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-rw-r--r--src/cracked_voronoi_fracture.c427
1 files changed, 427 insertions, 0 deletions
diff --git a/src/cracked_voronoi_fracture.c b/src/cracked_voronoi_fracture.c
new file mode 100644
index 0000000..532c3c3
--- /dev/null
+++ b/src/cracked_voronoi_fracture.c
@@ -0,0 +1,427 @@
+
+
+#include "fracture.h"
+
+int main(int argc, char *argv[]) {
+ int opt;
+
+ // defining variables to be (potentially) set by command line flags
+ uint8_t filename_len;
+ uint32_t N;
+ uint_t L;
+ double beta, inf, cutoff, crack_len;
+ bool include_breaking, save_cluster_dist, use_voltage_boundaries, use_dual, save_network,
+ save_crit_stress, save_stress_field, save_voltage_field, save_toughness, save_conductivity,
+ save_damage, save_damage_field;
+ bound_t boundary;
+
+ filename_len = 100;
+
+ N = 100;
+ L = 16;
+ crack_len = 0.;
+ beta = .3;
+ inf = 1e10;
+ cutoff = 1e-9;
+ boundary = FREE_BOUND;
+ include_breaking = false;
+ save_cluster_dist = false;
+ use_voltage_boundaries = false;
+ use_dual = false;
+ save_network = false;
+ save_crit_stress = false;
+ save_stress_field = false;
+ save_voltage_field = false;
+ save_damage = false;
+ save_damage_field = false;
+ save_conductivity = false;
+ save_toughness = false;
+
+ uint8_t bound_i;
+ char boundc2 = 'f';
+
+ while ((opt = getopt(argc, argv, "n:L:b:B:dVcoNsCrtDSvel:")) != -1) {
+ switch (opt) {
+ case 'n':
+ N = atoi(optarg);
+ break;
+ case 'L':
+ L = atoi(optarg);
+ break;
+ case 'b':
+ beta = atof(optarg);
+ break;
+ case 'l':
+ crack_len = atof(optarg);
+ break;
+ case 'B':
+ bound_i = atoi(optarg);
+ switch (bound_i) {
+ case 0:
+ boundary = FREE_BOUND;
+ boundc2 = 'f';
+ break;
+ case 1:
+ boundary = CYLINDER_BOUND;
+ boundc2 = 'c';
+ break;
+ case 2:
+ boundary = TORUS_BOUND;
+ use_voltage_boundaries = true;
+ boundc2 = 't';
+ break;
+ case 3:
+ boundary = EMBEDDED_BOUND;
+ boundc2 = 'e';
+ use_dual = true;
+ use_voltage_boundaries = true;
+ break;
+ default:
+ printf("boundary specifier must be 0 (FREE_BOUND), 1 (CYLINDER_BOUND), or 2 (TORUS_BOUND).\n");
+ exit(EXIT_FAILURE);
+ }
+ break;
+ case 'd':
+ save_damage = true;
+ break;
+ case 'e':
+ save_damage_field = true;
+ break;
+ case 'V':
+ use_voltage_boundaries = true;
+ break;
+ case 'D':
+ use_dual = true;
+ break;
+ case 'c':
+ save_cluster_dist = true;
+ break;
+ case 'o':
+ include_breaking = true;
+ break;
+ case 'N':
+ save_network = true;
+ break;
+ case 's':
+ save_crit_stress = true;
+ break;
+ case 'S':
+ save_stress_field = true;
+ break;
+ case 'v':
+ save_voltage_field = true;
+ break;
+ case 'r':
+ save_conductivity = true;
+ //inf = 1;
+ break;
+ case 't':
+ save_toughness = true;
+ break;
+ default: /* '?' */
+ exit(EXIT_FAILURE);
+ }
+ }
+
+ char boundc;
+ if (use_voltage_boundaries) boundc = 'v';
+ else boundc = 'c';
+
+ FILE *break_out;
+ if (include_breaking) {
