void
acb_sinc_pi(acb_t res, const acb_t x, slong prec)
{
mag_t m;
acb_t t;
if (acb_is_zero(x))
{
acb_one(res);
return;
}
mag_init(m);
acb_init(t);
acb_get_mag_lower(m, x);
if (mag_cmp_2exp_si(m, -1) > 0)
{
acb_const_pi(t, prec + 4);
acb_mul(t, t, x, prec + 4);
acb_sin_pi(res, x, prec + 4);
acb_div(res, res, t, prec);
}
else
{
acb_const_pi(t, prec + 4);
acb_mul(t, t, x, prec + 4);
acb_sinc(res, t, prec);
}
mag_clear(m);
acb_clear(t);
}
void
acb_hypgeom_bessel_j_asymp_prefactors(acb_t Ap, acb_t Am, acb_t C,
const acb_t nu, const acb_t z, long prec)
{
if (arb_is_positive(acb_realref(z)))
{
acb_t t, u;
acb_init(t);
acb_init(u);
/* -(2nu+1)/4 * pi + z */
acb_mul_2exp_si(t, nu, 1);
acb_add_ui(t, t, 1, prec);
acb_mul_2exp_si(t, t, -2);
acb_neg(t, t);
acb_const_pi(u, prec);
acb_mul(t, t, u, prec);
acb_add(t, t, z, prec);
acb_mul_onei(t, t);
acb_exp_invexp(Ap, Am, t, prec);
/* (2 pi z)^(-1/2) */
acb_const_pi(C, prec);
acb_mul_2exp_si(C, C, 1);
acb_mul(C, C, z, prec);
acb_rsqrt(C, C, prec);
acb_clear(t);
acb_clear(u);
return;
}
acb_hypgeom_bessel_j_asymp_prefactors_fallback(Ap, Am, C, nu, z, prec);
}
void
_acb_poly_sin_cos_pi_series(acb_ptr s, acb_ptr c, const acb_srcptr h, slong hlen, slong n, slong prec)
{
hlen = FLINT_MIN(hlen, n);
if (hlen == 1)
{
acb_sin_cos_pi(s, c, h, prec);
_acb_vec_zero(s + 1, n - 1);
_acb_vec_zero(c + 1, n - 1);
}
else if (n == 2)
{
acb_t t;
acb_init(t);
acb_const_pi(t, prec);
acb_mul(t, t, h + 1, prec);
acb_sin_cos_pi(s, c, h, prec);
acb_mul(s + 1, c, t, prec);
acb_neg(t, t);
acb_mul(c + 1, s, t, prec);
acb_clear(t);
}
else if (hlen < TANGENT_CUTOFF)
_acb_poly_sin_cos_series_basecase(s, c, h, hlen, n, prec, 1);
else
_acb_poly_sin_cos_series_tangent(s, c, h, hlen, n, prec, 1);
}
void
acb_modular_elliptic_e(acb_t res, const acb_t m, long prec)
{
if (acb_is_zero(m))
{
acb_const_pi(res, prec);
acb_mul_2exp_si(res, res, -1);
}
else if (acb_is_one(m))
{
acb_one(res);
}
else
{
acb_struct t[2];
acb_init(t + 0);
acb_init(t + 1);
acb_modular_elliptic_k_cpx(t, m, 2, prec);
acb_mul(t + 1, t + 1, m, prec);
acb_mul_2exp_si(t + 1, t + 1, 1);
acb_add(t, t, t + 1, prec);
acb_sub_ui(t + 1, m, 1, prec);
acb_mul(res, t, t + 1, prec);
acb_neg(res, res);
acb_clear(t + 0);
acb_clear(t + 1);
}
}
void
acb_lambertw_initial_asymp(acb_t w, const acb_t z, const fmpz_t k, slong prec)
{
acb_t L1, L2, t;
acb_init(L1);
acb_init(L2);
acb_init(t);
acb_const_pi(L2, prec);
acb_mul_2exp_si(L2, L2, 1);
acb_mul_fmpz(L2, L2, k, prec);
acb_mul_onei(L2, L2);
acb_log(L1, z, prec);
acb_add(L1, L1, L2, prec);
acb_log(L2, L1, prec);
/* L1 - L2 + L2/L1 + L2(L2-2)/(2 L1^2) */
acb_inv(t, L1, prec);
acb_mul_2exp_si(w, L2, 1);
acb_submul(w, L2, L2, prec);
acb_neg(w, w);
acb_mul(w, w, t, prec);
acb_mul_2exp_si(w, w, -1);
acb_add(w, w, L2, prec);
acb_mul(w, w, t, prec);
acb_sub(w, w, L2, prec);
acb_add(w, w, L1, prec);
acb_clear(L1);
acb_clear(L2);
acb_clear(t);
}
/* REAL: erf(x) = 2x/sqrt(pi) * exp(-x^2) 1F1(1, 3/2, x^2) */
void
acb_hypgeom_erf_1f1b(acb_t res, const acb_t z, slong prec)
{
acb_t a, b, t, w;
acb_init(a);
acb_init(b);
acb_init(t);
acb_init(w);
acb_set_ui(b, 3);
acb_mul_2exp_si(b, b, -1);
acb_mul(w, z, z, prec);
acb_hypgeom_pfq_direct(t, a, 0, b, 1, w, -1, prec);
acb_neg(w, w);
acb_exp(w, w, prec);
acb_mul(t, t, w, prec);
acb_const_pi(w, prec);
acb_rsqrt(w, w, prec);
acb_mul(t, t, w, prec);
acb_mul(t, t, z, prec);
acb_mul_2exp_si(res, t, 1);
acb_clear(a);
acb_clear(b);
acb_clear(t);
acb_clear (w);
}
void
acb_hypgeom_bessel_jy(acb_t res1, acb_t res2, const acb_t nu, const acb_t z, slong prec)
{
acb_t jnu, t, u, v;
acb_init(jnu);
acb_init(t);
acb_init(u);
acb_init(v);
acb_hypgeom_bessel_j(jnu, nu, z, prec);
if (acb_is_int(nu))
{
int is_real = acb_is_real(nu) && acb_is_real(z)
&& arb_is_positive(acb_realref(z));
acb_mul_onei(t, z);
acb_hypgeom_bessel_k(t, nu, t, prec);
acb_onei(u);
acb_pow(u, u, nu, prec);
acb_mul(t, t, u, prec);
acb_const_pi(u, prec);
acb_div(t, t, u, prec);
acb_mul_2exp_si(t, t, 1);
acb_neg(t, t);
phase(v, acb_realref(z), acb_imagref(z));
acb_mul(u, jnu, v, prec);
acb_mul_onei(u, u);
acb_sub(res2, t, u, prec);
if (is_real)
arb_zero(acb_imagref(res2));
}
else
{
acb_sin_cos_pi(t, u, nu, prec);
acb_mul(v, jnu, u, prec);
acb_neg(u, nu);
acb_hypgeom_bessel_j(u, u, z, prec);
acb_sub(v, v, u, prec);
acb_div(res2, v, t, prec);
}
if (res1 != NULL)
acb_set(res1, jnu);
acb_clear(jnu);
acb_clear(t);
acb_clear(u);
acb_clear(v);
}
void
acb_hypgeom_erf_asymp(acb_t res, const acb_t z, slong prec, slong prec2)
{
acb_t a, t, u;
acb_init(a);
acb_init(t);
acb_init(u);
acb_one(a);
acb_mul_2exp_si(a, a, -1);
acb_mul(t, z, z, prec2);
acb_hypgeom_u_asymp(u, a, a, t, -1, prec2);
acb_neg(t, t);
acb_exp(t, t, prec2);
acb_mul(u, u, t, prec2);
acb_const_pi(t, prec2);
acb_sqrt(t, t, prec2);
acb_mul(t, t, z, prec2);
acb_div(u, u, t, prec2);
/* branch cut term: -1 or 1 */
if (arb_contains_zero(acb_realref(z)))
{
arb_zero(acb_imagref(t));
arf_zero(arb_midref(acb_realref(t)));
mag_one(arb_radref(acb_realref(t)));
}
else
{
acb_set_si(t, arf_sgn(arb_midref(acb_realref(z))));
}
acb_sub(t, t, u, prec);
if (arb_is_zero(acb_imagref(z)))
arb_zero(acb_imagref(t));
else if (arb_is_zero(acb_realref(z)))
arb_zero(acb_realref(t));
acb_set(res, t);
acb_clear(a);
acb_clear(t);
acb_clear(u);
}
void
acb_modular_elliptic_k(acb_t k, const acb_t m, slong prec)
{
acb_t t;
acb_init(t);
acb_sub_ui(t, m, 1, prec);
acb_neg(t, t);
acb_sqrt(t, t, prec);
acb_agm1(k, t, prec);
acb_const_pi(t, prec);
acb_div(k, t, k, prec);
acb_mul_2exp_si(k, k, -1);
acb_clear(t);
}
void
acb_hypgeom_bessel_i_asymp_prefactors(acb_t A, acb_t B, acb_t C,
const acb_t nu, const acb_t z, long prec)
{
acb_t t, u;
acb_init(t);
acb_init(u);
/* C = (2 pi z)^(-1/2) */
acb_const_pi(C, prec);
acb_mul_2exp_si(C, C, 1);
acb_mul(C, C, z, prec);
acb_rsqrt(C, C, prec);
if (arb_is_positive(acb_imagref(z)) ||
(arb_is_zero(acb_imagref(z)) && arb_is_negative(acb_realref(z))))
{
acb_exp_pi_i(t, nu, prec);
acb_mul_onei(t, t);
}
else if (arb_is_negative(acb_imagref(z)) ||
(arb_is_zero(acb_imagref(z)) && arb_is_positive(acb_realref(z))))
{
acb_neg(t, nu);
acb_exp_pi_i(t, t, prec);
acb_mul_onei(t, t);
acb_neg(t, t);
}
else
{
acb_exp_pi_i(t, nu, prec);
acb_mul_onei(t, t);
acb_neg(u, nu);
acb_exp_pi_i(u, u, prec);
acb_mul_onei(u, u);
acb_neg(u, u);
arb_union(acb_realref(t), acb_realref(t), acb_realref(u), prec);
arb_union(acb_imagref(t), acb_imagref(t), acb_imagref(u), prec);
}
acb_exp_invexp(B, A, z, prec);
acb_mul(A, A, t, prec);
acb_clear(t);
acb_clear(u);
}
void
acb_acos(acb_t res, const acb_t z, slong prec)
{
if (acb_is_one(z))
