C Copyright(C) 1999-2020 National Technology & Engineering Solutions C of Sandia, LLC (NTESS). Under the terms of Contract DE-NA0003525 with C NTESS, the U.S. Government retains certain rights in this software. C C See packages/seacas/LICENSE for details program testwtd c This is a test program for the Fortran binding of the EXODUS II c database write routines using double precision reals. c history - c Original L.A. Schoof c 02/25/93 V.R. Yarberry - Added error checks for file creation. c 03/04/93 V.R. Yarberry - Fixed bug in expvtt test, ebids was not passed c 08/31/93 VRY - updated to match API version 2.00 include 'exodusII.inc' integer iin, iout integer exoid, num_dim, num_nodes, num_elem, num_elem_blk integer num_elem_in_block(2), num_node_sets integer num_side_sets integer i, j, k, m, elem_map(2), connect(4) integer node_list(10), elem_list(10), side_list(10) integer ebids(2),ids(2), num_nodes_per_set(2), num_elem_per_set(2) integer num_df_per_set(2) integer df_ind(2), node_ind(2), elem_ind(2), num_qa_rec, num_info integer num_glo_vars, num_nod_vars, num_ele_vars integer truth_tab(3,2) integer whole_time_step, num_time_steps integer cpu_word_size, io_word_size integer prop_array(2) real*8 glob_var_vals(10), nodal_var_vals(8) real*8 time_value, elem_var_vals(20) real*8 x(8), y(8), dummy(1) real*8 attrib(1), dist_fact(8) character*(MXSTLN) coord_names(3) character*(MXSTLN) cname character*(MXSTLN) var_names(3) character*(MXSTLN) qa_record(4,2) character*(MXLNLN) inform(3) character*(MXSTLN) prop_names(2) logical whole data iin /5/, iout /6/ cpu_word_size = 8 io_word_size = 8 c create EXODUS II files exoid = excre ("test.exo", 1 EXCLOB, cpu_word_size, io_word_size, ierr) write (iout,'("after excre for test.exo,id: ",i4,", err=",i3)') 1 exoid, ierr write (iout,'(" cpu word size: ",i4," io word size: ",i4)') 1 cpu_word_size, io_word_size write (iout,'("after excre, error = ", i4)') ierr c initialize file with parameters num_dim = 2 num_nodes = 8 num_elem = 2 num_elem_blk = 2 num_node_sets = 2 num_side_sets = 2 call expini (exoid, "This is a test", num_dim, num_nodes, 1 num_elem, num_elem_blk, num_node_sets, 2 num_side_sets, ierr) write (iout, '("after expini, error = ", i4)' ) ierr c write nodal coordinates values and names to database x(1) = 0.0 x(2) = 1.0 x(3) = 1.0 x(4) = 0.0 x(5) = 1.0 x(6) = 2.0 x(7) = 2.0 x(8) = 1.0 y(1) = 0.0 y(2) = 0.0 y(3) = 1.0 y(4) = 1.0 y(5) = 0.0 y(6) = 0.0 y(7) = 1.0 y(8) = 1.0 call expcor (exoid, x, y, dummy, ierr) write (iout, '("after expcor, error = ", i4)' ) ierr coord_names(1) = "xcoor" coord_names(2) = "ycoor" call expcon (exoid, coord_names, ierr) write (iout, '("after expcon, error = ", i4)' ) ierr c write element order map do 10 i = 1, num_elem elem_map(i) = i 10 continue call expmap (exoid, elem_map, ierr) write (iout, '("after expmap, error = ", i4)' ) ierr c write element block parameters num_elem_in_block(1) = 1 num_elem_in_block(2) = 1 ebids(1) = 10 ebids(2) = 11 cname = "quad" call expelb (exoid,ebids(1),cname,num_elem_in_block(1),4,1,ierr) write (iout, '("after expelb, error = ", i4)' ) ierr call expelb (exoid,ebids(2),cname,num_elem_in_block(2),4,1,ierr) write (iout, '("after expelb, error = ", i4)' ) ierr c write element block properties prop_names(1) = "MATL" prop_names(2) = "DENSITY" call exppn(exoid,EXEBLK,2,prop_names,ierr) write (iout, '("after exppn, error = ", i4)' ) ierr call expp(exoid, EXEBLK, ebids(1), "MATL", 10, ierr) write (iout, '("after expp, error = ", i4)' ) ierr call expp(exoid, EXEBLK, ebids(2), "MATL", 20, ierr) write (iout, '("after expp, error = ", i4)' ) ierr c write element connectivity connect(1) = 1 connect(2) = 2 connect(3) = 3 connect(4) = 4 call expelc (exoid, ebids(1), connect, ierr) write (iout, '("after expelc, error = ", i4)' ) ierr connect(1) = 5 connect(2) = 6 connect(3) = 7 connect(4) = 8 call expelc (exoid, ebids(2), connect, ierr) write (iout, '("after expelc, error = ", i4)' ) ierr