+ char *break_filename = (char *)malloc(filename_len * sizeof(char));
+ snprintf(break_filename, filename_len, "breaks_v_%c_%c_%u_%g.txt", boundc, boundc2, L, beta);
+ break_out = fopen(break_filename, "a");
+ free(break_filename);
+ }
+
+ uint_t voronoi_max_verts, c_dist_size, a_dist_size;
+
+ voronoi_max_verts = 4 * pow(L, 2);
+ c_dist_size = voronoi_max_verts;
+ a_dist_size = voronoi_max_verts;
+
+ if (voronoi_max_verts > CINT_MAX) {
+ exit(EXIT_FAILURE);
+ }
+
+ // define arrays for saving cluster and avalanche distributions
+ uint32_t *cluster_size_dist;
+ uint32_t *avalanche_size_dist;
+ char *c_filename;
+ char *a_filename;
+ if (save_cluster_dist) {
+ cluster_size_dist =
+ (uint32_t *)malloc(c_dist_size * sizeof(uint32_t));
+ avalanche_size_dist =
+ (uint32_t *)malloc(a_dist_size * sizeof(uint32_t));
+
+ c_filename = (char *)malloc(filename_len * sizeof(char));
+ a_filename = (char *)malloc(filename_len * sizeof(char));
+ snprintf(c_filename, filename_len, "cstr_v_%c_%c_%d_%g.dat", boundc, boundc2, L, beta);
+ snprintf(a_filename, filename_len, "avln_v_%c_%c_%d_%g.dat", boundc, boundc2, L, beta);
+
+ FILE *cluster_out = fopen(c_filename, "rb");
+ FILE *avalanche_out = fopen(a_filename, "rb");
+
+ if (cluster_out != NULL) {
+ fread(cluster_size_dist, sizeof(uint32_t), c_dist_size, cluster_out);
+ fclose(cluster_out);
+ }
+ if (avalanche_out != NULL) {
+ fread(avalanche_size_dist, sizeof(uint32_t), a_dist_size, avalanche_out);
+ fclose(avalanche_out);
+ }
+ }
+
+ double *crit_stress;
+ if (save_crit_stress) {
+ crit_stress = (double *)malloc(N * sizeof(double));
+ }
+
+ double *conductivity;
+ if (save_conductivity) {
+ conductivity = (double *)malloc(N * sizeof(double));
+ }
+
+ // define arrays for saving damage distributions
+ uint32_t *damage;
+ char *d_filename;
+ if (save_damage) {
+ damage =
+ (uint32_t *)malloc(a_dist_size * sizeof(uint32_t));
+
+ d_filename = (char *)malloc(filename_len * sizeof(char));
+ snprintf(d_filename, filename_len, "damg_v_%c_%c_%d_%g.dat", boundc, boundc2, L, beta);
+
+ FILE *damage_out = fopen(d_filename, "rb");
+
+ if (damage_out != NULL) {
+ fread(damage, sizeof(uint32_t), a_dist_size, damage_out);
+ fclose(damage_out);
+ }
+ }
+
+ double *toughness;
+ if (save_toughness) {
+ toughness = (double *)malloc(N * sizeof(double));
+ }
+
+
+ // start cholmod
+ cholmod_common c;
+ CHOL_F(start)(&c);
+
+ /* if we use voltage boundary conditions, the laplacian matrix is positive
+ * definite and we can use a supernodal LL decomposition. otherwise we need
+ * to use the simplicial LDL decomposition
+ */
+ if (use_voltage_boundaries) {
+ //(&c)->supernodal = CHOLMOD_SUPERNODAL;
+ (&c)->supernodal = CHOLMOD_SIMPLICIAL;
+ } else {
+ (&c)->supernodal = CHOLMOD_SIMPLICIAL;
+ }
+
+
+ printf("\n");
+ for (uint32_t i = 0; i < N; i++) {
+ printf("\033[F\033[JFRACTURE: %0*d / %d\n", (uint8_t)log10(N) + 1, i + 1, N);
+
+ fnet *network = ini_voronoi_network(L, boundary, use_dual, genfunc_hyperuniform, &c);