{
acb_zero(res);
}
else
{
acb_t t;
acb_init(t);
acb_asin(res, z, prec);
acb_const_pi(t, prec);
acb_mul_2exp_si(t, t, -1);
acb_sub(res, t, res, prec);
acb_clear(t);
}
}
/* (+/- iz)^(-1/2-v) * z^v * exp(+/- iz) */
void
acb_hypgeom_bessel_j_asymp_prefactors_fallback(acb_t Ap, acb_t Am, acb_t C,
const acb_t nu, const acb_t z, long prec)
{
acb_t t, u, v;
acb_init(t);
acb_init(u);
acb_init(v);
/* v = -1/2-nu */
acb_one(v);
acb_mul_2exp_si(v, v, -1);
acb_add(v, v, nu, prec);
acb_neg(v, v);
acb_mul_onei(t, z); /* t = iz */
acb_neg(u, t); /* u = -iz */
/* Ap, Am = (+/- iz)^(-1/2-nu) */
acb_pow(Ap, t, v, prec);
acb_pow(Am, u, v, prec);
/* Ap, Am *= exp(+/- iz) */
acb_exp_invexp(u, v, t, prec);
acb_mul(Ap, Ap, u, prec);
acb_mul(Am, Am, v, prec);
/* z^nu */
acb_pow(t, z, nu, prec);
acb_mul(Ap, Ap, t, prec);
acb_mul(Am, Am, t, prec);
/* (2 pi)^(-1/2) */
acb_const_pi(C, prec);
acb_mul_2exp_si(C, C, 1);
acb_rsqrt(C, C, prec);
acb_clear(t);
acb_clear(u);
acb_clear(v);
}
/* IMAG: erf(z) = 2z/sqrt(pi) * 1F1(1/2, 3/2, -z^2) */
void
acb_hypgeom_erf_1f1a(acb_t res, const acb_t z, slong prec)
{
acb_t a, t, w;
acb_struct b[2];
acb_init(a);
acb_init(b);
acb_init(b + 1);
acb_init(t);
acb_init(w);
acb_one(a);
acb_mul_2exp_si(a, a, -1);
acb_set_ui(b, 3);
acb_mul_2exp_si(b, b, -1);
acb_one(b + 1);
acb_mul(w, z, z, prec);
acb_neg(w, w);
acb_hypgeom_pfq_direct(t, a, 1, b, 2, w, -1, prec);
acb_const_pi(w, prec);
acb_rsqrt(w, w, prec);
acb_mul(t, t, w, prec);
acb_mul(t, t, z, prec);
acb_mul_2exp_si(res, t, 1);
acb_clear(a);
acb_clear(b);
acb_clear(b + 1);
acb_clear(t);
acb_clear(w);
}
void
acb_hypgeom_chi_asymp(acb_t res, const acb_t z, slong prec)
{
acb_t t, u, v, one;
acb_init(t);
acb_init(u);
acb_init(v);
acb_init(one);
acb_one(one);
/* u = U(1,1,z) */
acb_hypgeom_u_asymp(u, one, one, z, -1, prec);
/* v = e^(-z) */
acb_neg(v, z);
acb_exp(v, v, prec);
acb_mul(t, u, v, prec);
if (arb_is_zero(acb_realref(z)))
{
arb_div(acb_realref(t), acb_imagref(t), acb_imagref(z), prec);
arb_zero(acb_imagref(t));
acb_neg(t, t);
}
else
{
/* u = U(1,1,-z) */
acb_neg(u, z);
acb_hypgeom_u_asymp(u, one, one, u, -1, prec);
acb_inv(v, v, prec);
acb_submul(t, u, v, prec);
acb_div(t, t, z, prec);
acb_mul_2exp_si(t, t, -1);
acb_neg(t, t);
}
if (acb_is_real(z))
{
if (arb_is_positive(acb_realref(z)))
{
arb_zero(acb_imagref(t));
}
else if (arb_is_negative(acb_realref(z)))
{
arb_const_pi(acb_imagref(t), prec);
}
else
{
/* add [-pi,pi]/2 i */
acb_const_pi(u, prec);
arb_zero(acb_imagref(t));
arb_add_error(acb_imagref(t), acb_realref(u));
}
}
else
{
/* -pi/2 if positive real or in lower half plane
pi/2 if negative real or in upper half plane */
if (arb_is_negative(acb_imagref(z)))
{
acb_const_pi(u, prec);
acb_mul_2exp_si(u, u, -1);
arb_sub(acb_imagref(t), acb_imagref(t), acb_realref(u), prec);
}
else if (arb_is_positive(acb_imagref(z)))
{
acb_const_pi(u, prec);
acb_mul_2exp_si(u, u, -1);
arb_add(acb_imagref(t), acb_imagref(t), acb_realref(u), prec);
}
else
{
/* add [-pi,pi]/2 i */
acb_const_pi(u, prec);
acb_mul_2exp_si(u, u, -1);
arb_add_error(acb_imagref(t), acb_realref(u));
}
}
acb_swap(res, t);
acb_clear(t);
acb_clear(u);
acb_clear(v);
acb_clear(one);
}
int main()
{
slong iter;
flint_rand_t state;
flint_printf("cos_pi_series....");
fflush(stdout);
flint_randinit(state);
for (iter = 0; iter < 1000 * arb_test_multiplier(); iter++)
{
slong m, n1, n2, bits1, bits2, bits3;
acb_poly_t S, A, B, C;
acb_t pi;
bits1 = 2 + n_randint(state, 200);
bits2 = 2 + n_randint(state, 200);
bits3 = 2 + n_randint(state, 200);
m = 1 + n_randint(state, 30);
n1 = 1 + n_randint(state, 30);
n2 = 1 + n_randint(state, 30);
acb_poly_init(S);
acb_poly_init(A);
acb_poly_init(B);
acb_poly_init(C);
acb_init(pi);
acb_poly_randtest(S, state, m, bits1, 3);
acb_poly_randtest(A, state, m, bits1, 3);
acb_poly_randtest(B, state, m, bits1, 3);
acb_poly_cos_pi_series(A, S, n1, bits2);
acb_const_pi(pi, bits3);
acb_poly_set_acb(B, pi);
acb_poly_mul(B, S, B, bits3);
acb_poly_cos_series(B, B, n2, bits3);
acb_poly_set(C, A);
acb_poly_truncate(C, FLINT_MIN(n1, n2));
acb_poly_truncate(B, FLINT_MIN(n1, n2));
if (!acb_poly_overlaps(B, C))
{
flint_printf("FAIL\n\n");
flint_printf("S = "); acb_poly_printd(S, 15); flint_printf("\n\n");
flint_printf("A = "); acb_poly_printd(A, 15); flint_printf("\n\n");
flint_printf("B = "); acb_poly_printd(B, 15); flint_printf("\n\n");
abort();
}
acb_poly_cos_pi_series(S, S, n1, bits2);
if (!acb_poly_overlaps(A, S))
{
flint_printf("FAIL (aliasing)\n\n");
abort();
}
acb_poly_clear(S);
acb_poly_clear(A);
acb_poly_clear(B);
acb_poly_clear(C);
acb_clear(pi);
}
flint_randclear(state);
flint_cleanup();
flint_printf("PASS\n");
return EXIT_SUCCESS;
}
int main()
{
slong iter;
flint_rand_t state;
flint_printf("airy_series....");
fflush(stdout);
flint_randinit(state);
for (iter = 0; iter < 1000 * arb_test_multiplier(); iter++)
{
acb_poly_t ai, aip, bi, bip, ai2, aip2, bi2, bip2, z, w, t;
acb_t c;
slong n1, n2, prec1, prec2;
unsigned int mask;
acb_poly_init(ai); acb_poly_init(aip);
acb_poly_init(bi); acb_poly_init(bip);
acb_poly_init(ai2); acb_poly_init(aip2);
acb_poly_init(bi2); acb_poly_init(bip2);
acb_poly_init(z); acb_poly_init(w);
acb_poly_init(t); acb_init(c);
prec1 = 2 + n_randint(state, 300);
prec2 = 2 + n_randint(state, 300);
n1 = n_randint(state, 6);
n2 = n_randint(state, 6);
acb_poly_randtest(ai, state, 10, prec1, 10);
acb_poly_randtest(aip, state, 10, prec1, 10);
acb_poly_randtest(bi, state, 10, prec1, 10);
acb_poly_randtest(bip, state, 10, prec1, 10);
acb_poly_randtest(z, state, 1 + n_randint(state, 10), prec1, 10);
acb_hypgeom_airy_series(ai, aip, bi, bip, z, n1, prec1);
acb_poly_mullow(w, ai, bip, n1, prec1);
acb_poly_mullow(t, bi, aip, n1, prec1);
acb_poly_sub(w, w, t, prec1);
acb_const_pi(c, prec1);
acb_inv(c, c, prec1);
acb_poly_set_acb(t, c);
acb_poly_truncate(t, n1);
if (!acb_poly_overlaps(w, t))
{
flint_printf("FAIL: wronskian\n\n");
flint_printf("z = "); acb_poly_printd(z, 30); flint_printf("\n\n");
flint_printf("ai = "); acb_poly_printd(ai, 30); flint_printf("\n\n");
flint_printf("aip = "); acb_poly_printd(aip, 30); flint_printf("\n\n");
flint_printf("bi = "); acb_poly_printd(bi, 30); flint_printf("\n\n");
flint_printf("bip = "); acb_poly_printd(bip, 30); flint_printf("\n\n");
flint_printf("w = "); acb_poly_printd(w, 30); flint_printf("\n\n");
abort();
}
mask = n_randlimb(state);
acb_hypgeom_airy_series((mask & 1) ? ai2 : NULL,
(mask & 2) ? aip2 : NULL,
(mask & 4) ? bi2 : NULL,
(mask & 8) ? bip2 : NULL, z, n2, prec2);
acb_poly_truncate(ai, FLINT_MIN(n1, n2));
