void write_exo_mesh(int debug, char *file_name, INT map_origin, INT num_nodes, INT num_elements,
INT num_domains, INT num_nodal_fields, INT num_global_fields,
INT num_element_fields, INT num_timesteps, realtyp *x, realtyp *y, realtyp *z,
INT *connect, int compression_level, int shuffle, int int64bit)
{
int CPU_word_size = sizeof(realtyp);
int IO_word_size = sizeof(realtyp);
int exoid, err, num_dim, num_elem_blk, num_node_sets, num_side_sets;
INT i, j, t, index, loc_num_elements, loc_num_nodes, len_connect;
INT *elem_map = NULL, *node_map = NULL, *domain_connect = NULL, *loc_connect = NULL;
int *elem_var_tab;
INT accum_num_elements = 0;
INT loc_node_size = -1;
realtyp *loc_xcoords = NULL;
realtyp *loc_ycoords = NULL;
realtyp *loc_zcoords = NULL;
realtyp *globals = NULL;
char temporary_name[MAX_STRING_LEN];
char **var_name;
accum_num_elements = 0;
for (i = 0; i < num_domains; i++) {
int mymode = EX_MAPS_INT64_API | EX_BULK_INT64_API | EX_IDS_INT64_API;
if (int64bit) {
mymode |= EX_MAPS_INT64_DB | EX_BULK_INT64_DB | EX_IDS_INT64_DB;
}
/* create the EXODUSII file */
get_file_name(file_name, "e", i, num_domains, NULL, temporary_name);
exoid = ex_create(temporary_name, EX_CLOBBER | mymode, &CPU_word_size, &IO_word_size);
if (exoid < 0) {
fprintf(stderr, "after ex_create, error = %d\n", exoid);
exit(-1);
}
ex_set_option(exoid, EX_OPT_COMPRESSION_LEVEL, compression_level);
ex_set_option(exoid, EX_OPT_COMPRESSION_SHUFFLE, shuffle);
if (num_domains > 1) {
/* Determine local number of elements */
if (num_elements < num_domains) {
fprintf(stderr, "number of elements is less than number of domains.\n");
if (i < num_elements)
loc_num_elements = 1;
else
loc_num_elements = 0;
}
else {
loc_num_elements = num_elements / num_domains;
if (i < (num_elements % num_domains))
loc_num_elements++;
}
len_connect = NUM_NODES_PER_ELEM * loc_num_elements;
/* malloc things we need */
if (i == 0) { /* first time through; max size arrays occur on
first iteration */
elem_map = malloc(loc_num_elements * sizeof(INT));
domain_connect = malloc(len_connect * sizeof(INT));
loc_connect = malloc(len_connect * sizeof(INT));
node_map = malloc(num_nodes * sizeof(INT));
}
/* Create element local/global map */
create_elem_map(loc_num_elements, accum_num_elements, elem_map, map_origin);
/* Extract current domain's connectivity, referencing global node ids */
extract_connect(accum_num_elements, loc_num_elements, elem_map, connect, domain_connect,
map_origin);
accum_num_elements += loc_num_elements;
/* The local/global node map is just the current domain's connectivity,
sorted with duplicate entries removed */
create_node_map(num_nodes, len_connect, domain_connect, node_map, &loc_num_nodes, map_origin);
/* Using local/global node map, convert the domain connectivity
(referencing global node ids) to local connectivity (referencing
local node ids) */
create_local_connect(node_map, loc_num_nodes, len_connect, domain_connect, loc_connect,
map_origin);
}
else {
loc_num_elements = num_elements;
loc_num_nodes = num_nodes;
}
if (debug) {
fprintf(stderr, "\n\n\n");
fprintf(stderr, "\n domain: %" PRId64 "\n", i);
fprintf(stderr, "\n loc_num_elements: %" PRId64 "\n", loc_num_elements);
fprintf(stderr, "\n loc_num_nodes: %" PRId64 "\n", loc_num_nodes);
}
num_dim = 3;
num_elem_blk = 1;
num_node_sets = 0;
num_side_sets = 0;
err = ex_put_init(exoid, "This is an EXODUSII performance test.", num_dim, loc_num_nodes,
loc_num_elements, num_elem_blk, num_node_sets, num_side_sets);
