int main(int argc, char **argv)
{
if (argc != 2) {
fprintf(stderr, "*** Invalid number of parameters\n");
exit(1);
}
const char *const filename_sg1= argv[1];
struct sgraph1_reader_a r;
if (0 > sgraph1_open_read_a(filename_sg1, &r, 0)) {
exit(1);
}
/* No need for file advisories since we're only reading the
header */
if (r.h->format == FORMAT_SYM || r.h->format == FORMAT_ASYM) {
assert(r.h->n1 == r.h->n2);
const ua_ft n= r.h->n1;
printf("%" PR_fua "\n", n);
} else if (r.h->format == FORMAT_BIP) {
const ua_ft n1= r.h->n1;
const va_ft n2= r.h->n2;
const uintmax_t n= n1 + n2;
printf("%" PRIuMAX "\n"
"%" PR_fua "\n"
"%" PR_fva "\n",
n, n1, n2);
} else
assert(0);
exit(0);
}
/* Invocation:
* $0 INPUT-FILE OUTPUTFILE
*/
int main(int argc, char **argv)
{
assert(argc == 3);
(void) argc;
const char *const filename_in= argv[1];
const char *const filename_out= argv[2];
struct sgraph1_reader_a r;
if (0 > sgraph1_open_read_a(filename_in, &r, 2)) {
exit(1);
}
if (0 > sgraph1_advise_a(&r, MADV_RANDOM)) {
perror(filename_in);
exit(1);
}
unsigned char *lcc= lcc_find(&r);
if (0 > sgraph1_subgraph_a(&r, lcc, filename_out)) {
exit(1);
}
exit(0);
}
int main(int argc, char **argv)
{
if (argc != 3) {
fprintf(stderr, "*** Expected 2 parameters\n");
exit(1);
}
const char *const filename_sg1= argv[1];
struct sgraph1_reader_a r;
if (0 > sgraph1_open_read_a(filename_sg1, &r, 2)) {
exit(1);
}
if (0 > sgraph1_advise_a(&r, MADV_SEQUENTIAL)) {
perror(filename_sg1);
exit(1);
}
uintmax_t t= 0;
const ma_ft len_m= 2 * r.h->m - r.loops;
assert(len_m == r.len_m);
const ua_ft n= (ua_ft)r.h->n1;
r_to= r.to;
for (ua_ft u= 0; u < n; ++u) {
const ma_ft beg1_u= read_ma(r.adj_to, u);
const ma_ft end1= (u + 1 == n ? len_m : read_ma(r.adj_to, u+1));
for (ma_ft i= beg1_u; i < end1; ++i) {
const va_ft v= read_va(r.to, i);
if (v >= u)
break;
ma_ft beg1= beg1_u;
ma_ft beg2= read_ma(r.adj_to, v);
const ma_ft end2= (v + 1 == n) ? len_m : read_ma(r.adj_to, v+1);
assert(beg1 <= end1);
assert(beg2 <= end2);
assert(beg1 >= end2 || beg2 >= end1);
#if VARIANT == 0
while (beg1 < end1 && beg2 < end2) {
/* This network is without multiple edges */
assert(beg1 + 1 == end1 || read_u(r.to, beg1) < read_u(r.to, beg1 + 1));
assert(beg2 + 1 == end2 || read_u(r.to, beg2) < read_u(r.to, beg2 + 1));
const ua_ft x1= read_u(r.to, beg1);
const ua_ft x2= read_u(r.to, beg2);
assert(SIZE_MAX - 1 >= t);
t += (x1 == x2);
if (x1 <= x2) ++beg1;
if (x2 <= x1) ++beg2;
}
#elif VARIANT == 1
ma_ft t_uv= common_elements(beg1, end1, beg2, end2);
assert(SIZE_MAX - t_uv >= t);
t += t_uv;
#endif
}
}
assert(t % 3 == 0);
t /= 3;
if (0 > printf("%" PRIuMAX "\n", t)) {
perror("printf");
exit(1);
}
exit(0);
}
int main(int argc, char **argv)
{
if (argc != 3) {
fprintf(stderr, "*** Invalid number of parameters\n");
exit(1);
}
const char *const filename_sg1= argv[1];
const char *const filename_ft= argv[2];
struct sgraph1_reader_a r;
if (0 > sgraph1_open_read_a(filename_sg1, &r, 2)) {
exit(1);
}
if (0 > sgraph1_advise_a(&r, MADV_SEQUENTIAL)) {
perror(filename_sg1);
exit(1);
}
struct feature_a f;
if (0 > feature_open_write_a(filename_ft, &f, r.h->n1
#if FEATURE_N2
, r.h->n2
#endif
)) {
exit(1);
}
if (0 > feature_advise_a(&f, MADV_SEQUENTIAL)) {
perror(filename_ft);
exit(1);
}
for (ua_ft u= 0; u < r.h->n1; ++u) {
const ma_ft beg= read_ma(r.adj_to, u);
const ma_ft end= u == r.h->n1 - 1 ? r.len_m : read_ma(r.adj_to, u + 1);
assert(beg <= end);
assert((ma_ft)(end - beg) < fa_max);
writeonzero_fa(f.f1, u, end - beg);
}
#if FEATURE_N2
for (u_ft v= 0; v < r.h->n2; ++v) {
const m_ft beg= read_m(r.adj_from, v);
const m_ft end= v == r.h->n2 - 1 ? r.len_m : read_m(r.adj_from, v + 1);
assert(end - beg < f_max);
writeonzero_f(f.f2, v, end - beg);
}
#endif
if (0 > feature_close_write_a(&f)) {
perror(filename_ft);
if (0 > unlink(filename_ft)) {
perror(filename_ft);
}
exit(1);
}
exit(0);
}