acb_poly_truncate(aip, FLINT_MIN(n1, n2));
acb_poly_truncate(bi, FLINT_MIN(n1, n2));
acb_poly_truncate(bip, FLINT_MIN(n1, n2));
acb_poly_truncate(ai2, FLINT_MIN(n1, n2));
acb_poly_truncate(aip2, FLINT_MIN(n1, n2));
acb_poly_truncate(bi2, FLINT_MIN(n1, n2));
acb_poly_truncate(bip2, FLINT_MIN(n1, n2));
if (((mask & 1) && (!acb_poly_overlaps(ai, ai2))) ||
((mask & 2) && (!acb_poly_overlaps(aip, aip2))) ||
((mask & 4) && (!acb_poly_overlaps(bi, bi2))) ||
((mask & 8) && (!acb_poly_overlaps(bip, bip2))))
{
flint_printf("FAIL: consistency (mask)\n\n");
flint_printf("mask = %u\n\n", mask);
flint_printf("len1 = %wd, len2 = %wd\n\n", n1, n2);
flint_printf("z = "); acb_poly_printd(z, 30); flint_printf("\n\n");
flint_printf("ai = "); acb_poly_printd(ai, 30); flint_printf("\n\n");
flint_printf("ai2 = "); acb_poly_printd(ai2, 30); flint_printf("\n\n");
flint_printf("aip = "); acb_poly_printd(aip, 30); flint_printf("\n\n");
flint_printf("aip2 = "); acb_poly_printd(aip2, 30); flint_printf("\n\n");
flint_printf("bi = "); acb_poly_printd(bi, 30); flint_printf("\n\n");
flint_printf("bi2 = "); acb_poly_printd(bi2, 30); flint_printf("\n\n");
flint_printf("bip = "); acb_poly_printd(bip, 30); flint_printf("\n\n");
flint_printf("bip2 = "); acb_poly_printd(bip2, 30); flint_printf("\n\n");
abort();
}
acb_poly_clear(ai); acb_poly_clear(aip);
acb_poly_clear(bi); acb_poly_clear(bip);
acb_poly_clear(ai2); acb_poly_clear(aip2);
acb_poly_clear(bi2); acb_poly_clear(bip2);
acb_poly_clear(z); acb_poly_clear(w);
acb_poly_clear(t); acb_clear(c);
}
flint_randclear(state);
flint_cleanup();
flint_printf("PASS\n");
return EXIT_SUCCESS;
}
int main(int argc, char *argv[])
{
acb_t s, t, a, b;
mag_t tol;
slong prec, goal;
slong N;
ulong k;
int integral, ifrom, ito;
int i, twice, havegoal, havetol;
acb_calc_integrate_opt_t options;
ifrom = ito = -1;
for (i = 1; i < argc; i++)
{
if (!strcmp(argv[i], "-i"))
{
if (!strcmp(argv[i+1], "all"))
{
ifrom = 0;
ito = NUM_INTEGRALS - 1;
}
else
{
ifrom = ito = atol(argv[i+1]);
if (ito < 0 || ito >= NUM_INTEGRALS)
flint_abort();
}
}
}
if (ifrom == -1)
{
flint_printf("Compute integrals using acb_calc_integrate.\n");
flint_printf("Usage: integrals -i n [-prec p] [-tol eps] [-twice] [...]\n\n");
flint_printf("-i n - compute integral n (0 <= n <= %d), or \"-i all\"\n", NUM_INTEGRALS - 1);
flint_printf("-prec p - precision in bits (default p = 64)\n");
flint_printf("-goal p - approximate relative accuracy goal (default p)\n");
flint_printf("-tol eps - approximate absolute error goal (default 2^-p)\n");
flint_printf("-twice - run twice (to see overhead of computing nodes)\n");
flint_printf("-heap - use heap for subinterval queue\n");
flint_printf("-verbose - show information\n");
flint_printf("-verbose2 - show more information\n");
flint_printf("-deg n - use quadrature degree up to n\n");
flint_printf("-eval n - limit number of function evaluations to n\n");
flint_printf("-depth n - limit subinterval queue size to n\n\n");
flint_printf("Implemented integrals:\n");
for (integral = 0; integral < NUM_INTEGRALS; integral++)
flint_printf("I%d = %s\n", integral, descr[integral]);
flint_printf("\n");
return 1;
}
acb_calc_integrate_opt_init(options);
prec = 64;
twice = 0;
goal = 0;
havetol = havegoal = 0;
acb_init(a);
acb_init(b);
acb_init(s);
acb_init(t);
mag_init(tol);
for (i = 1; i < argc; i++)
{
if (!strcmp(argv[i], "-prec"))
{
prec = atol(argv[i+1]);
}
else if (!strcmp(argv[i], "-twice"))
{
twice = 1;
}
else if (!strcmp(argv[i], "-goal"))
{
goal = atol(argv[i+1]);
if (goal < 0)
{
flint_printf("expected goal >= 0\n");
return 1;
}
havegoal = 1;
}
else if (!strcmp(argv[i], "-tol"))
{
arb_t x;
arb_init(x);
arb_set_str(x, argv[i+1], 10);
arb_get_mag(tol, x);
arb_clear(x);
havetol = 1;
}
else if (!strcmp(argv[i], "-deg"))
{
options->deg_limit = atol(argv[i+1]);
}
else if (!strcmp(argv[i], "-eval"))
{
options->eval_limit = atol(argv[i+1]);
}
else if (!strcmp(argv[i], "-depth"))
{
options->depth_limit = atol(argv[i+1]);
}
else if (!strcmp(argv[i], "-verbose"))
{
options->verbose = 1;
}
else if (!strcmp(argv[i], "-verbose2"))
{
options->verbose = 2;
}
else if (!strcmp(argv[i], "-heap"))
{
options->use_heap = 1;
}
}
if (!havegoal)
goal = prec;
if (!havetol)
mag_set_ui_2exp_si(tol, 1, -prec);
for (integral = ifrom; integral <= ito; integral++)
{
flint_printf("I%d = %s ...\n", integral, descr[integral]);
for (i = 0; i < 1 + twice; i++)
{
TIMEIT_ONCE_START
switch (integral)
{
case 0:
acb_set_d(a, 0);
acb_set_d(b, 100);
acb_calc_integrate(s, f_sin, NULL, a, b, goal, tol, options, prec);
break;
case 1:
acb_set_d(a, 0);
acb_set_d(b, 1);
acb_calc_integrate(s, f_atanderiv, NULL, a, b, goal, tol, options, prec);
acb_mul_2exp_si(s, s, 2);
break;
case 2:
acb_set_d(a, 0);
acb_one(b);
acb_mul_2exp_si(b, b, goal);
acb_calc_integrate(s, f_atanderiv, NULL, a, b, goal, tol, options, prec);
arb_add_error_2exp_si(acb_realref(s), -goal);
acb_mul_2exp_si(s, s, 1);
break;
case 3:
acb_set_d(a, 0);
acb_set_d(b, 1);
acb_calc_integrate(s, f_circle, NULL, a, b, goal, tol, options, prec);
acb_mul_2exp_si(s, s, 2);
break;
case 4:
acb_set_d(a, 0);
acb_set_d(b, 8);
acb_calc_integrate(s, f_rump, NULL, a, b, goal, tol, options, prec);
break;
case 5:
acb_set_d(a, 1);
acb_set_d(b, 101);
acb_calc_integrate(s, f_floor, NULL, a, b, goal, tol, options, prec);
break;
case 6:
acb_set_d(a, 0);
acb_set_d(b, 1);
acb_calc_integrate(s, f_helfgott, NULL, a, b, goal, tol, options, prec);
break;
case 7:
acb_zero(s);
acb_set_d_d(a, -1.0, -1.0);
acb_set_d_d(b, 2.0, -1.0);
acb_calc_integrate(t, f_zeta, NULL, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, 2.0, -1.0);
acb_set_d_d(b, 2.0, 1.0);
acb_calc_integrate(t, f_zeta, NULL, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, 2.0, 1.0);
acb_set_d_d(b, -1.0, 1.0);
acb_calc_integrate(t, f_zeta, NULL, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, -1.0, 1.0);
acb_set_d_d(b, -1.0, -1.0);
acb_calc_integrate(t, f_zeta, NULL, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_const_pi(t, prec);
acb_div(s, s, t, prec);
acb_mul_2exp_si(s, s, -1);
acb_div_onei(s, s);
break;
case 8:
acb_set_d(a, 0);
acb_set_d(b, 1);
acb_calc_integrate(s, f_essing, NULL, a, b, goal, tol, options, prec);
break;
case 9:
acb_set_d(a, 0);
acb_set_d(b, 1);
acb_calc_integrate(s, f_essing2, NULL, a, b, goal, tol, options, prec);
break;
case 10:
acb_set_d(a, 0);
acb_set_d(b, 10000);
acb_calc_integrate(s, f_factorial1000, NULL, a, b, goal, tol, options, prec);
break;
case 11:
acb_set_d_d(a, 1.0, 0.0);
acb_set_d_d(b, 1.0, 1000.0);
acb_calc_integrate(s, f_gamma, NULL, a, b, goal, tol, options, prec);