if (err) {
fprintf(stderr, "after ex_put_init, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
/* Extract the local x and y coordinates */
if (num_domains > 1) {
if (loc_num_nodes > loc_node_size) {
loc_xcoords = realloc(loc_xcoords, loc_num_nodes * sizeof(realtyp));
loc_ycoords = realloc(loc_ycoords, loc_num_nodes * sizeof(realtyp));
loc_zcoords = realloc(loc_zcoords, loc_num_nodes * sizeof(realtyp));
loc_node_size = loc_num_nodes;
}
for (j = 0; j < loc_num_nodes; j++) {
index = node_map[j] - map_origin;
loc_xcoords[j] = x[index];
loc_ycoords[j] = y[index];
loc_zcoords[j] = z[index];
}
err = ex_put_coord(exoid, loc_xcoords, loc_ycoords, loc_zcoords);
}
else {
err = ex_put_coord(exoid, x, y, z);
}
if (err) {
fprintf(stderr, "after ex_put_coord, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
if (debug) {
fprintf(stderr, "\tCoordinates output.\n");
}
#if 1
{
INT ids[1] = {EBLK_ID};
INT num_elem_per_block[1];
char *names[1] = {"hex"};
INT num_node_per_elem[1];
INT num_attr_per_block[1];
int write_map = num_domains > 1 ? EX_TRUE : EX_FALSE;
num_elem_per_block[0] = loc_num_elements;
num_node_per_elem[0] = NUM_NODES_PER_ELEM;
num_attr_per_block[0] = 0;
err = ex_put_concat_elem_block(exoid, ids, names, num_elem_per_block, num_node_per_elem,
num_attr_per_block, write_map);
}
#else
err = ex_put_elem_block(exoid, 10000000000, "hex", loc_num_elements, NUM_NODES_PER_ELEM, 0);
#endif
if (err) {
fprintf(stderr, "after ex_put_elem_block, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
if (num_domains > 1) {
err = ex_put_elem_conn(exoid, EBLK_ID, loc_connect);
}
else {
err = ex_put_elem_conn(exoid, EBLK_ID, connect);
}
if (err) {
fprintf(stderr, "after ex_put_elem_conn, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
if (debug) {
fprintf(stderr, "\tConnectivity output.\n");
}
/* write out element and node maps */
if (num_domains > 1) {
err = ex_put_id_map(exoid, EX_NODE_MAP, node_map);
if (err) {
fprintf(stderr, "after ex_put_id_map, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
err = ex_put_id_map(exoid, EX_ELEM_MAP, elem_map);
if (err) {
fprintf(stderr, "after ex_put_id_map, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
if (debug) {
fprintf(stderr, "\tMaps output.\n");
}
}
/* write out simulated results fields;
we'll just write out the x coordinate field 'num_nodal_fields' times */
if (loc_num_nodes < loc_num_elements) {
fprintf(stderr, "INTERNAL ERROR: Programmer assumed number of nodes > number of elements, "
"but that is not true.\n");
ex_close(exoid);
exit(-1);
}
if (num_element_fields > 0) {
elem_var_tab = malloc(num_element_fields * sizeof(int));
for (j = 0; j < num_element_fields; j++)
elem_var_tab[j] = 1;
}
else {
elem_var_tab = 0;
}
err = ex_put_all_var_param(exoid, num_global_fields, num_nodal_fields, num_element_fields,
elem_var_tab, 0, 0, 0, 0);
if (err) {
fprintf(stderr, "after ex_put_all_var_param, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
if (num_nodal_fields > 0) {
var_name = malloc(num_nodal_fields * sizeof(char *));
for (j = 0; j < num_nodal_fields; j++) {
var_name[j] = malloc((MAX_STRING_LEN + 1) * sizeof(char));
sprintf(var_name[j], "node_field_%" PRId64, j + 1);
}
err = ex_put_variable_names(exoid, EX_NODAL, num_nodal_fields, var_name);
for (j = 0; j < num_nodal_fields; j++) {
free(var_name[j]);
}
free(var_name);
}
if (num_global_fields > 0) {
globals = malloc(num_global_fields * sizeof(realtyp));
var_name = malloc(num_global_fields * sizeof(char *));
