only intend to sort on rows 1:2; the routine we call here % sorts on the full column but that won't hurt us. % % What we need is to find all cases where tetrahedrons share an edge. % By sorting the columns of the EDGE_DATA array, we will put shared edges % next to each other. % edge_data = i4col_sort_a ( 5, 6*tetra_num1, edge_data ); % % Step 3. All the tetrahedrons which share an edge show up as consecutive % columns with identical first two entries. Figure out how many new % nodes there are, and allocate space for their coordinates. % node_num2 = node_num1; n1_old = -1; n2_old = -1; for edge = 1 : 6 * tetra_num1 n1 = edge_data(1,edge); n2 = edge_data(2,edge); if ( n1 ~= n1_old || n2 ~= n2_old ) node_num2 = node_num2 + 1; n1_old = n1; n2_old = n2; end end tetra_num2 = 8 * tetra_num1; return end function timestamp ( ) %*****************************************************************************80 % %% TIMESTAMP prints the current YMDHMS date as a timestamp. % % Licensing: % % This code is distributed under the GNU LGPL license. % % Modified: % % 14 February 2003 % % Author: % % John Burkardt % t = now; c = datevec ( t ); s = datestr ( c, 0 ); fprintf ( 1, '%s\n', s ); return end