break;
case 12:
acb_set_d(a, -10.0);
acb_set_d(b, 10.0);
acb_calc_integrate(s, f_sin_plus_small, NULL, a, b, goal, tol, options, prec);
break;
case 13:
acb_set_d(a, -1020.0);
acb_set_d(b, -1010.0);
acb_calc_integrate(s, f_exp, NULL, a, b, goal, tol, options, prec);
break;
case 14:
acb_set_d(a, 0);
acb_set_d(b, ceil(sqrt(goal * 0.693147181) + 1.0));
acb_calc_integrate(s, f_gaussian, NULL, a, b, goal, tol, options, prec);
acb_mul(b, b, b, prec);
acb_neg(b, b);
acb_exp(b, b, prec);
arb_add_error(acb_realref(s), acb_realref(b));
break;
case 15:
acb_set_d(a, 0.0);
acb_set_d(b, 1.0);
acb_calc_integrate(s, f_spike, NULL, a, b, goal, tol, options, prec);
break;
case 16:
acb_set_d(a, 0.0);
acb_set_d(b, 8.0);
acb_calc_integrate(s, f_monster, NULL, a, b, goal, tol, options, prec);
break;
case 17:
acb_set_d(a, 0);
acb_set_d(b, ceil(goal * 0.693147181 + 1.0));
acb_calc_integrate(s, f_sech, NULL, a, b, goal, tol, options, prec);
acb_neg(b, b);
acb_exp(b, b, prec);
acb_mul_2exp_si(b, b, 1);
arb_add_error(acb_realref(s), acb_realref(b));
break;
case 18:
acb_set_d(a, 0);
acb_set_d(b, ceil(goal * 0.693147181 / 3.0 + 2.0));
acb_calc_integrate(s, f_sech3, NULL, a, b, goal, tol, options, prec);
acb_neg(b, b);
acb_mul_ui(b, b, 3, prec);
acb_exp(b, b, prec);
acb_mul_2exp_si(b, b, 3);
acb_div_ui(b, b, 3, prec);
arb_add_error(acb_realref(s), acb_realref(b));
break;
case 19:
if (goal < 0)
abort();
/* error bound 2^-N (1+N) when truncated at 2^-N */
N = goal + FLINT_BIT_COUNT(goal);
acb_one(a);
acb_mul_2exp_si(a, a, -N);
acb_one(b);
acb_calc_integrate(s, f_log_div1p, NULL, a, b, goal, tol, options, prec);
acb_set_ui(b, N + 1);
acb_mul_2exp_si(b, b, -N);
arb_add_error(acb_realref(s), acb_realref(b));
break;
case 20:
if (goal < 0)
abort();
/* error bound (N+1) exp(-N) when truncated at N */
N = goal + FLINT_BIT_COUNT(goal);
acb_zero(a);
acb_set_ui(b, N);
acb_calc_integrate(s, f_log_div1p_transformed, NULL, a, b, goal, tol, options, prec);
acb_neg(b, b);
acb_exp(b, b, prec);
acb_mul_ui(b, b, N + 1, prec);
arb_add_error(acb_realref(s), acb_realref(b));
break;
case 21:
acb_zero(s);
N = 10;
acb_set_d_d(a, 0.5, -0.5);
acb_set_d_d(b, 0.5, 0.5);
acb_calc_integrate(t, f_elliptic_p_laurent_n, &N, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, 0.5, 0.5);
acb_set_d_d(b, -0.5, 0.5);
acb_calc_integrate(t, f_elliptic_p_laurent_n, &N, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, -0.5, 0.5);
acb_set_d_d(b, -0.5, -0.5);
acb_calc_integrate(t, f_elliptic_p_laurent_n, &N, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, -0.5, -0.5);
acb_set_d_d(b, 0.5, -0.5);
acb_calc_integrate(t, f_elliptic_p_laurent_n, &N, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_const_pi(t, prec);
acb_div(s, s, t, prec);
acb_mul_2exp_si(s, s, -1);
acb_div_onei(s, s);
break;
case 22:
acb_zero(s);
N = 1000;
acb_set_d_d(a, 100.0, 0.0);
acb_set_d_d(b, 100.0, N);
acb_calc_integrate(t, f_zeta_frac, NULL, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_set_d_d(a, 100, N);
acb_set_d_d(b, 0.5, N);
acb_calc_integrate(t, f_zeta_frac, NULL, a, b, goal, tol, options, prec);
acb_add(s, s, t, prec);
acb_div_onei(s, s);
arb_zero(acb_imagref(s));
acb_set_ui(t, N);
acb_dirichlet_hardy_theta(t, t, NULL, NULL, 1, prec);
acb_add(s, s, t, prec);
acb_const_pi(t, prec);
acb_div(s, s, t, prec);
acb_add_ui(s, s, 1, prec);
break;
case 23:
acb_set_d(a, 0.0);
acb_set_d(b, 1000.0);
acb_calc_integrate(s, f_lambertw, NULL, a, b, goal, tol, options, prec);
break;
case 24:
acb_set_d(a, 0.0);
acb_const_pi(b, prec);
acb_calc_integrate(s, f_max_sin_cos, NULL, a, b, goal, tol, options, prec);
break;
case 25:
acb_set_si(a, -1);
acb_set_si(b, 1);
acb_calc_integrate(s, f_erf_bent, NULL, a, b, goal, tol, options, prec);
break;
case 26:
acb_set_si(a, -10);
acb_set_si(b, 10);
acb_calc_integrate(s, f_airy_ai, NULL, a, b, goal, tol, options, prec);
break;
case 27:
acb_set_si(a, 0);
acb_set_si(b, 10);
acb_calc_integrate(s, f_horror, NULL, a, b, goal, tol, options, prec);
break;
case 28:
acb_set_d_d(a, -1, -1);
acb_set_d_d(b, -1, 1);
acb_calc_integrate(s, f_sqrt, NULL, a, b, goal, tol, options, prec);
break;
case 29:
acb_set_d(a, 0);
acb_set_d(b, ceil(sqrt(goal * 0.693147181) + 1.0));
acb_calc_integrate(s, f_gaussian_twist, NULL, a, b, goal, tol, options, prec);
acb_mul(b, b, b, prec);
acb_neg(b, b);
acb_exp(b, b, prec);
arb_add_error(acb_realref(s), acb_realref(b));
arb_add_error(acb_imagref(s), acb_realref(b));
break;
case 30:
acb_set_d(a, 0);
acb_set_d(b, ceil(goal * 0.693147181 + 1.0));
acb_calc_integrate(s, f_exp_airy, NULL, a, b, goal, tol, options, prec);
acb_neg(b, b);
acb_exp(b, b, prec);
acb_mul_2exp_si(b, b, 1);
arb_add_error(acb_realref(s), acb_realref(b));
break;
case 31:
acb_zero(a);
acb_const_pi(b, prec);
acb_calc_integrate(s, f_sin_cos_frac, NULL, a, b, goal, tol, options, prec);
break;
case 32:
acb_zero(a);
acb_set_ui(b, 3);
acb_calc_integrate(s, f_sin_near_essing, NULL, a, b, goal, tol, options, prec);
break;
case 33:
acb_zero(a);
acb_zero(b);
k = 3;
scaled_bessel_select_N(acb_realref(b), k, prec);
acb_calc_integrate(s, f_scaled_bessel, &k, a, b, goal, tol, options, prec);
scaled_bessel_tail_bound(acb_realref(a), k, acb_realref(b), prec);
arb_add_error(acb_realref(s), acb_realref(a));
break;
case 34:
acb_zero(a);
acb_zero(b);
k = 15;
scaled_bessel_select_N(acb_realref(b), k, prec);
acb_calc_integrate(s, f_scaled_bessel, &k, a, b, goal, tol, options, prec);
scaled_bessel_tail_bound(acb_realref(a), k, acb_realref(b), prec);
arb_add_error(acb_realref(s), acb_realref(a));
break;
case 35:
acb_set_d_d(a, -1, -1);
acb_set_d_d(b, -1, 1);
acb_calc_integrate(s, f_rsqrt, NULL, a, b, goal, tol, options, prec);
break;
default:
abort();
}
TIMEIT_ONCE_STOP
}
flint_printf("I%d = ", integral);
acb_printn(s, 3.333 * prec, 0);
flint_printf("\n\n");
}
acb_clear(a);
acb_clear(b);
acb_clear(s);
acb_clear(t);
mag_clear(tol);
flint_cleanup();
return 0;
}
void
acb_hypgeom_ci_asymp(acb_t res, const acb_t z, slong prec)
{
acb_t t, u, w, v, one;
acb_init(t);
acb_init(u);
acb_init(w);
acb_init(v);
acb_init(one);
acb_one(one);
acb_mul_onei(w, z);
/* u = U(1,1,iz) */
acb_hypgeom_u_asymp(u, one, one, w, -1, prec);
/* v = e^(-iz) */
acb_neg(v, w);
acb_exp(v, v, prec);
acb_mul(t, u, v, prec);
if (acb_is_real(z))
{
arb_div(acb_realref(t), acb_imagref(t), acb_realref(z), prec);
arb_zero(acb_imagref(t));
acb_neg(t, t);
}
else
{
/* u = U(1,1,-iz) */
acb_neg(w, w);
acb_hypgeom_u_asymp(u, one, one, w, -1, prec);
acb_inv(v, v, prec);
acb_submul(t, u, v, prec);
acb_div(t, t, w, prec);
