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#include "fracture.h"
bool set_connected(const cholmod_sparse *laplacian, uint_t *marks,
int vertex, int label, int stop_at, int exclude) {
unsigned int num_verts = (int_t)laplacian->nrow;
int_t *ia = (int_t *)laplacian->p;
int_t *ja = (int_t *)laplacian->i;
double *a = (double *)laplacian->x;
bool stopped = false;
int *queue = (int *)malloc((num_verts) * sizeof(int));
assert(queue != NULL);
int queue_pos = 0;
int *component_list = (int *)malloc((num_verts) * sizeof(int));
assert(component_list != NULL);
int list_pos = 0;
queue[0] = vertex;
component_list[0] = vertex;
unsigned int old_label = marks[vertex];
marks[vertex] = label;
while (queue_pos >= 0) {
int next_vertex = queue[queue_pos];
queue_pos--;
for (int j = 0; j < ia[next_vertex + 1] - ia[next_vertex]; j++) {
if (ja[ia[next_vertex] + j] == stop_at && a[ia[next_vertex] + j] != 0) {
// if we run into the other vertex, the components haven't changed
stopped = true; queue_pos = -1;
break;
}
if (marks[ja[ia[next_vertex] + j]] != label &&
a[ia[next_vertex] + j] != 0 &&
ja[ia[next_vertex] + j] < num_verts - exclude) {
marks[ja[ia[next_vertex] + j]] = label;
queue_pos++;
queue[queue_pos] = ja[ia[next_vertex] + j];
list_pos++;
component_list[list_pos] = ja[ia[next_vertex] + j];
}
}
}
if (stopped) {
for (unsigned int i = 0; i <= list_pos; i++) {
marks[component_list[i]] = old_label;
}
}
free(queue);
free(component_list);
if (stopped)
return false;
else
return true;
}
int update_components(const cholmod_sparse *laplacian, unsigned int *marks,
int old_num_components, int v1, int v2, int exclude) {
assert(laplacian != NULL);
assert(marks != NULL);
if (set_connected(laplacian, marks, v1, old_num_components + 1, v2,
exclude)) {
return old_num_components + 1;
} else
return old_num_components;
}
unsigned int *find_components(const cholmod_sparse *laplacian, unsigned int skip) {
size_t num_verts = laplacian->nrow;
unsigned int *marks = (unsigned int *)calloc(num_verts, sizeof(unsigned int));
int num_components = 0;
for (int i = 0; i < num_verts; i++) {
if (marks[i] == 0) {
num_components++;
set_connected(laplacian, marks, i, num_components, -1, skip);
}
}
return marks;
}
uint_t find_cycles(uint_t num_edges, const bool *fuses, const uint_t *ev, const unsigned
int *vei, const uint_t *ve, int **cycles) {
uint_t num_cycles = 0;
uint_t *elist = (uint_t *)malloc(num_edges * sizeof(uint_t));
uint_t *side = (uint_t *)calloc(num_edges, sizeof(uint_t));
uint_t *num = (uint_t *)malloc(num_edges * sizeof(uint_t));
for (uint_t i = 0; i < num_edges; i++) {
if (fuses[i]) {
bool in_cycle = false;
for (uint_t j = 0; j < num_cycles; j++) {
uint_t k = 0;
int e;
while ((e = cycles[j][k]) >= 0) {
if (e == i) {
in_cycle = true;
break;
}
k++;
}
if (in_cycle) {
break;
}
}
if (!in_cycle) {
uint_t pos = 0;
uint_t cur_e = i;
bool *included = (bool *)calloc(num_edges, sizeof(bool));
included[cur_e] = true;
elist[0] = cur_e;
side[0] = 1;
num[0] = 0;
while (true) {
uint_t cv = ev[2 * cur_e + side[pos]];
uint_t new_e = cur_e;
uint_t j;
for (j = num[pos]; j < vei[cv+1] - vei[cv]; j++) {
new_e = ve[vei[cv] + j];
if (new_e != cur_e && fuses[new_e]) break;
}
if (new_e != cur_e && fuses[new_e]) {
if (new_e == elist[0] && cv == ev[2 * elist[0] + !side[0]]) {
pos++;
cycles[2*num_cycles] = (int *)malloc((pos + 1) * sizeof(int));
cycles[2*num_cycles+1] = (int *)malloc((pos + 1) * sizeof(int));
for (uint_t i = 0; i < pos; i++) {
cycles[2*num_cycles][i] = elist[i];
cycles[2*num_cycles+1][i] = side[i];
}
cycles[2*num_cycles][pos] = -1;
cycles[2*num_cycles+1][pos] = -1;
num_cycles++;
pos--;
num[pos]++;
included[pos] = false;
cur_e = elist[pos];
} else if (included[new_e]) {
if (pos == 0) break;
included[cur_e] = false;
pos--;
num[pos]++;
cur_e = elist[pos];
} else {
num[pos] = j;
pos++;
elist[pos] = new_e;
included[new_e] = true;
uint_t nv1 = ev[2 * new_e];
uint_t nv2 = ev[2 * new_e + 1];
uint_t v = nv1 == cv ? nv2 : nv1;
side[pos] = v == nv1 ? 0 : 1;
num[pos] = 0;
cur_e = new_e;
}
} else {
if (pos == 0) break;
included[cur_e] = false;
pos--;
num[pos]++;
cur_e = elist[pos];
}
}
free(included);
}
}
}
free(elist);
free(side);
free(num);
return num_cycles;
}
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