#include "ulong_extras.h"
#include "mpn_extras.h"
#include "nmod_vec.h"
#include "nmod_poly.h"
#include "nmod_mat.h"
void
_nmod_poly_reduce_matrix_mod_poly(nmod_mat_t A, const nmod_mat_t B,
const nmod_poly_t f)
{
nn_ptr tmp1;
slong n = f->length - 1;
slong i, m = n_sqrt(n) + 1;
nmod_mat_init(A, m, n, f->mod.n);
tmp1 = _nmod_vec_init(B->c - f->length + 1);
nmod_mat_entry(A, 0, 0) = 1;
for (i = 1; i < m; i++)
_nmod_poly_divrem(tmp1, nmod_mat_entry_ptr(A, i, 0), nmod_mat_entry_ptr(B, i, 0), B->c, f->coeffs,
f->length, f->mod);
_nmod_vec_clear(tmp1);
}
void
_nmod_poly_precompute_matrix(nmod_mat_t A, nn_srcptr poly1, nn_srcptr poly2,
slong len2, nn_srcptr poly2inv, slong len2inv, nmod_t mod)
{
slong n, m;
nn_ptr * Arows;
slong i;
n = len2 - 1;
m = n_sqrt(n) + 1;
Arows = flint_malloc(sizeof(nn_ptr) * A->r);
for (i = 0; i < A->r; i++)
Arows[i] = nmod_mat_entry_ptr(A, i, 0);
_nmod_poly_powers_mod_preinv_naive(Arows, poly1, n, m,
poly2, len2, poly2inv, len2inv, mod);
flint_free(Arows);
}
void
nmod_poly_precompute_matrix(nmod_mat_t A, const nmod_poly_t poly1,
const nmod_poly_t poly2, const nmod_poly_t poly2inv)
{
slong len1 = poly1->length;
slong len2 = poly2->length;
slong len = len2 - 1;
slong m = n_sqrt(len) + 1;
nn_ptr ptr1;
if (len2 == 0)
{
flint_throw(FLINT_DIVZERO, "Exception (nmod_poly_precompute_matrix). Division by zero.\n");
}
if (A->r != m || A->c != len)
{
flint_throw(FLINT_ERROR, "Exception (nmod_poly_precompute_matrix). Wrong dimensions.\n");
}
if (len2 == 1)
{
nmod_mat_zero(A);
return;
}
ptr1 = _nmod_vec_init(len);
if (len1 <= len)
{
flint_mpn_copyi(ptr1, poly1->coeffs, len1);
flint_mpn_zero(ptr1 + len1, len - len1);
} else
{
_nmod_poly_rem(ptr1, poly1->coeffs, len1, poly2->coeffs, len2, A->mod);
}
_nmod_poly_precompute_matrix(A, ptr1, poly2->coeffs,
len2, poly2inv->coeffs, poly2inv->length, A->mod);
_nmod_vec_clear(ptr1);
}
void
_nmod_poly_compose_mod_brent_kung_precomp_preinv(nn_ptr res, nn_srcptr poly1,
slong len1, const nmod_mat_t A, nn_srcptr poly3, slong len3,
nn_srcptr poly3inv, slong len3inv, nmod_t mod)
{
nmod_mat_t B, C;
nn_ptr h;
slong i, n, m;
n = len3 - 1;
if (len3 == 1)
return;
if (len1 == 1)
{
res[0] = poly1[0];
return;
}
if (len3 == 2)
{
res[0] = _nmod_poly_evaluate_nmod(poly1, len1, nmod_mat_entry(A, 1, 0), mod);
return;
}
m = n_sqrt(n) + 1;
FLINT_ASSERT(m == A->r);
nmod_mat_init(B, m, m, mod.n);
nmod_mat_init(C, m, n, mod.n);
h = _nmod_vec_init(n);
for (i = 0; i < len1 / m; i++)
_nmod_vec_set(nmod_mat_entry_ptr(B, i, 0), poly1 + i*m, m);
_nmod_vec_set(nmod_mat_entry_ptr(B, i, 0), poly1 + i*m, len1%m);
nmod_mat_mul(C, B, A);
_nmod_poly_mulmod_preinv(h, nmod_mat_entry_ptr(A, m / 2, 0), n,
nmod_mat_entry_ptr(A, m - (m / 2), 0), n, poly3, len3, poly3inv, len3inv, mod);
_nmod_poly_mod_matrix_rows_evaluate(res, C, h, n, poly3, len3, poly3inv, len3inv, mod);
_nmod_vec_clear(h);
nmod_mat_clear(B);
nmod_mat_clear(C);
}
void
nmod_poly_compose_mod_brent_kung_precomp_preinv(nmod_poly_t res,
const nmod_poly_t poly1, const nmod_mat_t A,
const nmod_poly_t poly3, const nmod_poly_t poly3inv)
{
slong len1 = poly1->length;
slong len3 = poly3->length;
slong len = len3 - 1;
if (len3 == 0)
{
flint_throw(FLINT_DIVZERO, "(nmod_poly_compose_mod_brent_kung_precomp_preinv): Division by zero.\n");
}
if (len1 >= len3)
{
flint_throw(FLINT_ERROR, "(nmod_poly_compose_mod_brent_kung_precomp_preinv): "
"The degree of the first polynomial must be smaller than that of the modulus.\n");
}
if (len1 == 0 || len3 == 1)
{
nmod_poly_zero(res);
return;
}
if (len1 == 1)
{
nmod_poly_set(res, poly1);
return;
}
if (res == poly3 || res == poly1 || res == poly3inv)
{
nmod_poly_t tmp;
nmod_poly_init_mod(tmp, res->mod);
nmod_poly_compose_mod_brent_kung_precomp_preinv(tmp, poly1, A,
poly3, poly3inv);
nmod_poly_swap(tmp, res);
nmod_poly_clear(tmp);
return;
}
nmod_poly_fit_length(res, len);
_nmod_poly_compose_mod_brent_kung_precomp_preinv(res->coeffs,
poly1->coeffs, len1, A, poly3->coeffs, len3,
poly3inv->coeffs, poly3inv->length, res->mod);
res->length = len;
_nmod_poly_normalise(res);
}