acb_mul_2exp_si(t, t, -1);
}
if (arb_is_zero(acb_realref(z)))
{
if (arb_is_positive(acb_imagref(z)))
{
arb_const_pi(acb_imagref(t), prec);
arb_mul_2exp_si(acb_imagref(t), acb_imagref(t), -1);
}
else if (arb_is_negative(acb_imagref(z)))
{
arb_const_pi(acb_imagref(t), prec);
arb_mul_2exp_si(acb_imagref(t), acb_imagref(t), -1);
arb_neg(acb_imagref(t), acb_imagref(t));
}
else
{
acb_const_pi(u, prec);
acb_mul_2exp_si(u, u, -1);
arb_zero(acb_imagref(t));
arb_add_error(acb_imagref(t), acb_realref(u));
}
}
else
{
/* 0 if positive or positive imaginary
pi if upper left quadrant (including negative real axis)
-pi if lower left quadrant (including negative imaginary axis) */
if (arb_is_positive(acb_realref(z)))
{
/* do nothing */
}
else if (arb_is_negative(acb_realref(z)) && arb_is_nonnegative(acb_imagref(z)))
{
acb_const_pi(u, prec);
arb_add(acb_imagref(t), acb_imagref(t), acb_realref(u), prec);
}
else if (arb_is_nonpositive(acb_realref(z)) && arb_is_negative(acb_imagref(z)))
{
acb_const_pi(u, prec);
arb_sub(acb_imagref(t), acb_imagref(t), acb_realref(u), prec);
}
else
{
/* add [-pi,pi] */
acb_const_pi(u, prec);
arb_add_error(acb_imagref(t), acb_realref(u));
}
}
acb_swap(res, t);
acb_clear(t);
acb_clear(u);
acb_clear(w);
acb_clear(v);
acb_clear(one);
}
void
acb_dirichlet_zeta_rs_mid(acb_t res, const acb_t s, slong K, slong prec)
{
acb_t R1, R2, X, t;
slong wp;
if (arf_sgn(arb_midref(acb_imagref(s))) < 0)
{
acb_init(t);
acb_conj(t, s);
acb_dirichlet_zeta_rs(res, t, K, prec);
acb_conj(res, res);
acb_clear(t);
return;
}
acb_init(R1);
acb_init(R2);
acb_init(X);
acb_init(t);
/* rs_r increases the precision internally */
wp = prec;
acb_dirichlet_zeta_rs_r(R1, s, K, wp);
if (arb_is_exact(acb_realref(s)) &&
(arf_cmp_2exp_si(arb_midref(acb_realref(s)), -1) == 0))
{
acb_conj(R2, R1);
}
else
{
/* conj(R(conj(1-s))) */
arb_sub_ui(acb_realref(t), acb_realref(s), 1, 10 * wp);
arb_neg(acb_realref(t), acb_realref(t));
arb_set(acb_imagref(t), acb_imagref(s));
acb_dirichlet_zeta_rs_r(R2, t, K, wp);
acb_conj(R2, R2);
}
if (acb_is_finite(R1) && acb_is_finite(R2))
{
wp += 10 + arf_abs_bound_lt_2exp_si(arb_midref(acb_imagref(s)));
wp = FLINT_MAX(wp, 10);
/* X = pi^(s-1/2) gamma((1-s)/2) rgamma(s/2)
= (2 pi)^s rgamma(s) / (2 cos(pi s / 2)) */
acb_rgamma(X, s, wp);
acb_const_pi(t, wp);
acb_mul_2exp_si(t, t, 1);
acb_pow(t, t, s, wp);
acb_mul(X, X, t, wp);
acb_mul_2exp_si(t, s, -1);
acb_cos_pi(t, t, wp);
acb_mul_2exp_si(t, t, 1);
acb_div(X, X, t, wp);
acb_mul(R2, R2, X, wp);
}
/* R1 + X * R2 */
acb_add(res, R1, R2, prec);
acb_clear(R1);
acb_clear(R2);
acb_clear(X);
acb_clear(t);
}
int main()
{
long iter;
flint_rand_t state;
printf("bessel_j....");
fflush(stdout);
flint_randinit(state);
for (iter = 0; iter < 2000; iter++)
{
acb_t nu0, nu1, nu2, z, w0, w1, w2, t, u;
long prec0, prec1, prec2;
acb_init(nu0);
acb_init(nu1);
acb_init(nu2);
acb_init(z);
acb_init(w0);
acb_init(w1);
acb_init(w2);
acb_init(t);
acb_init(u);
prec0 = 2 + n_randint(state, 1000);
prec1 = 2 + n_randint(state, 1000);
prec2 = 2 + n_randint(state, 1000);
acb_randtest_param(nu0, state, 1 + n_randint(state, 1000), 1 + n_randint(state, 100));
acb_randtest(z, state, 1 + n_randint(state, 1000), 1 + n_randint(state, 100));
acb_randtest(w0, state, 1 + n_randint(state, 1000), 1 + n_randint(state, 100));
acb_randtest(w1, state, 1 + n_randint(state, 1000), 1 + n_randint(state, 100));
acb_randtest(w2, state, 1 + n_randint(state, 1000), 1 + n_randint(state, 100));
acb_sub_ui(nu1, nu0, 1, prec0);
acb_sub_ui(nu2, nu0, 2, prec0);
switch (n_randint(state, 3))
{
case 0:
acb_hypgeom_bessel_j_asymp(w0, nu0, z, prec0);
break;
case 1:
acb_hypgeom_bessel_j_0f1(w0, nu0, z, prec0);
break;
default:
acb_hypgeom_bessel_j(w0, nu0, z, prec0);
}
switch (n_randint(state, 3))
{
case 0:
acb_hypgeom_bessel_j_asymp(w1, nu0, z, prec1);
break;
case 1:
acb_hypgeom_bessel_j_0f1(w1, nu0, z, prec1);
break;
default:
acb_hypgeom_bessel_j(w1, nu0, z, prec1);
}
if (!acb_overlaps(w0, w1))
{
printf("FAIL: consistency\n\n");
printf("nu = "); acb_printd(nu0, 30); printf("\n\n");
printf("z = "); acb_printd(z, 30); printf("\n\n");
printf("w0 = "); acb_printd(w0, 30); printf("\n\n");
printf("w1 = "); acb_printd(w1, 30); printf("\n\n");
abort();
}
switch (n_randint(state, 3))
{
case 0:
acb_hypgeom_bessel_j_asymp(w1, nu1, z, prec1);
break;
case 1:
acb_hypgeom_bessel_j_0f1(w1, nu1, z, prec1);
break;
default:
acb_hypgeom_bessel_j(w1, nu1, z, prec1);
}
switch (n_randint(state, 3))
{
case 0:
acb_hypgeom_bessel_j_asymp(w2, nu2, z, prec2);
break;
case 1:
acb_hypgeom_bessel_j_0f1(w2, nu2, z, prec2);
break;
default:
acb_hypgeom_bessel_j(w2, nu2, z, prec2);
}
acb_mul(t, w1, nu1, prec0);
acb_mul_2exp_si(t, t, 1);
acb_submul(t, w2, z, prec0);
acb_submul(t, w0, z, prec0);
if (!acb_contains_zero(t))
{
printf("FAIL: contiguous relation\n\n");
printf("nu = "); acb_printd(nu0, 30); printf("\n\n");
printf("z = "); acb_printd(z, 30); printf("\n\n");
printf("w0 = "); acb_printd(w0, 30); printf("\n\n");
printf("w1 = "); acb_printd(w1, 30); printf("\n\n");
printf("w2 = "); acb_printd(w2, 30); printf("\n\n");
printf("t = "); acb_printd(t, 30); printf("\n\n");
abort();
}
acb_neg(t, nu0);
switch (n_randint(state, 3))
{
case 0:
acb_hypgeom_bessel_j_asymp(w2, t, z, prec2);
break;
case 1:
acb_hypgeom_bessel_j_0f1(w2, t, z, prec2);
break;
default:
acb_hypgeom_bessel_j(w2, t, z, prec2);
}
acb_mul(w1, w1, w2, prec2);
acb_neg(t, nu1);
switch (n_randint(state, 3))
{
case 0:
acb_hypgeom_bessel_j_asymp(w2, t, z, prec2);
break;
case 1:
acb_hypgeom_bessel_j_0f1(w2, t, z, prec2);
break;
default:
acb_hypgeom_bessel_j(w2, t, z, prec2);
}
acb_mul(w0, w0, w2, prec2);
acb_add(w0, w0, w1, prec2);
acb_sin_pi(t, nu0, prec2);
acb_const_pi(u, prec2);
acb_mul(u, u, z, prec2);
acb_div(t, t, u, prec2);
acb_mul_2exp_si(t, t, 1);
if (!acb_overlaps(w0, t))
{
printf("FAIL: wronskian\n\n");
printf("nu = "); acb_printd(nu0, 30); printf("\n\n");
printf("z = "); acb_printd(z, 30); printf("\n\n");
printf("w0 = "); acb_printd(w0, 30); printf("\n\n");
printf("t = "); acb_printd(t, 30); printf("\n\n");
abort();
}
acb_clear(nu0);
acb_clear(nu1);
acb_clear(nu2);
acb_clear(z);
acb_clear(w0);
acb_clear(w1);
acb_clear(w2);
acb_clear(t);
acb_clear(u);
}
flint_randclear(state);
flint_cleanup();
printf("PASS\n");
return EXIT_SUCCESS;
}
void
_acb_poly_lgamma_series(acb_ptr res, acb_srcptr h, slong hlen, slong len, slong prec)
{
int reflect;
slong i, r, n, wp;
acb_t zr;
acb_ptr t, u;
hlen = FLINT_MIN(hlen, len);
if (hlen == 1)
{
acb_lgamma(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 (len == 2)
{
acb_t v;
