int main()
{
flint_printf("hilbert_class_poly....");
fflush(stdout);
{
slong i;
mp_limb_t c;
fmpz_poly_t hd;
nmod_poly_t hdp;
fmpz_poly_init(hd);
nmod_poly_init(hdp, 31337);
for (i = 0; i < 1000; i++)
{
acb_modular_hilbert_class_poly(hd, -i);
fmpz_poly_get_nmod_poly(hdp, hd);
c = nmod_poly_evaluate_nmod(hdp, 2015);
if (c != hilbert_poly_values[i])
{
flint_printf("FAIL!\n");
flint_printf("D = %wd\n", -i);
flint_printf("c = %wu\n", c);
flint_printf("expected = %d\n", (int) hilbert_poly_values[i]);
abort();
}
}
for (i = 0; hilbert_poly_values_2[2 * i] != 0; i++)
{
acb_modular_hilbert_class_poly(hd, hilbert_poly_values_2[2 * i]);
fmpz_poly_get_nmod_poly(hdp, hd);
c = nmod_poly_evaluate_nmod(hdp, 2015);
if (c != hilbert_poly_values_2[2 * i + 1])
{
flint_printf("FAIL!\n");
flint_printf("D = %wd\n", -i);
flint_printf("c = %wu\n", c);
flint_printf("expected = %d\n", (int) hilbert_poly_values_2[2*i+1]);
abort();
}
}
fmpz_poly_clear(hd);
nmod_poly_clear(hdp);
}
flint_cleanup();
flint_printf("PASS\n");
return EXIT_SUCCESS;
}
void
fmpz_poly_mod(fmpz_poly_t a,
const uint32_t mod)
{
nmod_poly_t nmod_tmp;
nmod_poly_init(nmod_tmp, mod);
fmpz_poly_get_nmod_poly(nmod_tmp, a);
fmpz_poly_set_nmod_poly(a, nmod_tmp);
nmod_poly_clear(nmod_tmp);
}
int
main(void)
{
int i, result;
flint_rand_t state;
printf("hensel_start_continue_lift....");
fflush(stdout);
flint_randinit(state);
/* We check that lifting local factors of F yields factors */
for (i = 0; i < 1000; i++)
{
fmpz_poly_t F, G, H, R;
nmod_poly_factor_t f_fac;
fmpz_poly_factor_t F_fac;
long bits, nbits, n, exp, j, part_exp;
long r;
fmpz_poly_t *v, *w;
long *link;
long prev_exp;
bits = n_randint(state, 200) + 1;
nbits = n_randint(state, FLINT_BITS - 6) + 6;
fmpz_poly_init(F);
fmpz_poly_init(G);
fmpz_poly_init(H);
fmpz_poly_init(R);
nmod_poly_factor_init(f_fac);
fmpz_poly_factor_init(F_fac);
n = n_randprime(state, nbits, 0);
exp = bits / (FLINT_BIT_COUNT(n) - 1) + 1;
part_exp = n_randint(state, exp);
/* Produce F as the product of random G and H */
{
nmod_poly_t f;
nmod_poly_init(f, n);
do {
do {
fmpz_poly_randtest(G, state, n_randint(state, 200) + 2, bits);
} while (G->length < 2);
fmpz_randtest_not_zero(G->coeffs, state, bits);
fmpz_one(fmpz_poly_lead(G));
do {
fmpz_poly_randtest(H, state, n_randint(state, 200) + 2, bits);
} while (H->length < 2);
fmpz_randtest_not_zero(H->coeffs, state, bits);
fmpz_one(fmpz_poly_lead(H));
fmpz_poly_mul(F, G, H);
fmpz_poly_get_nmod_poly(f, F);
} while (!nmod_poly_is_squarefree(f));
fmpz_poly_get_nmod_poly(f, G);
nmod_poly_factor_insert(f_fac, f, 1);
fmpz_poly_get_nmod_poly(f, H);
nmod_poly_factor_insert(f_fac, f, 1);
nmod_poly_clear(f);
}
r = f_fac->num;
v = flint_malloc((2*r - 2)*sizeof(fmpz_poly_t));
