#include "arb/impl.h"
#include "arb_poly.h"
#include "acb_poly.h"
#include "acb_poly/impl.h"
#include "acb_hypgeom/impl.h"
static void
bsplit(acb_ptr Q, acb_ptr T, const acb_t z, slong a, slong b, slong num, slong prec)
{
if (b - a == 1)
{
arb_gamma_stirling_coeff(acb_realref(T), a, 0, prec);
arb_zero(acb_imagref(T));
if (a == 1)
{
acb_set(Q, z);
if (num > 1) acb_one(Q + 1);
if (num > 2) acb_zero(Q + 2);
}
else
{
acb_mul(Q, z, z, prec);
if (num > 1) acb_mul_2exp_si(Q + 1, z, 1);
if (num > 2) acb_one(Q + 2);
}
}
else
{
slong m, n1, n2, q1len, q2len, t1len, t2len, qlen, tlen, alloc;
acb_ptr Q1, T1, Q2, T2;
m = a + (b - a) / 2;
n1 = m - a;
n2 = b - m;
q1len = FLINT_MIN(2 * n1 + 1, num);
t1len = FLINT_MIN(2 * n1 - 1, num);
q2len = FLINT_MIN(2 * n2 + 1, num);
t2len = FLINT_MIN(2 * n2 - 1, num);
qlen = FLINT_MIN(q1len + q2len - 1, num);
tlen = FLINT_MIN(t1len + q2len - 1, num);
alloc = q1len + q2len + t1len + t2len;
Q1 = _acb_vec_init(alloc);
Q2 = Q1 + q1len;
T1 = Q2 + q2len;
T2 = T1 + t1len;
bsplit(Q1, T1, z, a, m, num, prec);
bsplit(Q2, T2, z, m, b, num, prec);
_acb_poly_mullow(Q, Q2, q2len, Q1, q1len, qlen, prec);
_acb_poly_mullow(T, Q2, q2len, T1, t1len, tlen, prec);
_acb_poly_add(T, T, tlen, T2, t2len, prec);
_acb_vec_clear(Q1, alloc);
}
}
static void
_acb_poly_log_cpx_series(acb_ptr res, const acb_t c, slong num, slong prec)
{
slong i;
for (i = 0; i < num; i++)
{
if (i == 0)
acb_log(res + i, c, prec);
else if (i == 1)
acb_inv(res + i, c, prec);
else
acb_mul(res + i, res + i - 1, res + 1, prec);
}
for (i = 2; i < num; i++)
{
acb_div_ui(res + i, res + i, i, prec);
if (i % 2 == 0)
acb_neg(res + i, res + i);
}
}
void
_acb_poly_gamma_stirling_eval2(acb_ptr res, const acb_t z, slong n, slong num, int diff, slong prec)
{
slong k, tlen, qlen;
acb_ptr T, Q;
mag_ptr err;
acb_t c;
T = _acb_vec_init(num);
Q = _acb_vec_init(num);
err = _mag_vec_init(num);
acb_init(c);
acb_gamma_stirling_bound(err, z, 0, num, n);
if (n <= 1)
{
_acb_vec_zero(res, num);
}
else
{
qlen = FLINT_MIN(2 * (n - 1) + 1, num);
tlen = FLINT_MIN(2 * (n - 1) - 1, num);
bsplit(Q, T, z, 1, n, num, prec);
_acb_poly_div_series(res, T, tlen, Q, qlen, num, prec);
}
if (diff)
{
_acb_vec_add_error_mag_vec(res, err, num);
_acb_poly_derivative(res, res, num, prec);
if (num > 1)
{
acb_inv(c, z, prec);
_acb_vec_set_powers(T, c, num, prec);
for (k = 1; k < num - 1; k++)
{
acb_mul_2exp_si(T, z, 1);
acb_div_ui(T, T, k, prec);
acb_add_ui(T, T, 1, prec);
acb_mul_2exp_si(T, T, -1);
if (k % 2 == 0)
acb_submul(res + k, T, T + k + 1, prec);
else
acb_addmul(res + k, T, T + k + 1, prec);
}
acb_mul_2exp_si(c, c, -1);
acb_sub(res, res, c, prec);
acb_log(c, z, prec);
acb_add(res, res, c, prec);
}
}
else
{
_acb_poly_log_cpx_series(T, z, num, prec);
acb_one(c);
acb_mul_2exp_si(c, c, -1);
acb_sub(c, z, c, prec);
_acb_poly_mullow_cpx(T, T, num, c, num, prec);
arb_const_log_sqrt2pi(acb_realref(c), prec);
arb_zero(acb_imagref(c));
acb_add(T, T, c, prec);
acb_sub(T, T, z, prec);