acb_init(v);
acb_set(v, h + 1);
acb_digamma(res + 1, h, prec);
acb_lgamma(res, h, prec);
acb_mul(res + 1, res + 1, v, prec);
acb_clear(v);
return;
}
/* use real code for real input and output */
if (_acb_vec_is_real(h, hlen) && arb_is_positive(acb_realref(h)))
{
arb_ptr tmp = _arb_vec_init(len);
for (i = 0; i < hlen; i++)
arb_set(tmp + i, acb_realref(h + i));
_arb_poly_lgamma_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);
acb_init(zr);
/* use Stirling series */
acb_gamma_stirling_choose_param(&reflect, &r, &n, h, 1, 0, wp);
if (reflect)
{
/* log gamma(h+x) = log rf(1-(h+x), r) - log gamma(1-(h+x)+r) - log sin(pi (h+x)) + log(pi) */
if (r != 0) /* otherwise t = 0 */
{
acb_sub_ui(u, h, 1, wp);
acb_neg(u, u);
_log_rising_ui_series(t, u, r, len, wp);
for (i = 1; i < len; i += 2)
acb_neg(t + i, t + i);
}
acb_sub_ui(u, h, 1, wp);
acb_neg(u, u);
acb_add_ui(zr, u, r, wp);
_acb_poly_gamma_stirling_eval(u, zr, n, len, wp);
for (i = 1; i < len; i += 2)
acb_neg(u + i, u + i);
_acb_vec_sub(t, t, u, len, wp);
/* log(sin) is unstable with large imaginary parts;
cot_pi is implemented in a numerically stable way */
acb_set(u, h);
acb_one(u + 1);
_acb_poly_cot_pi_series(u, u, 2, len - 1, wp);
_acb_poly_integral(u, u, len, wp);
acb_const_pi(u, wp);
_acb_vec_scalar_mul(u + 1, u + 1, len - 1, u, wp);
acb_log_sin_pi(u, h, wp);
_acb_vec_sub(u, t, u, len, wp);
acb_const_pi(t, wp); /* todo: constant for log pi */
acb_log(t, t, wp);
acb_add(u, u, t, wp);
}
else
{
/* log gamma(x) = log gamma(x+r) - log rf(x,r) */
acb_add_ui(zr, h, r, wp);
_acb_poly_gamma_stirling_eval(u, zr, n, len, wp);
if (r != 0)
{
_log_rising_ui_series(t, h, r, len, wp);
_acb_vec_sub(u, u, t, len, wp);
}
}
/* compose with nonconstant part */
acb_zero(t);
_acb_vec_set(t + 1, h + 1, hlen - 1);
_acb_poly_compose_series(res, u, len, t, hlen, len, prec);
acb_clear(zr);
_acb_vec_clear(t, len);
_acb_vec_clear(u, len);
}
void
acb_hypgeom_bessel_k_0f1(acb_t res, const acb_t nu, const acb_t z, slong prec)
{
if (acb_is_int(nu))
{
acb_poly_t nux, zx, rx;
acb_poly_init(nux);
acb_poly_init(zx);
acb_poly_init(rx);
acb_poly_set_coeff_acb(nux, 0, nu);
acb_poly_set_coeff_si(nux, 1, 1);
acb_poly_set_acb(zx, z);
acb_hypgeom_bessel_k_0f1_series(rx, nux, zx, 1, prec);
acb_poly_get_coeff_acb(res, rx, 0);
acb_poly_clear(nux);
acb_poly_clear(zx);
acb_poly_clear(rx);
}
else
{
acb_t t, u, v, w;
acb_struct b[2];
acb_init(t);
acb_init(u);
acb_init(v);
acb_init(w);
acb_init(b + 0);
acb_init(b + 1);
/* u = 0F1(1+nu), v = 0F1(1-nu) */
acb_mul(t, z, z, prec);
acb_mul_2exp_si(t, t, -2);
acb_add_ui(b, nu, 1, prec);
acb_one(b + 1);
acb_hypgeom_pfq_direct(u, NULL, 0, b, 2, t, -1, prec);
acb_sub_ui(b, nu, 1, prec);
acb_neg(b, b);
acb_hypgeom_pfq_direct(v, NULL, 0, b, 2, t, -1, prec);
/* v = v * gamma(nu) / (z/2)^nu */
acb_mul_2exp_si(t, z, -1);
acb_pow(t, t, nu, prec);
acb_gamma(w, nu, prec);
acb_mul(v, v, w, prec);
acb_div(v, v, t, prec);
/* u = u * t * pi / (gamma(nu) * nu * sin(pi nu)) */
acb_mul(u, u, t, prec);
acb_const_pi(t, prec);
acb_mul(u, u, t, prec);
acb_sin_pi(t, nu, prec);
acb_mul(t, t, w, prec);
acb_mul(t, t, nu, prec);
acb_div(u, u, t, prec);
acb_sub(res, v, u, prec);
acb_mul_2exp_si(res, res, -1);
acb_clear(t);
acb_clear(u);
acb_clear(v);
acb_clear(w);
acb_clear(b + 0);
acb_clear(b + 1);
}
}
int main(int argc, char *argv[])
{
acb_t r, s, a, b;
arf_t inr, outr;
long digits, prec;
if (argc < 2)
{
printf("integrals d\n");
printf("compute integrals using d decimal digits of precision\n");
return 1;
}
acb_init(r);
acb_init(s);
acb_init(a);
acb_init(b);
arf_init(inr);
arf_init(outr);
arb_calc_verbose = 0;
digits = atol(argv[1]);
prec = digits * 3.32193;
printf("Digits: %ld\n", digits);
printf("----------------------------------------------------------------\n");
printf("Integral of sin(t) from 0 to 100.\n");
arf_set_d(inr, 0.125);
arf_set_d(outr, 1.0);
TIMEIT_ONCE_START
acb_set_si(a, 0);
acb_set_si(b, 100);
acb_calc_integrate_taylor(r, sinx, NULL, a, b, inr, outr, prec, 1.1 * prec);
printf("RESULT:\n");
acb_printd(r, digits); printf("\n");
TIMEIT_ONCE_STOP
printf("----------------------------------------------------------------\n");
printf("Elliptic integral F(phi, m) = integral of 1/sqrt(1 - m*sin(t)^2)\n");
printf("from 0 to phi, with phi = 6+6i, m = 1/2. Integration path\n");
printf("0 -> 6 -> 6+6i.\n");
arf_set_d(inr, 0.2);
arf_set_d(outr, 0.5);
TIMEIT_ONCE_START
acb_set_si(a, 0);
acb_set_si(b, 6);
acb_calc_integrate_taylor(r, elliptic, NULL, a, b, inr, outr, prec, 1.1 * prec);
acb_set_si(a, 6);
arb_set_si(acb_realref(b), 6);
arb_set_si(acb_imagref(b), 6);
acb_calc_integrate_taylor(s, elliptic, NULL, a, b, inr, outr, prec, 1.1 * prec);
acb_add(r, r, s, prec);
printf("RESULT:\n");
acb_printd(r, digits); printf("\n");
TIMEIT_ONCE_STOP
printf("----------------------------------------------------------------\n");
printf("Bessel function J_n(z) = (1/pi) * integral of cos(t*n - z*sin(t))\n");
printf("from 0 to pi. With n = 10, z = 20 + 10i.\n");
arf_set_d(inr, 0.1);
arf_set_d(outr, 0.5);
TIMEIT_ONCE_START
acb_set_si(a, 0);
acb_const_pi(b, 3 * prec);
acb_calc_integrate_taylor(r, bessel, NULL, a, b, inr, outr, prec, 3 * prec);
acb_div(r, r, b, prec);
printf("RESULT:\n");
acb_printd(r, digits); printf("\n");
TIMEIT_ONCE_STOP
acb_clear(r);
acb_clear(s);
acb_clear(a);
acb_clear(b);
arf_clear(inr);
arf_clear(outr);
flint_cleanup();
return 0;
}
void
_acb_poly_sin_cos_series_tangent(acb_ptr s, acb_ptr c,
const acb_srcptr h, slong hlen, slong len, slong prec, int times_pi)
{
acb_ptr t, u, v;
acb_t s0, c0;
hlen = FLINT_MIN(hlen, len);
if (hlen == 1)
{
if (times_pi)
acb_sin_cos_pi(s, c, h, prec);
else
acb_sin_cos(s, c, h, prec);
_acb_vec_zero(s + 1, len - 1);
_acb_vec_zero(c + 1, len - 1);
return;
}
/*
sin(x) = 2*tan(x/2)/(1+tan(x/2)^2)
cos(x) = (1-tan(x/2)^2)/(1+tan(x/2)^2)
*/
acb_init(s0);
acb_init(c0);
t = _acb_vec_init(3 * len);
u = t + len;
v = u + len;
/* sin, cos of h0 */
if (times_pi)
acb_sin_cos_pi(s0, c0, h, prec);
else
acb_sin_cos(s0, c0, h, prec);
/* t = tan((h-h0)/2) */
acb_zero(u);
_acb_vec_scalar_mul_2exp_si(u + 1, h + 1, hlen - 1, -1);
if (times_pi)
{
acb_const_pi(t, prec);
_acb_vec_scalar_mul(u + 1, u + 1, hlen - 1, t, prec);
}
_acb_poly_tan_series(t, u, hlen, len, prec);
/* v = 1 + t^2 */
_acb_poly_mullow(v, t, len, t, len, len, prec);
acb_add_ui(v, v, 1, prec);
/* u = 1/(1+t^2) */
_acb_poly_inv_series(u, v, len, len, prec);
/* sine */
_acb_poly_mullow(s, t, len, u, len, len, prec);
_acb_vec_scalar_mul_2exp_si(s, s, len, 1);
/* cosine */
acb_sub_ui(v, v, 2, prec);
_acb_vec_neg(v, v, len);