for (j = 0; j < num_global_fields; j++) {
var_name[j] = malloc((MAX_STRING_LEN + 1) * sizeof(char));
sprintf(var_name[j], "global_field_%" PRId64, j + 1);
globals[j] = j;
}
err = ex_put_variable_names(exoid, EX_GLOBAL, num_global_fields, var_name);
for (j = 0; j < num_global_fields; j++) {
free(var_name[j]);
}
free(var_name);
}
if (num_element_fields > 0) {
free(elem_var_tab);
var_name = malloc(num_element_fields * sizeof(char *));
for (j = 0; j < num_element_fields; j++) {
var_name[j] = malloc((MAX_STRING_LEN + 1) * sizeof(char));
sprintf(var_name[j], "element_field_%" PRId64, j + 1);
}
err = ex_put_variable_names(exoid, EX_ELEM_BLOCK, num_element_fields, var_name);
for (j = 0; j < num_element_fields; j++) {
free(var_name[j]);
}
free(var_name);
}
if (num_nodal_fields + num_global_fields + num_element_fields > 0) {
fprintf(stderr, "Domain %" PRId64 "/%" PRId64 ", Writing Timestep: ", i + 1, num_domains);
for (t = 0; t < num_timesteps; t++) {
realtyp time = t;
ex_put_time(exoid, t + 1, &time);
fprintf(stderr, "%" PRId64 ", ", t + 1);
if (num_global_fields > 0) {
err = ex_put_var(exoid, t + 1, EX_GLOBAL, 1, 0, num_global_fields, globals);
if (err) {
fprintf(stderr, "after ex_put_global_var, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
}
for (j = 0; j < num_nodal_fields; j++) {
err = ex_put_var(exoid, t + 1, EX_NODAL, j + 1, 0, loc_num_nodes, x);
if (err) {
fprintf(stderr, "after ex_put_nodal_var, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
}
for (j = 0; j < num_element_fields; j++) {
err = ex_put_var(exoid, t + 1, EX_ELEM_BLOCK, j + 1, EBLK_ID, loc_num_elements, x);
if (err) {
fprintf(stderr, "after ex_put_element_var, error = %d\n", err);
ex_close(exoid);
exit(-1);
}
}
}
fprintf(stderr, "\n");
}
err = ex_close(exoid);
if (err) {
fprintf(stderr, "after ex_close, error = %d\n", err);
exit(-1);
}
if (debug) {
fprintf(stderr, "\tFile written.\n");
}
}
/*
* Free Memory
*/
if (num_domains > 1) {
free(domain_connect);
free(elem_map);
free(loc_connect);
free(loc_xcoords);
free(loc_ycoords);
free(loc_zcoords);
free(node_map);
}
if (num_global_fields > 0)
free(globals);
}
int main (int argc, char **argv)
{
int exoid, num_dim, num_nodes, num_elem, num_elem_blk;
int num_elem_in_block[10], num_nodes_per_elem[10];
int num_node_sets, num_side_sets, error;
int i, j, k, kk, m, *elem_map, *connect;
int node_list[100],elem_list[100],side_list[100];
int ebids[10], ssids[10], nsids[10], nattr[10];
int num_nodes_per_set[10], num_elem_per_set[10];
int num_df_per_set[10];
int num_qa_rec, num_info;
int num_glo_vars, num_nod_vars, num_ele_vars, num_nset_vars, num_sset_vars;
int *truth_tab, *nset_tab, *sset_tab;
int whole_time_step, num_time_steps;
int CPU_word_size,IO_word_size;
int prop_array[2];
float *glob_var_vals, *nodal_var_vals, *elem_var_vals, *nset_var_vals, *sset_var_vals;
float time_value;
float x[100], y[100], z[100];
float attrib[1], dist_fact[100];
char *coord_names[3], *qa_record[2][4], *info[3], *var_names[7];
char *prop_names[2];
char *eb_type[10];
ex_opts (EX_VERBOSE|EX_ABORT);
/* Specify compute and i/o word size */
CPU_word_size = 0; /* sizeof(float) */
IO_word_size = 4; /* (4 bytes) */
/* create EXODUS II file */
exoid = ex_create ("test.exo", /* filename path */
EX_CLOBBER, /* create mode */
&CPU_word_size, /* CPU float word size in bytes */
&IO_word_size); /* I/O float word size in bytes */
printf ("after ex_create for test.exo, exoid = %d\n", exoid);
printf (" cpu word size: %d io word size: %d\n",CPU_word_size,IO_word_size);