+ finst *perm_instance = create_instance(network, inf, use_voltage_boundaries, false, &c);
+ if (boundary == EMBEDDED_BOUND) {
+ voronoi_bound_ini(perm_instance, L, crack_len);
+ }
+ gen_voro_crack(perm_instance, crack_len, &c);
+ finish_instance(perm_instance, &c);
+ double *fuse_thres = gen_fuse_thres(network->num_edges, network->edge_coords, beta, beta_scaling_flat);
+ finst *instance = copy_instance(perm_instance, &c);
+ break_data *breaking_data = fracture_network(instance, fuse_thres, &c, cutoff);
+ free_instance(instance, &c);
+ free(fuse_thres);
+
+ uint_t max_pos = 0;
+ double max_val = 0;
+
+ for (uint_t j = 0; j < breaking_data->num_broken; j++) {
+ double val = breaking_data->extern_field[j];
+
+ if (val > max_val) {
+ max_pos = j;
+ max_val = val;
+ }
+ }
+
+ if (save_crit_stress) {
+ crit_stress[i] =
+ breaking_data->extern_field[max_pos];
+ }
+
+ finst *tmp_instance = copy_instance(perm_instance, &c);
+
+ uint_t av_size = 0;
+ double cur_val = 0;
+ for (uint_t j = 0; j < max_pos; j++) {
+ break_edge(tmp_instance, breaking_data->break_list[j], &c);
+
+ double val = breaking_data->extern_field[j];
+ if (save_cluster_dist) {
+ if (val < cur_val) {
+ av_size++;
+ }
+
+ if (val > cur_val) {
+ avalanche_size_dist[av_size]++;
+ av_size = 0;
+ cur_val = val;
+ }
+ }
+ }
+
+ if (save_conductivity) {
+ if (!use_voltage_boundaries) {
+ double *tmp_voltage = get_voltage(tmp_instance, &c);
+ conductivity[i] = 1/fabs(tmp_voltage[tmp_instance->network->num_verts + 1] - tmp_voltage[tmp_instance->network->num_verts]);
+ free(tmp_voltage);
+ } else {
+ conductivity[i] = breaking_data->conductivity[max_pos];
+ }
+ }
+
+ if (save_toughness) {
+ double tmp_toughness = 0;
+ if (max_pos > 0) {
+ double sigma1 = breaking_data->extern_field[0];
+ double epsilon1 = sigma1 / breaking_data->conductivity[0];
+ for (uint_t j = 0; j < max_pos - 1; j++) {
+ double sigma2 = breaking_data->extern_field[j+1];
+ double epsilon2 = sigma2 / breaking_data->conductivity[j+1];
+ if (epsilon2 > epsilon1) {
+ tmp_toughness += (sigma1 + sigma2) * (epsilon2 - epsilon1) / 2;
+ sigma1 = sigma2; epsilon1 = epsilon2;
+ }
+ }
+ }
+ toughness[i] = tmp_toughness;
+ }
+
+ if (save_damage) {
+ damage[max_pos]++;
+ }
+
+ if (save_cluster_dist) {
+ uint_t *tmp_cluster_dist = get_cluster_dist(tmp_instance, &c);
+ for (uint_t j = 0; j < tmp_instance->network->num_dual_verts; j++) {
+ cluster_size_dist[j] += tmp_cluster_dist[j];
+ }
+ free(tmp_cluster_dist);
+ }
+
+ if (save_network) {
+ FILE *net_out = fopen("network.txt", "w");
+ for (uint_t j = 0; j < network->num_verts; j++) {
+ fprintf(net_out, "%f %f ", network->vert_coords[2 * j],
+ tmp_instance->network->vert_coords[2 * j + 1]);
+ }
+ fprintf(net_out, "\n");
+ for (uint_t j = 0; j < tmp_instance->network->num_edges; j++) {
+ fprintf(net_out, "%u %u ", tmp_instance->network->edges_to_verts[2 * j],