_acb_poly_mullow(c, v, len, u, len, len, prec);
/* sin(h0 + h1) = cos(h0) sin(h1) + sin(h0) cos(h1)
cos(h0 + h1) = cos(h0) cos(h1) - sin(h0) sin(h1) */
if (!acb_is_zero(s0))
{
_acb_vec_scalar_mul(t, s, len, c0, prec);
_acb_vec_scalar_mul(u, c, len, s0, prec);
_acb_vec_scalar_mul(v, s, len, s0, prec);
_acb_vec_add(s, t, u, len, prec);
_acb_vec_scalar_mul(t, c, len, c0, prec);
_acb_vec_sub(c, t, v, len, prec);
}
_acb_vec_clear(t, 3 * len);
acb_clear(s0);
acb_clear(c0);
}
int main()
{
long iter;
flint_rand_t state;
printf("legendre_q....");
fflush(stdout);
flint_randinit(state);
for (iter = 0; iter < 1000; iter++)
{
acb_t n, m, z, res1, res2;
long prec1, prec2, ebits;
acb_init(n);
acb_init(m);
acb_init(z);
acb_init(res1);
acb_init(res2);
prec1 = 2 + n_randint(state, 300);
prec2 = 2 + n_randint(state, 300);
ebits = 1 + n_randint(state, 10);
if (n_randint(state, 2))
{
acb_set_si(m, n_randint(state, 20) - 10);
acb_set_si(n, n_randint(state, 20) - 10);
}
else
{
acb_randtest_param(n, state, 1 + n_randint(state, 400), ebits);
acb_randtest_param(m, state, 1 + n_randint(state, 400), ebits);
}
acb_randtest_param(z, state, 1 + n_randint(state, 400), ebits);
_acb_hypgeom_legendre_q_single(res1, n, m, z, prec1);
_acb_hypgeom_legendre_q_double(res2, n, m, z, prec2);
if (!acb_overlaps(res1, res2))
{
printf("FAIL: consistency 1\n\n");
printf("iter = %ld, prec1 = %ld, prec2 = %ld\n\n", iter, prec1, prec2);
printf("m = "); acb_printd(m, 30); printf("\n\n");
printf("n = "); acb_printd(n, 30); printf("\n\n");
printf("z = "); acb_printd(z, 30); printf("\n\n");
printf("res1 = "); acb_printd(res1, 30); printf("\n\n");
printf("res2 = "); acb_printd(res2, 30); printf("\n\n");
abort();
}
acb_clear(n);
acb_clear(m);
acb_clear(z);
acb_clear(res1);
acb_clear(res2);
}
for (iter = 0; iter < 2000; iter++)
{
acb_t n, m, z, res1, res2, t, u;
long prec1, prec2, ebits;
int type;
acb_init(n);
acb_init(m);
acb_init(z);
acb_init(res1);
acb_init(res2);
acb_init(t);
acb_init(u);
prec1 = 2 + n_randint(state, 300);
prec2 = 2 + n_randint(state, 300);
ebits = 1 + n_randint(state, 10);
if (n_randint(state, 2))
{
acb_set_si(m, n_randint(state, 20) - 10);
acb_set_si(n, n_randint(state, 20) - 10);
}
else
{
acb_randtest_param(n, state, 1 + n_randint(state, 400), ebits);
acb_randtest_param(m, state, 1 + n_randint(state, 400), ebits);
}
acb_randtest_param(z, state, 1 + n_randint(state, 400), ebits);
type = n_randint(state, 2);
acb_hypgeom_legendre_q(res1, n, m, z, type, prec1);
acb_neg(t, m);
acb_hypgeom_legendre_p(res2, n, t, z, type, prec2);
acb_add(u, m, n, prec2);
acb_add_ui(u, u, 1, prec2);
acb_gamma(u, u, prec2);
acb_mul(res2, res2, u, prec2);
acb_sub(u, n, m, prec2);
acb_add_ui(u, u, 1, prec2);
acb_rgamma(u, u, prec2);
acb_mul(res2, res2, u, prec2);
acb_hypgeom_legendre_p(t, n, m, z, type, prec2);
if (type == 0)
{
acb_cos_pi(u, m, prec2);
acb_mul(t, t, u, prec2);
}
acb_sub(res2, t, res2, prec2);
if (type == 1)
{
acb_exp_pi_i(t, m, prec2);
acb_mul(res2, res2, t, prec2);
}
acb_sin_pi(t, m, prec2);
if (acb_contains_zero(t))
acb_indeterminate(res2);
else
acb_div(res2, res2, t, prec2);
acb_const_pi(t, prec2);
acb_mul(res2, res2, t, prec2);
acb_mul_2exp_si(res2, res2, -1);
if (!acb_overlaps(res1, res2))
{
printf("FAIL: consistency 2\n\n");
printf("iter = %ld, prec1 = %ld, prec2 = %ld\n\n", iter, prec1, prec2);
printf("type = %d\n\n", type);
printf("m = "); acb_printd(m, 30); printf("\n\n");
printf("n = "); acb_printd(n, 30); printf("\n\n");
printf("z = "); acb_printd(z, 30); printf("\n\n");
printf("res1 = "); acb_printd(res1, 30); printf("\n\n");
printf("res2 = "); acb_printd(res2, 30); printf("\n\n");
abort();
}
acb_clear(n);
acb_clear(m);
acb_clear(z);
acb_clear(res1);
acb_clear(res2);
acb_clear(t);
acb_clear(u);
}
flint_randclear(state);
flint_cleanup();
printf("PASS\n");
return EXIT_SUCCESS;
}
int main()
{
slong iter;
flint_rand_t state;
flint_printf("exp_pi_i....");
fflush(stdout);
flint_randinit(state);
for (iter = 0; iter < 10000 * arb_test_multiplier(); iter++)
{
acb_t a, b, c, d;
slong prec;
acb_init(a);
acb_init(b);
acb_init(c);
acb_init(d);
acb_randtest(a, state, 1 + n_randint(state, 200), 3);
acb_randtest(b, state, 1 + n_randint(state, 200), 3);
acb_randtest(c, state, 1 + n_randint(state, 200), 3);
acb_randtest(d, state, 1 + n_randint(state, 200), 3);
prec = 2 + n_randint(state, 200);
acb_exp_pi_i(b, a, prec);
acb_const_pi(c, prec);
acb_mul(c, c, a, prec);
acb_mul_onei(c, c);
acb_exp(d, c, prec);
if (!acb_overlaps(d, b))
{
flint_printf("FAIL: overlap\n\n");
flint_printf("a = "); acb_printd(a, 30); flint_printf("\n\n");
flint_printf("b = "); acb_printd(b, 30); flint_printf("\n\n");
flint_printf("c = "); acb_printd(c, 30); flint_printf("\n\n");
flint_printf("d = "); acb_printd(d, 30); flint_printf("\n\n");
abort();
}
acb_set(c, a);
acb_exp_pi_i(c, c, prec);
if (!acb_overlaps(c, d))
{
flint_printf("FAIL: aliasing\n\n");
flint_printf("a = "); acb_print(a); flint_printf("\n\n");
flint_printf("b = "); acb_print(b); flint_printf("\n\n");
flint_printf("c = "); acb_print(c); flint_printf("\n\n");
flint_printf("d = "); acb_print(d); flint_printf("\n\n");
abort();
}
acb_clear(a);
acb_clear(b);
acb_clear(c);
acb_clear(d);
}
flint_randclear(state);
flint_cleanup();
flint_printf("PASS\n");
return EXIT_SUCCESS;
}
void
acb_modular_eisenstein(acb_ptr r, const acb_t tau, slong len, slong prec)
{
psl2z_t g;
arf_t one_minus_eps;
acb_t tau_prime, t1, t2, t3, t4, q;
slong m, n;
if (len < 1)
return;
psl2z_init(g);
arf_init(one_minus_eps);
acb_init(tau_prime);
acb_init(t1);
acb_init(t2);
acb_init(t3);
acb_init(t4);
acb_init(q);
arf_set_ui_2exp_si(one_minus_eps, 63, -6);
acb_modular_fundamental_domain_approx(tau_prime, g, tau,
one_minus_eps, prec);
acb_exp_pi_i(q, tau_prime, prec);
acb_modular_theta_const_sum(t2, t3, t4, q, prec);
/* fourth powers of the theta functions (a, b, c) */
acb_mul(t2, t2, t2, prec);
acb_mul(t2, t2, t2, prec);
acb_mul(t2, t2, q, prec);
acb_mul(t3, t3, t3, prec);
acb_mul(t3, t3, t3, prec);
acb_mul(t4, t4, t4, prec);
acb_mul(t4, t4, t4, prec);
/* c2 = pi^4 * (a^8 + b^8 + c^8) / 30 */
/* c3 = pi^6 * (b^12 + c^12 - 3a^8 * (b^4+c^4)) / 180 */
/* r = a^8 */
acb_mul(r, t2, t2, prec);
if (len > 1)
{
/* r[1] = -3 a^8 * (b^4 + c^4) */
acb_add(r + 1, t3, t4, prec);
acb_mul(r + 1, r + 1, r, prec);
acb_mul_si(r + 1, r + 1, -3, prec);
}
/* b^8 */
acb_mul(t1, t3, t3, prec);
acb_add(r, r, t1, prec);
/* b^12 */
if (len > 1)
acb_addmul(r + 1, t1, t3, prec);
/* c^8 */
acb_mul(t1, t4, t4, prec);
acb_add(r, r, t1, prec);
/* c^12 */
if (len > 1)
acb_addmul(r + 1, t1, t4, prec);