/* ncopts = NC_VERBOSE; */
/* initialize file with parameters */
num_dim = 3;
num_nodes = 33;
num_elem = 7;
num_elem_blk = 7;
num_node_sets = 2;
num_side_sets = 5;
error = ex_put_init (exoid, "This is a test", num_dim, num_nodes, num_elem,
num_elem_blk, num_node_sets, num_side_sets);
printf ("after ex_put_init, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write nodal coordinates values and names to database */
/* Quad #1 */
x[0] = 0.0; y[0] = 0.0; z[0] = 0.0;
x[1] = 1.0; y[1] = 0.0; z[1] = 0.0;
x[2] = 1.0; y[2] = 1.0; z[2] = 0.0;
x[3] = 0.0; y[3] = 1.0; z[3] = 0.0;
/* Quad #2 */
x[4] = 1.0; y[4] = 0.0; z[4] = 0.0;
x[5] = 2.0; y[5] = 0.0; z[5] = 0.0;
x[6] = 2.0; y[6] = 1.0; z[6] = 0.0;
x[7] = 1.0; y[7] = 1.0; z[7] = 0.0;
/* Hex #1 */
x[8] = 0.0; y[8] = 0.0; z[8] = 0.0;
x[9] = 10.0; y[9] = 0.0; z[9] = 0.0;
x[10] = 10.0; y[10] = 0.0; z[10] =-10.0;
x[11] = 1.0; y[11] = 0.0; z[11] =-10.0;
x[12] = 1.0; y[12] = 10.0; z[12] = 0.0;
x[13] = 10.0; y[13] = 10.0; z[13] = 0.0;
x[14] = 10.0; y[14] = 10.0; z[14] =-10.0;
x[15] = 1.0; y[15] = 10.0; z[15] =-10.0;
/* Tetra #1 */
x[16] = 0.0; y[16] = 0.0; z[16] = 0.0;
x[17] = 1.0; y[17] = 0.0; z[17] = 5.0;
x[18] = 10.0; y[18] = 0.0; z[18] = 2.0;
x[19] = 7.0; y[19] = 5.0; z[19] = 3.0;
/* Wedge #1 */
x[20] = 3.0; y[20] = 0.0; z[20] = 6.0;
x[21] = 6.0; y[21] = 0.0; z[21] = 0.0;
x[22] = 0.0; y[22] = 0.0; z[22] = 0.0;
x[23] = 3.0; y[23] = 2.0; z[23] = 6.0;
x[24] = 6.0; y[24] = 2.0; z[24] = 2.0;
x[25] = 0.0; y[25] = 2.0; z[25] = 0.0;
/* Tetra #2 */
x[26] = 2.7; y[26] = 1.7; z[26] = 2.7;
x[27] = 6.0; y[27] = 1.7; z[27] = 3.3;
x[28] = 5.7; y[28] = 1.7; z[28] = 1.7;
x[29] = 3.7; y[29] = 0.0; z[29] = 2.3;
/* 3d Tri */
x[30] = 0.0; y[30] = 0.0; z[30] = 0.0;
x[31] = 10.0; y[31] = 0.0; z[31] = 0.0;
x[32] = 10.0; y[32] = 10.0; z[32] = 10.0;
error = ex_put_coord (exoid, x, y, z);
printf ("after ex_put_coord, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
coord_names[0] = "xcoor";
coord_names[1] = "ycoor";
coord_names[2] = "zcoor";
error = ex_put_coord_names (exoid, coord_names);
printf ("after ex_put_coord_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write element order map */
elem_map = (int *) calloc(num_elem, sizeof(int));
for (i=1; i<=num_elem; i++)
{
elem_map[i-1] = i;
}
error = ex_put_map (exoid, elem_map);
printf ("after ex_put_map, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
free (elem_map);
/* write element block parameters */
num_elem_in_block[0] = 1;
num_elem_in_block[1] = 1;
num_elem_in_block[2] = 1;
num_elem_in_block[3] = 1;
num_elem_in_block[4] = 1;
num_elem_in_block[5] = 1;
num_elem_in_block[6] = 1;
num_nodes_per_elem[0] = 4; /* elements in block #1 are 4-node quads */
num_nodes_per_elem[1] = 4; /* elements in block #2 are 4-node quads */
num_nodes_per_elem[2] = 8; /* elements in block #3 are 8-node hexes */
num_nodes_per_elem[3] = 4; /* elements in block #4 are 4-node tetras */
num_nodes_per_elem[4] = 6; /* elements in block #5 are 6-node wedges */
num_nodes_per_elem[5] = 8; /* elements in block #6 are 8-node tetras */
num_nodes_per_elem[6] = 3; /* elements in block #7 are 3-node tris */
ebids[0] = 10;
ebids[1] = 11;
ebids[2] = 12;
ebids[3] = 13;
ebids[4] = 14;
ebids[5] = 15;
ebids[6] = 16;
nattr[0] = nattr[1] = nattr[2] = nattr[3] = 1;
nattr[4] = nattr[5] = nattr[6] = 1;
eb_type[0] = "quad";
eb_type[1] = "quad";
eb_type[2] = "hex";
eb_type[3] = "tetra";
eb_type[4] = "wedge";
eb_type[5] = "tetra";
eb_type[6] = "tri";