c write element block attributes attrib(1) = 3.14159 call expeat (exoid, ebids(1), attrib, ierr) write (iout, '("after expeat, error = ", i4)' ) ierr attrib(1) = 6.14159 call expeat (exoid, ebids(2), attrib, ierr) write (iout, '("after expeat, error = ", i4)' ) ierr c write individual node sets node_list(1) = 100 node_list(2) = 101 node_list(3) = 102 node_list(4) = 103 node_list(5) = 104 dist_fact(1) = 1.0 dist_fact(2) = 2.0 dist_fact(3) = 3.0 dist_fact(4) = 4.0 dist_fact(5) = 5.0 c call expnp (exoid, 20, 5, 5, ierr) c write (iout, '("after expnp, error = ", i4)' ) ierr c call expns (exoid, 20, node_list, ierr) c write (iout, '("after expns, error = ", i4)' ) ierr c call expnsd (exoid, 20, dist_fact, ierr) c write (iout, '("after expnsd, error = ", i4)' ) ierr node_list(1) = 200 node_list(2) = 201 node_list(3) = 202 dist_fact(1) = 1.1 dist_fact(2) = 2.1 dist_fact(3) = 3.1 c call expnp (exoid, 21, 3, 3, ierr) c write (iout, '("after expnp, error = ", i4)' ) ierr c call expns (exoid, 21, node_list, ierr) c write (iout, '("after expns, error = ", i4)' ) ierr c call expnsd (exoid, 21, dist_fact, ierr) c write (iout, '("after expnsd, error = ", i4)' ) ierr c write concatenated node sets; this produces the same information as c the above code which writes individual node sets ids(1) = 20 ids(2) = 21 num_nodes_per_set(1) = 5 num_nodes_per_set(2) = 3 num_df_per_set(1) = 5 num_df_per_set(2) = 3 node_ind(1) = 1 node_ind(2) = 6 df_ind(1) = 1 df_ind(2) = 6 node_list(1) = 100 node_list(2) = 101 node_list(3) = 102 node_list(4) = 103 node_list(5) = 104 node_list(6) = 200 node_list(7) = 201 node_list(8) = 202 dist_fact(1) = 1.0 dist_fact(2) = 2.0 dist_fact(3) = 3.0 dist_fact(4) = 4.0 dist_fact(5) = 5.0 dist_fact(6) = 1.1 dist_fact(7) = 2.1 dist_fact(8) = 3.1 call expcns (exoid, ids, num_nodes_per_set, num_df_per_set, 1 node_ind, df_ind, node_list, dist_fact, ierr) write (iout, '("after expcns, error = ", i4)' ) ierr c write node set properties prop_names(1) = "FACE" call expp(exoid, EXNSET, 20, prop_names(1), 4, ierr) write (iout, '("after expp, error = ", i4)' ) ierr call expp(exoid, EXNSET, 21, prop_names(1), 5, ierr) write (iout, '("after expp, error = ", i4)' ) ierr prop_array(1) = 1000 prop_array(2) = 2000 prop_names(1) = "VELOCITY" call exppa(exoid, EXNSET, prop_names(1), prop_array, ierr) write (iout, '("after exppa, error = ", i4)' ) ierr c write individual side sets elem_list(1) = 11 elem_list(2) = 12 side_list(1) = 1 side_list(2) = 2 dist_fact(1) = 30.0 dist_fact(2) = 30.1 dist_fact(3) = 30.2 dist_fact(4) = 30.3 c call expsp (exoid, 30, 2, 4, ierr) c write (iout, '("after expsp, error = ", i4)' ) ierr c call expss (exoid, 30, elem_list, side_list, ierr) c write (iout, '("after expss, error = ", i4)' ) ierr c call expssd (exoid, 30, dist_fact, ierr) c write (iout, '("after expssd, error = ", i4)' ) ierr elem_list(1) = 13 elem_list(2) = 14 side_list(1) = 3 side_list(2) = 4 dist_fact(1) = 31.0 dist_fact(2) = 31.1 dist_fact(3) = 31.2 dist_fact(4) = 31.3 c call expsp (exoid, 31, 2, 4, ierr) c write (iout, '("after expsp, error = ", i4)' ) ierr c call expss (exoid, 31, elem_list, side_list, ierr) c write (iout, '("after expss, error = ", i4)' ) ierr c call expssd (exoid, 31, dist_fact, ierr) c write (iout, '("after expssd, error = ", i4)' ) ierr c write concatenated side sets; this produces the same information as c the above code which writes individual side sets ids(1) = 30 ids(2) = 31 num_elem_per_set(1) = 2 num_elem_per_set(2) = 2 num_df_per_set(1) = 4 num_df_per_set(2) = 4 elem_ind(1) = 1 elem_ind(2) = 3 df_ind(1) = 1 df_ind(2) = 5 elem_list(1) = 11 elem_list(2) = 12 elem_list(3) = 13 elem_list(4) = 14 side_list(1) = 1 side_list(2) = 2 side_list(3) = 3 side_list(4) = 4 dist_fact(1) = 30.0 dist_fact(2) = 30.1 dist_fact(3) = 30.2 dist_fact(4) = 30.3 dist_fact(5) = 31.0 dist_fact(6) = 31.1 dist_fact(7) = 31.2 dist_fact(8) = 31.3 call expcss (exoid, ids, num_elem_per_set, num_df_per_set, 