w = flint_malloc((2*r - 2)*sizeof(fmpz_poly_t));
link = flint_malloc((2*r - 2)*sizeof(long));
for (j = 0; j < 2*r - 2; j++)
{
fmpz_poly_init(v[j]);
fmpz_poly_init(w[j]);
}
if (part_exp < 1)
{
_fmpz_poly_hensel_start_lift(F_fac, link, v, w, F, f_fac, exp);
}
else
{
fmpz_t nn;
fmpz_init_set_ui(nn, n);
prev_exp = _fmpz_poly_hensel_start_lift(F_fac, link, v, w,
F, f_fac, part_exp);
_fmpz_poly_hensel_continue_lift(F_fac, link, v, w,
F, prev_exp, part_exp, exp, nn);
fmpz_clear(nn);
}
result = 1;
for (j = 0; j < F_fac->num; j++)
{
fmpz_poly_rem(R, F, F_fac->p + j);
result &= (R->length == 0);
}
for (j = 0; j < 2*r - 2; j++)
{
fmpz_poly_clear(v[j]);
fmpz_poly_clear(w[j]);
}
flint_free(link);
flint_free(v);
flint_free(w);
if (!result)
{
printf("FAIL:\n");
printf("bits = %ld, n = %ld, exp = %ld\n", bits, n, exp);
fmpz_poly_print(F); printf("\n\n");
fmpz_poly_print(G); printf("\n\n");
fmpz_poly_print(H); printf("\n\n");
fmpz_poly_factor_print(F_fac); printf("\n\n");
abort();
}
nmod_poly_factor_clear(f_fac);
fmpz_poly_factor_clear(F_fac);
fmpz_poly_clear(F);
fmpz_poly_clear(H);
fmpz_poly_clear(G);
fmpz_poly_clear(R);
}
flint_randclear(state);
_fmpz_cleanup();
printf("PASS\n");
return 0;
}
int
main(void)
{
int i;
flint_rand_t state;
printf("CRT_ui_unsigned....");
fflush(stdout);
flint_randinit(state);
for (i = 0; i < 10000; i++)
{
long bits, prime_bits, length, num_primes, j;
fmpz_t mod;
fmpz_poly_t A, B, C;
nmod_poly_t Amod;
mp_limb_t primes[1000];
bits = n_randint(state, 500) + 1;
length = n_randint(state, 30) + 1;
prime_bits = 1 + n_randint(state, FLINT_BITS - 1);
fmpz_poly_init(A);
fmpz_poly_init(B);
fmpz_poly_init(C);
fmpz_poly_randtest_unsigned(A, state, length, bits);
fmpz_init(mod);
num_primes = 0;
primes[0] = n_nextprime(1UL << prime_bits, 0);
fmpz_set_ui(mod, primes[0]);
while (fmpz_bits(mod) <= bits)
{
primes[num_primes + 1] = n_nextprime(primes[num_primes], 0);
fmpz_mul_ui(mod, mod, primes[num_primes + 1]);
num_primes++;
}
num_primes++;
nmod_poly_init(Amod, primes[0]);
fmpz_poly_get_nmod_poly(Amod, A);
fmpz_poly_set_nmod_poly_unsigned(B, Amod);
fmpz_set_ui(mod, primes[0]);
for (j = 1; j < num_primes; j++)
{
nmod_poly_clear(Amod);
nmod_poly_init(Amod, primes[j]);
fmpz_poly_get_nmod_poly(Amod, A);
fmpz_poly_CRT_ui(B, B, mod, Amod, 0);
fmpz_mul_ui(mod, mod, primes[j]);
}
if (!fmpz_poly_equal(B, A))
{
printf("FAIL!\n");
printf("primes: ");
for (j = 0; j < num_primes; j++)
printf("%lu ", primes[j]);
printf("\nA: \n");
fmpz_poly_print(A);
printf("\nB: \n");
fmpz_poly_print(B);
printf("\n");
abort();
}
nmod_poly_clear(Amod);
fmpz_poly_clear(A);
fmpz_poly_clear(B);
fmpz_poly_clear(C);
fmpz_clear(mod);
}
flint_randclear(state);
_fmpz_cleanup();
printf("PASS\n");
return 0;
}