error = ex_put_concat_elem_block (exoid, ebids, eb_type,
num_elem_in_block, num_nodes_per_elem,
nattr, 0);
printf ("after ex_put_concat_elem_block, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write element block properties */
prop_names[0] = "MATL";
prop_names[1] = "DENSITY";
error = ex_put_prop_names(exoid,EX_ELEM_BLOCK,2,prop_names);
printf ("after ex_put_prop_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[0], "MATL", 10);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[1], "MATL", 20);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[2], "MATL", 30);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[3], "MATL", 40);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[4], "MATL", 50);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[5], "MATL", 60);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_ELEM_BLOCK, ebids[6], "MATL", 70);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write element connectivity */
connect = (int *) calloc(8, sizeof(int));
connect[0] = 1; connect[1] = 2; connect[2] = 3; connect[3] = 4;
error = ex_put_elem_conn (exoid, ebids[0], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
connect[0] = 5; connect[1] = 6; connect[2] = 7; connect[3] = 8;
error = ex_put_elem_conn (exoid, ebids[1], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
connect[0] = 9; connect[1] = 10; connect[2] = 11; connect[3] = 12;
connect[4] = 13; connect[5] = 14; connect[6] = 15; connect[7] = 16;
error = ex_put_elem_conn (exoid, ebids[2], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
connect[0] = 17; connect[1] = 18; connect[2] = 19; connect[3] = 20;
error = ex_put_elem_conn (exoid, ebids[3], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
connect[0] = 21; connect[1] = 22; connect[2] = 23;
connect[3] = 24; connect[4] = 25; connect[5] = 26;
error = ex_put_elem_conn (exoid, ebids[4], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
connect[0] = 17; connect[1] = 18; connect[2] = 19; connect[3] = 20;
connect[4] = 27; connect[5] = 28; connect[6] = 30; connect[7] = 29;
error = ex_put_elem_conn (exoid, ebids[5], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
connect[0] = 31; connect[1] = 32; connect[2] = 33;
error = ex_put_elem_conn (exoid, ebids[6], connect);
printf ("after ex_put_elem_conn, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
free (connect);
/* write element block attributes */
attrib[0] = 3.14159;
error = ex_put_elem_attr (exoid, ebids[0], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
attrib[0] = 6.14159;
error = ex_put_elem_attr (exoid, ebids[1], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_elem_attr (exoid, ebids[2], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_elem_attr (exoid, ebids[3], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_elem_attr (exoid, ebids[4], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_elem_attr (exoid, ebids[5], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_elem_attr (exoid, ebids[6], attrib);
printf ("after ex_put_elem_attr, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write individual node sets */
nsids[0] = 20; nsids[1] = 21;
num_nodes_per_set[0] = 5; num_nodes_per_set[1] = 3;
num_df_per_set[0] = 5; num_df_per_set[1] = 3;
error = ex_put_concat_node_sets (exoid, nsids, num_nodes_per_set,
num_df_per_set, 0, 0, 0, 0);
printf ("after ex_put_concat_node_sets, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
node_list[0] = 10; node_list[1] = 11; node_list[2] = 12;