if (num > 1)
acb_sub_ui(T + 1, T + 1, 1, prec);
_acb_vec_add(res, res, T, num, prec);
_acb_vec_add_error_mag_vec(res, err, num);
}
_acb_vec_clear(T, num);
_acb_vec_clear(Q, num);
_mag_vec_clear(err, num);
acb_clear(c);
}
void
_acb_poly_gamma_stirling_eval(acb_ptr res, const acb_t z, slong n, slong num, slong prec)
{
_acb_poly_gamma_stirling_eval2(res, z, n, num, 0, prec);
}
void
_acb_poly_gamma_series(acb_ptr res, acb_srcptr h, slong hlen, slong len, slong prec)
{
int reflect;
slong i, rflen, r, n, wp;
acb_ptr t, u, v;
acb_struct f[2];
hlen = FLINT_MIN(hlen, len);
if (hlen == 1)
{
acb_gamma(res, h, prec);
if (acb_is_finite(res))
_acb_vec_zero(res + 1, len - 1);
else
_acb_vec_indeterminate(res + 1, len - 1);
return;
}
if (_acb_vec_is_real(h, hlen))
{
arb_ptr tmp = _arb_vec_init(len);
for (i = 0; i < hlen; i++)
arb_set(tmp + i, acb_realref(h + i));
_arb_poly_gamma_series(tmp, tmp, hlen, len, prec);
for (i = 0; i < len; i++)
acb_set_arb(res + i, tmp + i);
_arb_vec_clear(tmp, len);
return;
}
wp = prec + FLINT_BIT_COUNT(prec);
t = _acb_vec_init(len);
u = _acb_vec_init(len);
v = _acb_vec_init(len);
acb_init(f);
acb_init(f + 1);
acb_hypgeom_gamma_stirling_choose_param(&reflect, &r, &n, h, 1, 0, wp);
if (reflect)
{
acb_sub_ui(f, h, r + 1, wp);
acb_neg(f, f);
_acb_poly_gamma_stirling_eval(t, f, n, len, wp);
_acb_vec_neg(t, t, len);
_acb_poly_exp_series(u, t, len, len, wp);
for (i = 1; i < len; i += 2)
acb_neg(u + i, u + i);
acb_set(f, h);
acb_one(f + 1);
_acb_poly_sin_pi_series(t, f, 2, len, wp);
_acb_poly_inv_series(v, t, len, len, wp);
_acb_poly_mullow(t, u, len, v, len, len, wp);
if (r == 0)
{
rflen = 1;
acb_const_pi(u, wp);
}
else
{
acb_sub_ui(f, h, 1, wp);
acb_neg(f, f);
acb_set_si(f + 1, -1);
rflen = FLINT_MIN(len, r + 1);
_acb_poly_rising_ui_series(u, f, FLINT_MIN(2, len), r, rflen, wp);
acb_const_pi(v, wp);
_acb_vec_scalar_mul(u, u, rflen, v, wp);
}
_acb_poly_mullow(v, t, len, u, rflen, len, wp);
}
else
{
if (r == 0)
{
acb_add_ui(f, h, r, wp);
_acb_poly_gamma_stirling_eval(t, f, n, len, wp);
_acb_poly_exp_series(v, t, len, len, wp);
}
else
{
acb_set(f, h);
acb_one(f + 1);
rflen = FLINT_MIN(len, r + 1);
_acb_poly_rising_ui_series(u, f, FLINT_MIN(2, len), r, rflen, wp);
_acb_poly_inv_series(t, u, rflen, len, wp);
acb_add_ui(f, h, r, wp);
_acb_poly_gamma_stirling_eval(v, f, n, len, wp);
_acb_poly_exp_series(u, v, len, len, wp);
_acb_poly_mullow(v, u, len, t, len, len, wp);
}
}
acb_zero(t);
_acb_vec_set(t + 1, h + 1, hlen - 1);
_acb_poly_compose_series(res, v, len, t, hlen, len, prec);
acb_clear(f);
acb_clear(f + 1);
_acb_vec_clear(t, len);
_acb_vec_clear(u, len);
_acb_vec_clear(v, len);
}
void
acb_poly_gamma_series(acb_poly_t res, const acb_poly_t f, slong n, slong prec)
{
acb_poly_fit_length(res, n);
if (f->length == 0 || n == 0)
_acb_vec_indeterminate(res->coeffs, n);
else
_acb_poly_gamma_series(res->coeffs, f->coeffs, f->length, n, prec);
_acb_poly_set_length(res, n);
_acb_poly_normalise(res);
}