+ tmp_instance->network->edges_to_verts[2 * j + 1]);
+ }
+ fprintf(net_out, "\n");
+ for (uint_t j = 0; j < tmp_instance->network->num_dual_verts; j++) {
+ fprintf(net_out, "%f %f ", tmp_instance->network->dual_vert_coords[2 * j],
+ tmp_instance->network->dual_vert_coords[2 * j + 1]);
+ }
+ fprintf(net_out, "\n");
+ for (uint_t j = 0; j < tmp_instance->network->num_edges; j++) {
+ fprintf(net_out, "%u %u ", tmp_instance->network->dual_edges_to_verts[2 * j],
+ tmp_instance->network->dual_edges_to_verts[2 * j + 1]);
+ }
+ fprintf(net_out, "\n");
+ for (uint_t j = 0; j < tmp_instance->network->num_edges; j++) {
+ fprintf(net_out, "%d ", tmp_instance->fuses[j]);
+ }
+ fclose(net_out);
+ }
+
+ free_instance(tmp_instance, &c);
+ free_instance(perm_instance, &c);
+ free_fnet(network, &c);
+
+ if (include_breaking) {
+ for (uint_t j = 0; j < breaking_data->num_broken; j++) {
+ fprintf(break_out, "%u %g %g ", breaking_data->break_list[j],
+ breaking_data->extern_field[j], breaking_data->conductivity[j]);
+ }
+ fprintf(break_out, "\n");
+ }
+
+ free_break_data(breaking_data);
+ }
+
+ printf("\033[F\033[JFRACTURE: COMPLETE\n");
+
+ if (save_cluster_dist) {
+ FILE *cluster_out = fopen(c_filename, "wb");
+ FILE *avalanche_out = fopen(a_filename, "wb");
+
+ fwrite(cluster_size_dist, sizeof(uint32_t), c_dist_size, cluster_out);
+ fwrite(avalanche_size_dist, sizeof(uint32_t), a_dist_size, avalanche_out);
+
+ fclose(cluster_out);
+ fclose(avalanche_out);
+
+ free(c_filename);
+ free(a_filename);
+ free(cluster_size_dist);
+ free(avalanche_size_dist);
+ }
+
+ if (save_conductivity) {
+ char *cond_filename = (char *)malloc(filename_len * sizeof(char));
+ snprintf(cond_filename, filename_len, "cond_v_%c_%c_%d_%g.dat", boundc, boundc2, L, beta);
+ FILE *cond_file = fopen(cond_filename, "ab");
+ fwrite(conductivity, sizeof(double), N, cond_file);
+ fclose(cond_file);
+ free(cond_filename);
+ free(conductivity);
+ }
+
+ if (save_toughness) {
+ char *tough_filename = (char *)malloc(filename_len * sizeof(char));
+ snprintf(tough_filename, filename_len, "tuff_v_%c_%c_%d_%g.dat", boundc, boundc2, L, beta);
+ FILE *tough_file = fopen(tough_filename, "ab");
+ fwrite(toughness, sizeof(double), N, tough_file);
+ fclose(tough_file);
+ free(tough_filename);
+ free(toughness);
+ }
+
+ if (save_damage) {
+ FILE *hdam_file = fopen(d_filename, "wb");
+ fwrite(damage, sizeof(uint32_t), a_dist_size, hdam_file);
+ fclose(hdam_file);
+ free(d_filename);
+ free(damage);
+ }
+
+ if (include_breaking) {
+ fclose(break_out);
+ }
+
+ if (save_crit_stress) {
+ char *str_filename = (char *)malloc(filename_len * sizeof(char));
+ snprintf(str_filename, filename_len, "strs_v_%c_%c_%d_%g.dat", boundc, boundc2, L, beta);
+ FILE *str_file = fopen(str_filename, "ab");
+ fwrite(crit_stress, sizeof(double), N, str_file);
+ fclose(str_file);
+ free(str_filename);
+ free(crit_stress);
+ }
+
+ CHOL_F(finish)(&c);
+
+ return 0;
+}