node_list[3] = 13; node_list[4] = 14;
dist_fact[0] = 1.0; dist_fact[1] = 2.0; dist_fact[2] = 3.0;
dist_fact[3] = 4.0; dist_fact[4] = 5.0;
error = ex_put_node_set (exoid, 20, node_list);
printf ("after ex_put_node_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_node_set_dist_fact (exoid, 20, dist_fact);
printf ("after ex_put_node_set_dist_fact, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
node_list[0] = 20; node_list[1] = 21; node_list[2] = 22;
dist_fact[0] = 1.1; dist_fact[1] = 2.1; dist_fact[2] = 3.1;
error = ex_put_node_set (exoid, 21, node_list);
printf ("after ex_put_node_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_node_set_dist_fact (exoid, 21, dist_fact);
printf ("after ex_put_node_set_dist_fact, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_NODE_SET, 20, "FACE", 4);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_NODE_SET, 21, "FACE", 5);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
prop_array[0] = 1000;
prop_array[1] = 2000;
error = ex_put_prop_array(exoid, EX_NODE_SET, "VELOCITY", prop_array);
printf ("after ex_put_prop_array, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* Define the sideset params at one time, then write individually */
ssids[0] = 30;
ssids[1] = 31;
ssids[2] = 32;
ssids[3] = 33;
ssids[4] = 34;
num_elem_per_set[0] = 2;
num_elem_per_set[1] = 2;
num_elem_per_set[2] = 7;
num_elem_per_set[3] = 8;
num_elem_per_set[4] = 10;
num_df_per_set[0] = 4;
num_df_per_set[1] = 4;
num_df_per_set[2] = 0;
num_df_per_set[3] = 0;
num_df_per_set[4] = 0;
error = ex_put_concat_side_sets (exoid, ssids, num_elem_per_set,
num_df_per_set, 0, 0, 0, 0, 0);
printf ("after ex_put_concat_side_sets, error = %d\n", error);
/* write individual side sets */
/* side set #1 - quad */
elem_list[0] = 2; elem_list[1] = 2;
side_list[0] = 4; side_list[1] = 2;
dist_fact[0] = 30.0; dist_fact[1] = 30.1; dist_fact[2] = 30.2;
dist_fact[3] = 30.3;
error = ex_put_side_set (exoid, 30, elem_list, side_list);
printf ("after ex_put_side_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_side_set_dist_fact (exoid, 30, dist_fact);
printf ("after ex_put_side_set_dist_fact, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* side set #2 - quad, spanning 2 elements */
elem_list[0] = 1; elem_list[1] = 2;
side_list[0] = 2; side_list[1] = 3;
dist_fact[0] = 31.0; dist_fact[1] = 31.1; dist_fact[2] = 31.2;
dist_fact[3] = 31.3;
error = ex_put_side_set (exoid, 31, elem_list, side_list);
printf ("after ex_put_side_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_side_set_dist_fact (exoid, 31, dist_fact);
printf ("after ex_put_side_set_dist_fact, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* side set #3 - hex */
elem_list[0] = 3; elem_list[1] = 3;
elem_list[2] = 3; elem_list[3] = 3;
elem_list[4] = 3; elem_list[5] = 3;
elem_list[6] = 3;
side_list[0] = 5; side_list[1] = 3;
side_list[2] = 3; side_list[3] = 2;
side_list[4] = 4; side_list[5] = 1;
side_list[6] = 6;
error = ex_put_side_set (exoid, 32, elem_list, side_list);
printf ("after ex_put_side_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* side set #4 - tetras */
elem_list[0] = 4; elem_list[1] = 4;
elem_list[2] = 4; elem_list[3] = 4;
elem_list[4] = 6; elem_list[5] = 6;
elem_list[6] = 6; elem_list[7] = 6;
side_list[0] = 1; side_list[1] = 2;
side_list[2] = 3; side_list[3] = 4;
side_list[4] = 1; side_list[5] = 2;
side_list[6] = 3; side_list[7] = 4;
error = ex_put_side_set (exoid, 33, elem_list, side_list);
