void
fmpz_poly_revert_series_lagrange(fmpz_poly_t Qinv,
const fmpz_poly_t Q, slong n)
{
fmpz *Qcopy;
int Qalloc;
slong Qlen = Q->length;
if (Qlen < 2 || !fmpz_is_zero(Q->coeffs) || !fmpz_is_pm1(Q->coeffs + 1))
{
flint_printf("Exception (fmpz_poly_revert_series_lagrange). Input must have \n"
"zero constant term and +1 or -1 as coefficient of x^1.\n");
abort();
}
if (Qlen >= n)
{
Qcopy = Q->coeffs;
Qalloc = 0;
}
else
{
slong i;
Qcopy = (fmpz *) flint_malloc(n * sizeof(fmpz));
for (i = 0; i < Qlen; i++)
Qcopy[i] = Q->coeffs[i];
for ( ; i < n; i++)
Qcopy[i] = 0;
Qalloc = 1;
}
if (Qinv != Q)
{
fmpz_poly_fit_length(Qinv, n);
_fmpz_poly_revert_series_lagrange(Qinv->coeffs, Qcopy, n);
}
else
{
fmpz_poly_t t;
fmpz_poly_init2(t, n);
_fmpz_poly_revert_series_lagrange(t->coeffs, Qcopy, n);
fmpz_poly_swap(Qinv, t);
fmpz_poly_clear(t);
}
_fmpz_poly_set_length(Qinv, n);
_fmpz_poly_normalise(Qinv);
if (Qalloc)
flint_free(Qcopy);
}
void
_fmpz_poly_revert_series_newton(fmpz * Qinv, const fmpz * Q, long n)
{
if (n <= 2)
{
_fmpz_vec_set(Qinv, Q, n);
return;
}
else
{
long *a, i, k;
fmpz *T, *U, *V;
T = _fmpz_vec_init(n);
U = _fmpz_vec_init(n);
V = _fmpz_vec_init(n);
k = n;
for (i = 1; (1L << i) < k; i++);
a = (long *) flint_malloc(i * sizeof(long));
a[i = 0] = k;
while (k >= FLINT_REVERSE_NEWTON_CUTOFF)
a[++i] = (k = (k + 1) / 2);
_fmpz_poly_revert_series_lagrange(Qinv, Q, k);
_fmpz_vec_zero(Qinv + k, n - k);
for (i--; i >= 0; i--)
{
k = a[i];
_fmpz_poly_compose_series(T, Q, k, Qinv, k, k);
_fmpz_poly_derivative(U, T, k); fmpz_zero(U + k - 1);
fmpz_zero(T + 1);
_fmpz_poly_div_series(V, T, U, k);
_fmpz_poly_derivative(T, Qinv, k);
_fmpz_poly_mullow(U, V, k, T, k, k);
_fmpz_vec_sub(Qinv, Qinv, U, k);
}
flint_free(a);
_fmpz_vec_clear(T, n);
_fmpz_vec_clear(U, n);
_fmpz_vec_clear(V, n);
}
}