1 elem_ind, df_ind, elem_list, side_list, dist_fact, 2 ierr) write (iout, '("after expcss, error = ", i4)' ) ierr prop_names(1) = "COLOR" call expp(exoid, EXSSET, 30, prop_names(1), 100, ierr) write (iout, '("after expp, error = ", i4)' ) ierr call expp(exoid, EXSSET, 31, prop_names(1), 101, ierr) write (iout, '("after expp, error = ", i4)' ) ierr c write QA records num_qa_rec = 2 qa_record(1,1) = "TESTWTD fortran version" qa_record(2,1) = "testwtd" qa_record(3,1) = "07/07/93" qa_record(4,1) = "15:41:33" qa_record(1,2) = "FASTQ" qa_record(2,2) = "fastq" qa_record(3,2) = "07/07/93" qa_record(4,2) = "16:41:33" call expqa (exoid, num_qa_rec, qa_record, ierr) write (iout, '("after expqa, error = ", i4)' ) ierr c write information records num_info = 3 inform(1) = "This is the first information record." inform(2) = "This is the second information record." inform(3) = "This is the third information record." call expinf (exoid, num_info, inform, ierr) write (iout, '("after expinf, error = ", i4)' ) ierr c write results variables parameters and names num_glo_vars = 1 var_names(1) = "glo_vars" call expvp (exoid, "g", num_glo_vars, ierr) write (iout, '("after expvp, error = ", i4)' ) ierr call expvan (exoid, "g", num_glo_vars, var_names, ierr) write (iout, '("after expvan, error = ", i4)' ) ierr num_nod_vars = 2 var_names(1) = "nod_var0" var_names(2) = "nod_var1" call expvp (exoid, "n", num_nod_vars, ierr) write (iout, '("after expvp, error = ", i4)' ) ierr call expvan (exoid, "n", num_nod_vars, var_names, ierr) write (iout, '("after expvan, error = ", i4)' ) ierr num_ele_vars = 3 var_names(1) = "ele_var0" var_names(2) = "ele_var1" var_names(3) = "ele_var2" call expvp (exoid, "e", num_ele_vars, ierr) write (iout, '("after expvp, error = ", i4)' ) ierr call expvan (exoid, "e", num_ele_vars, var_names, ierr) write (iout, '("after expvan, error = ", i4)' ) ierr c write element variable truth table k = 0 do 30 i = 1,num_elem_blk do 20 j = 1,num_ele_vars truth_tab(j,i) = 1 20 continue 30 continue call expvtt (exoid, num_elem_blk, num_ele_vars, truth_tab, ierr) write (iout, '("after expvtt, error = ", i4)' ) ierr c for each time step, write the analysis results; c the code below fills the arrays hist_var_vals, glob_var_vals, c nodal_var_vals, and elem_var_vals with values for debugging purposes; c obviously the analysis code will populate these arrays whole = .true. hist_time_step = 1 whole_time_step = 1 num_time_steps = 10 do 110 i = 1, num_time_steps time_value = dble(i)/100 c write time value call exptim (exoid, whole_time_step, time_value, ierr) write (iout, '("after exptim, error = ", i4)' ) ierr c write global variables do 50 j = 1, num_glo_vars glob_var_vals(j) = real(j+1) * time_value 50 continue call expgv (exoid, whole_time_step, num_glo_vars, 1 glob_var_vals, ierr) write (iout, '("after expgv, error = ", i4)' ) ierr c write nodal variables do 70 k = 1, num_nod_vars do 60 j = 1, num_nodes nodal_var_vals(j) = real(k) + (real(j) * time_value) 60 continue call expnv (exoid, whole_time_step, k, num_nodes, 1 nodal_var_vals, ierr) write (iout, '("after expnv, error = ", i4)' ) ierr 70 continue c write element variables do 100 k = 1, num_ele_vars do 90 j = 1, num_elem_blk do 80 m = 1, num_elem_in_block(j) elem_var_vals(m) = real(k+1) + real(j+1) + 1 (real(m)*time_value) c write(iout,*)'elem_var_val(',m,'): ',elem_var_vals(m) 80 continue call expev (exoid, whole_time_step, k, ebids(j), 1 num_elem_in_block(j), elem_var_vals, ierr) write (iout, '("after expev, error = ", i4)' ) ierr 90 continue 100 continue whole_time_step = whole_time_step + 1 c update the data file; this should be done at the end of every time c step to ensure that no data is lost if the analysis dies call exupda (exoid, ierr) write (iout, '("after exupda, error = ", i4)' ) ierr 110 continue c close the EXODUS files call exclos (exoid, ierr) write (iout, '("after exclos, error = ", i4)' ) ierr stop end