printf ("after ex_put_side_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* side set #5 - wedges and tris */
elem_list[0] = 5; elem_list[1] = 5;
elem_list[2] = 5; elem_list[3] = 5;
elem_list[4] = 5; elem_list[5] = 7;
elem_list[6] = 7; elem_list[7] = 7;
elem_list[8] = 7; elem_list[9] = 7;
side_list[0] = 1; side_list[1] = 2;
side_list[2] = 3; side_list[3] = 4;
side_list[4] = 5; side_list[5] = 1;
side_list[6] = 2; side_list[7] = 3;
side_list[8] = 4; side_list[9] = 5;
error = ex_put_side_set (exoid, 34, elem_list, side_list);
printf ("after ex_put_side_set, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_SIDE_SET, 30, "COLOR", 100);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
error = ex_put_prop(exoid, EX_SIDE_SET, 31, "COLOR", 101);
printf ("after ex_put_prop, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write QA records; test empty and just blank-filled records */
num_qa_rec = 2;
qa_record[0][0] = "TESTWT";
qa_record[0][1] = "testwt";
qa_record[0][2] = "07/07/93";
qa_record[0][3] = "15:41:33";
qa_record[1][0] = "";
qa_record[1][1] = " ";
qa_record[1][2] = "";
qa_record[1][3] = " ";
error = ex_put_qa (exoid, num_qa_rec, qa_record);
printf ("after ex_put_qa, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write information records; test empty and just blank-filled records */
num_info = 3;
info[0] = "This is the first information record.";
info[1] = "";
info[2] = " ";
error = ex_put_info (exoid, num_info, info);
printf ("after ex_put_info, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write results variables parameters and names */
num_glo_vars = 1;
num_nod_vars = 2;
num_ele_vars = 3;
num_nset_vars = 4;
num_sset_vars = 7;
truth_tab = (int *) calloc ((num_elem_blk * num_ele_vars), sizeof(int));
nset_tab = (int *) calloc ((num_node_sets * num_nset_vars), sizeof(int));
sset_tab = (int *) calloc ((num_side_sets * num_sset_vars), sizeof(int));
k = 0;
for (i=0; i<num_elem_blk; i++) {
for (j=0; j<num_ele_vars; j++) {
truth_tab[k++] = 1;
}
}
k = 0;
for (i=0; i<num_node_sets; i++) {
for (j=0; j<num_nset_vars; j++) {
if (k%2 == 0)
nset_tab[k++] = 1;
else
nset_tab[k++] = 0;
}
}
k = 0;
for (i=0; i<num_side_sets; i++) {
for (j=0; j<num_sset_vars; j++) {
if (k%2 == 0)
sset_tab[k++] = 0;
else
sset_tab[k++] = 1;
}
}
ex_put_all_var_param(exoid, num_glo_vars, num_nod_vars, num_ele_vars, truth_tab,
num_nset_vars, nset_tab, num_sset_vars, sset_tab);
printf ("after ex_put_all_var_param, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
free (truth_tab);
free (nset_tab);
free (sset_tab);
var_names[0] = "glo_vars";
error = ex_put_var_names (exoid, "g", num_glo_vars, var_names);
printf ("after ex_put_var_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* 12345678901234567890123456789012 */
var_names[0] = "node_variable_a_very_long_name_0";
var_names[1] = "nod_var1";
error = ex_put_var_names (exoid, "n", num_nod_vars, var_names);
printf ("after ex_put_var_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
var_names[0] = "ele_var0";
var_names[1] = "ele_var1";
var_names[2] = "ele_var2";
error = ex_put_var_names (exoid, "e", num_ele_vars, var_names);
printf ("after ex_put_var_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
var_names[0] = "nset_var0";
var_names[1] = "nset_var1";
var_names[2] = "nset_var2";
var_names[3] = "nset_var3";
error = ex_put_var_names (exoid, "m", num_nset_vars, var_names);
printf ("after ex_put_var_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
var_names[0] = "sset_var0";
var_names[1] = "sset_var1";