acb_const_pi(t1, prec);
acb_mul(t1, t1, t1, prec);
acb_mul(t2, t1, t1, prec);
acb_mul(r, r, t2, prec);
acb_div_ui(r, r, 30, prec);
if (len > 1)
{
acb_mul(t2, t2, t1, prec);
acb_mul(r + 1, r + 1, t2, prec);
acb_div_ui(r + 1, r + 1, 189, prec);
}
/* apply modular transformation */
if (!fmpz_is_zero(&g->c))
{
acb_mul_fmpz(t1, tau, &g->c, prec);
acb_add_fmpz(t1, t1, &g->d, prec);
acb_inv(t1, t1, prec);
acb_mul(t1, t1, t1, prec);
acb_mul(t2, t1, t1, prec);
acb_mul(r, r, t2, prec);
if (len > 1)
{
acb_mul(t2, t1, t2, prec);
acb_mul(r + 1, r + 1, t2, prec);
}
}
/* compute more coefficients using recurrence */
for (n = 4; n < len + 2; n++)
{
acb_zero(r + n - 2);
m = 2;
for (m = 2; m * 2 < n; m++)
acb_addmul(r + n - 2, r + m - 2, r + n - m - 2, prec);
acb_mul_2exp_si(r + n - 2, r + n - 2, 1);
if (n % 2 == 0)
acb_addmul(r + n - 2, r + n / 2 - 2, r + n / 2 - 2, prec);
acb_mul_ui(r + n - 2, r + n - 2, 3, prec);
acb_div_ui(r + n - 2, r + n - 2, (2 * n + 1) * (n - 3), prec);
}
/* convert c's to G's */
for (n = 0; n < len; n++)
acb_div_ui(r + n, r + n, 2 * n + 3, prec);
psl2z_clear(g);
arf_clear(one_minus_eps);
acb_clear(tau_prime);
acb_clear(t1);
acb_clear(t2);
acb_clear(t3);
acb_clear(t4);
acb_clear(q);
}
/* todo: use log(1-z) when this is better? would also need to
adjust strategy in the main function */
void
acb_hypgeom_dilog_bernoulli(acb_t res, const acb_t z, slong prec)
{
acb_t s, w, w2;
slong n, k;
fmpz_t c, d;
mag_t m, err;
double lm;
int real;
acb_init(s);
acb_init(w);
acb_init(w2);
fmpz_init(c);
fmpz_init(d);
mag_init(m);
mag_init(err);
real = 0;
if (acb_is_real(z))
{
arb_sub_ui(acb_realref(w), acb_realref(z), 1, 30);
real = arb_is_nonpositive(acb_realref(w));
}
acb_log(w, z, prec);
acb_get_mag(m, w);
/* for k >= 4, the terms are bounded by (|w| / (2 pi))^k */
mag_set_ui_2exp_si(err, 2670177, -24); /* upper bound for 1/(2pi) */
mag_mul(err, err, m);
lm = mag_get_d_log2_approx(err);
if (lm < -0.25)
{
n = prec / (-lm) + 1;
n = FLINT_MAX(n, 4);
mag_geom_series(err, err, n);
BERNOULLI_ENSURE_CACHED(n)
acb_mul(w2, w, w, prec);
for (k = n - (n % 2 == 0); k >= 3; k -= 2)
{
fmpz_mul_ui(c, fmpq_denref(bernoulli_cache + k - 1), k - 1);
fmpz_mul_ui(d, c, (k + 1) * (k + 2));
acb_mul(s, s, w2, prec);
acb_mul_fmpz(s, s, c, prec);
fmpz_mul_ui(c, fmpq_numref(bernoulli_cache + k - 1), (k + 1) * (k + 2));
acb_sub_fmpz(s, s, c, prec);
acb_div_fmpz(s, s, d, prec);
}
acb_mul(s, s, w, prec);
acb_mul_2exp_si(s, s, 1);
acb_sub_ui(s, s, 3, prec);
acb_mul(s, s, w2, prec);
acb_mul_2exp_si(s, s, -1);
acb_const_pi(w2, prec);
acb_addmul(s, w2, w2, prec);
acb_div_ui(s, s, 6, prec);
acb_neg(w2, w);
acb_log(w2, w2, prec);
acb_submul(s, w2, w, prec);
acb_add(res, s, w, prec);
acb_add_error_mag(res, err);
if (real)
arb_zero(acb_imagref(res));
}
else
{
acb_indeterminate(res);
}
acb_clear(s);
acb_clear(w);
acb_clear(w2);
fmpz_clear(c);
fmpz_clear(d);
mag_clear(m);
mag_clear(err);
}
void
_acb_poly_zeta_cpx_reflect(acb_ptr t, const acb_t h, const acb_t a, int deflate, slong len, slong prec)
{
/* use reflection formula */
if (arf_sgn(arb_midref(acb_realref(h))) < 0 && acb_is_one(a))
{
/* zeta(s) = (2*pi)**s * sin(pi*s/2) / pi * gamma(1-s) * zeta(1-s) */
acb_t pi, hcopy;
acb_ptr f, s1, s2, s3, s4, u;
slong i;
acb_init(pi);
acb_init(hcopy);
f = _acb_vec_init(2);
s1 = _acb_vec_init(len);
s2 = _acb_vec_init(len);
s3 = _acb_vec_init(len);
s4 = _acb_vec_init(len);
u = _acb_vec_init(len);
acb_set(hcopy, h);
acb_const_pi(pi, prec);
/* s1 = (2*pi)**s */
acb_mul_2exp_si(pi, pi, 1);
_acb_poly_pow_cpx(s1, pi, h, len, prec);
acb_mul_2exp_si(pi, pi, -1);
/* s2 = sin(pi*s/2) / pi */
acb_set(f, h);
acb_one(f + 1);
acb_mul_2exp_si(f, f, -1);
acb_mul_2exp_si(f + 1, f + 1, -1);
_acb_poly_sin_pi_series(s2, f, 2, len, prec);
_acb_vec_scalar_div(s2, s2, len, pi, prec);
/* s3 = gamma(1-s) */
acb_sub_ui(f, hcopy, 1, prec);
acb_neg(f, f);
acb_set_si(f + 1, -1);
_acb_poly_gamma_series(s3, f, 2, len, prec);
/* s4 = zeta(1-s) */
acb_sub_ui(f, hcopy, 1, prec);
acb_neg(f, f);
_acb_poly_zeta_cpx_series(s4, f, a, 0, len, prec);
for (i = 1; i < len; i += 2)
acb_neg(s4 + i, s4 + i);
_acb_poly_mullow(u, s1, len, s2, len, len, prec);
_acb_poly_mullow(s1, s3, len, s4, len, len, prec);
_acb_poly_mullow(t, u, len, s1, len, len, prec);
/* add 1/(1-(s+t)) = 1/(1-s) + t/(1-s)^2 + ... */
if (deflate)
{
acb_sub_ui(u, hcopy, 1, prec);
acb_neg(u, u);
acb_inv(u, u, prec);
for (i = 1; i < len; i++)
acb_mul(u + i, u + i - 1, u, prec);
_acb_vec_add(t, t, u, len, prec);
}
acb_clear(pi);
acb_clear(hcopy);
_acb_vec_clear(f, 2);
_acb_vec_clear(s1, len);
_acb_vec_clear(s2, len);
_acb_vec_clear(s3, len);
_acb_vec_clear(s4, len);
_acb_vec_clear(u, len);
}
else
{
_acb_poly_zeta_cpx_series(t, h, a, deflate, len, prec);
}
}
void
_acb_poly_rgamma_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_rgamma(res, h, prec);
_acb_vec_zero(res + 1, len - 1);
return;
}
/* use real code for real input */
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_rgamma_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);
/* otherwise use Stirling series */
acb_gamma_stirling_choose_param(&reflect, &r, &n, h, 1, 0, wp);
/* rgamma(h) = (gamma(1-h+r) sin(pi h)) / (rf(1-h, r) * pi), h = h0 + t*/
if (reflect)
{
/* u = gamma(r+1-h) */
acb_sub_ui(f, h, r + 1, wp);
acb_neg(f, f);
_acb_poly_gamma_stirling_eval(t, f, n, len, wp);
_acb_poly_exp_series(u, t, len, len, wp);
for (i = 1; i < len; i += 2)
acb_neg(u + i, u + i);
/* v = sin(pi x) */
acb_set(f, h);
acb_one(f + 1);
_acb_poly_sin_pi_series(v, f, 2, len, wp);
_acb_poly_mullow(t, u, len, v, len, len, wp);
/* rf(1-h,r) * pi */
if (r == 0)
{
acb_const_pi(u, wp);
_acb_vec_scalar_div(v, t, len, 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(v, f, FLINT_MIN(2, len), r, rflen, wp);
acb_const_pi(u, wp);
_acb_vec_scalar_mul(v, v, rflen, u, wp);
/* divide by rising factorial */
/* TODO: might better to use div_series, when it has a good basecase */
_acb_poly_inv_series(u, v, rflen, len, wp);
_acb_poly_mullow(v, t, len, u, len, len, wp);
}
}
else
{
/* rgamma(h) = rgamma(h+r) rf(h,r) */
if (r == 0)
{
acb_add_ui(f, h, r, wp);
_acb_poly_gamma_stirling_eval(t, f, n, len, wp);
_acb_vec_neg(t, t, len);
_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(t, f, FLINT_MIN(2, len), r, rflen, wp);
acb_add_ui(f, h, r, wp);
_acb_poly_gamma_stirling_eval(v, f, n, len, wp);
_acb_vec_neg(v, v, len);
_acb_poly_exp_series(u, v, len, len, wp);
_acb_poly_mullow(v, u, len, t, rflen, len, wp);
}
}
/* compose with nonconstant part */
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);
}