var_names[2] = "sset_var2";
var_names[3] = "sset_var3";
var_names[4] = "sset_var4";
var_names[5] = "sset_var5";
var_names[6] = "sset_var6";
error = ex_put_var_names (exoid, "s", num_sset_vars, var_names);
printf ("after ex_put_var_names, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* for each time step, write the analysis results;
* the code below fills the arrays glob_var_vals,
* nodal_var_vals, and elem_var_vals with values for debugging purposes;
* obviously the analysis code will populate these arrays
*/
whole_time_step = 1;
num_time_steps = 10;
glob_var_vals = (float *) calloc (num_glo_vars, CPU_word_size);
nodal_var_vals = (float *) calloc (num_nodes, CPU_word_size);
elem_var_vals = (float *) calloc (4, CPU_word_size);
nset_var_vals = (float *) calloc (5, CPU_word_size);
sset_var_vals = (float *) calloc (10, CPU_word_size);
for (i=0; i<num_time_steps; i++)
{
time_value = (float)(i+1)/100.;
/* write time value */
error = ex_put_time (exoid, whole_time_step, &time_value);
printf ("after ex_put_time, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write global variables */
for (j=0; j<num_glo_vars; j++) {
glob_var_vals[j] = (float)(j+2) * time_value;
}
error = ex_put_glob_vars (exoid, whole_time_step, num_glo_vars,
glob_var_vals);
printf ("after ex_put_glob_vars, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
/* write nodal variables */
for (k=1; k<=num_nod_vars; k++) {
for (j=0; j<num_nodes; j++) {
nodal_var_vals[j] = (float)k + ((float)(j+1) * time_value);
}
error = ex_put_nodal_var (exoid, whole_time_step, k, num_nodes,
nodal_var_vals);
printf ("after ex_put_nodal_var, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
}
/* write element variables */
for (k=1; k<=num_ele_vars; k++) {
for (j=0; j<num_elem_blk; j++) {
for (m=0; m<num_elem_in_block[j]; m++) {
elem_var_vals[m] = (float)(k+1) + (float)(j+2) +
((float)(m+1)*time_value);
}
error = ex_put_elem_var (exoid, whole_time_step, k, ebids[j],
num_elem_in_block[j], elem_var_vals);
printf ("after ex_put_elem_var, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
}
}
/* write nodeset variables */
kk = 0;
for (j=0; j<num_node_sets; j++) {
for (k=0; k<num_nset_vars; k++) {
if (kk++ % 2 == 0) {
for (m=0; m<num_nodes_per_set[j]; m++) {
nset_var_vals[m] = (float)(k+1) + (float)(j+2) +
((float)(m+1)*time_value);
}
error = ex_put_nset_var (exoid, whole_time_step, k+1, nsids[j],
num_nodes_per_set[j], nset_var_vals);
printf ("after ex_put_nset_var, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
}
}
}
/* write sideset variables */
kk = 0;
for (j=0; j<num_side_sets; j++) {
for (k=0; k<num_sset_vars; k++) {
if (kk++ % 2 != 0) {
for (m=0; m<num_elem_per_set[j]; m++) {
sset_var_vals[m] = (float)(k+1) + (float)(j+2) +
((float)(m+1)*time_value);
}
error = ex_put_sset_var (exoid, whole_time_step, k+1, ssids[j],
num_elem_per_set[j], sset_var_vals);
printf ("after ex_put_sset_var, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
}
}
}
whole_time_step++;
/* update the data file; this should be done at the end of every time step
* to ensure that no data is lost if the analysis dies
*/
error = ex_update (exoid);
printf ("after ex_update, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
}
free(glob_var_vals);
free(nodal_var_vals);
free(elem_var_vals);
free(nset_var_vals);
free(sset_var_vals);
/* close the EXODUS files
*/
error = ex_close (exoid);
printf ("after ex_close, error = %d\n", error);
if (error) {
ex_close (exoid);
exit(-1);
}
return 0;
}