Ejemplo n.º 1
0
def mpc_agm(a, b, prec, rnd=round_fast):
    """
    Complex AGM.

    TODO:
    * check that convergence works as intended
    * optimize
    * select a nonarbitrary branch
    """
    if mpc_is_infnan(a) or mpc_is_infnan(b):
        return fnan, fnan
    if mpc_zero in (a, b):
        return fzero, fzero
    if mpc_neg(a) == b:
        return fzero, fzero
    wp = prec+20
    eps = mpf_shift(fone, -wp+10)
    while 1:
        a1 = mpc_shift(mpc_add(a, b, wp), -1)
        b1 = mpc_sqrt(mpc_mul(a, b, wp), wp)
        a, b = a1, b1
        size = mpf_min_max([mpc_abs(a,10), mpc_abs(b,10)])[1]
        err = mpc_abs(mpc_sub(a, b, 10), 10)
        if size == fzero or mpf_lt(err, mpf_mul(eps, size)):
            return a
Ejemplo n.º 2
0
def mpc_agm(a, b, prec, rnd=round_fast):
    """
    Complex AGM.

    TODO:
    * check that convergence works as intended
    * optimize
    * select a nonarbitrary branch
    """
    if mpc_is_infnan(a) or mpc_is_infnan(b):
        return fnan, fnan
    if mpc_zero in (a, b):
        return fzero, fzero
    if mpc_neg(a) == b:
        return fzero, fzero
    wp = prec + 20
    eps = mpf_shift(fone, -wp + 10)
    while 1:
        a1 = mpc_shift(mpc_add(a, b, wp), -1)
        b1 = mpc_sqrt(mpc_mul(a, b, wp), wp)
        a, b = a1, b1
        size = sorted([mpc_abs(a, 10), mpc_abs(a, 10)], cmp=mpf_cmp)[1]
        err = mpc_abs(mpc_sub(a, b, 10), 10)
        if size == fzero or mpf_lt(err, mpf_mul(eps, size)):
            return a
Ejemplo n.º 3
0
def mpc_erf(z, prec, rnd=round_fast):
    re, im = z
    if im == fzero:
        return (mpf_erf(re, prec, rnd), fzero)
    wp = prec + 20
    z2 = mpc_square(z, prec + 20)
    v = mpc_hyp1f1_rat((1, 2), (3, 2), mpc_neg(z2), wp, rnd)
    sqrtpi = mpf_sqrt(mpf_pi(wp), wp)
    c = mpf_rdiv_int(2, sqrtpi, wp)
    c = mpc_mul_mpf(z, c, wp)
    return mpc_mul(c, v, prec, rnd)
Ejemplo n.º 4
0
def mpc_erf(z, prec, rnd=round_fast):
    re, im = z
    if im == fzero:
        return (mpf_erf(re, prec, rnd), fzero)
    wp = prec + 20
    z2 = mpc_mul(z, z, prec+20)
    v = mpc_hyp1f1_rat((1,2), (3,2), mpc_neg(z2), wp, rnd)
    sqrtpi = mpf_sqrt(mpf_pi(wp), wp)
    c = mpf_rdiv_int(2, sqrtpi, wp)
    c = mpc_mul_mpf(z, c, wp)
    return mpc_mul(c, v, prec, rnd)
Ejemplo n.º 5
0
def mpc_zeta(s, prec, rnd=round_fast, alt=0, force=False):
    re, im = s
    if im == fzero:
        return mpf_zeta(re, prec, rnd, alt), fzero

    # slow for large s
    if (not force) and mpf_gt(mpc_abs(s, 10), from_int(prec)):
        raise NotImplementedError

    wp = prec + 20

    # Near pole
    r = mpc_sub(mpc_one, s, wp)
    asign, aman, aexp, abc = mpc_abs(r, 10)
    pole_dist = -2*(aexp+abc)
    if pole_dist > wp:
        if alt:
            q = mpf_ln2(wp)
            y = mpf_mul(q, mpf_euler(wp), wp)
            g = mpf_shift(mpf_mul(q, q, wp), -1)
            g = mpf_sub(y, g)
            z = mpc_mul_mpf(r, mpf_neg(g), wp)
            z = mpc_add_mpf(z, q, wp)
            return mpc_pos(z, prec, rnd)
        else:
            q = mpc_neg(mpc_div(mpc_one, r, wp))
            q = mpc_add_mpf(q, mpf_euler(wp), wp)
            return mpc_pos(q, prec, rnd)
    else:
        wp += max(0, pole_dist)

    # Reflection formula. To be rigorous, we should reflect to the left of
    # re = 1/2 (see comments for mpf_zeta), but this leads to unnecessary
    # slowdown for interesting values of s
    if mpf_lt(re, fzero):
        # XXX: could use the separate refl. formula for Dirichlet eta
        if alt:
            q = mpc_sub(mpc_one, mpc_pow(mpc_two, mpc_sub(mpc_one, s, wp),
                wp), wp)
            return mpc_mul(mpc_zeta(s, wp), q, prec, rnd)
        # XXX: -1 should be done exactly
        y = mpc_sub(mpc_one, s, 10*wp)
        a = mpc_gamma(y, wp)
        b = mpc_zeta(y, wp)
        c = mpc_sin_pi(mpc_shift(s, -1), wp)
        rsign, rman, rexp, rbc = re
        isign, iman, iexp, ibc = im
        mag = max(rexp+rbc, iexp+ibc)
        wp2 = wp + mag
        pi = mpf_pi(wp+wp2)
        pi2 = (mpf_shift(pi, 1), fzero)
        d = mpc_div_mpf(mpc_pow(pi2, s, wp2), pi, wp2)
        return mpc_mul(a,mpc_mul(b,mpc_mul(c,d,wp),wp),prec,rnd)
    n = int(wp/2.54 + 5)
    n += int(0.9*abs(to_int(im)))
    d = borwein_coefficients(n)
    ref = to_fixed(re, wp)
    imf = to_fixed(im, wp)
    tre = MPZ_ZERO
    tim = MPZ_ZERO
    one = MPZ_ONE << wp
    one_2wp = MPZ_ONE << (2*wp)
    critical_line = re == fhalf
    for k in xrange(n):
        log = log_int_fixed(k+1, wp)
        # A square root is much cheaper than an exp
        if critical_line:
            w = one_2wp // sqrt_fixed((k+1) << wp, wp)
        else:
            w = to_fixed(mpf_exp(from_man_exp(-ref*log, -2*wp), wp), wp)
        if k & 1:
            w *= (d[n] - d[k])
        else:
            w *= (d[k] - d[n])
        wre, wim = mpf_cos_sin(from_man_exp(-imf * log, -2*wp), wp)
        tre += (w * to_fixed(wre, wp)) >> wp
        tim += (w * to_fixed(wim, wp)) >> wp
    tre //= (-d[n])
    tim //= (-d[n])
    tre = from_man_exp(tre, -wp, wp)
    tim = from_man_exp(tim, -wp, wp)
    if alt:
        return mpc_pos((tre, tim), prec, rnd)
    else:
        q = mpc_sub(mpc_one, mpc_pow(mpc_two, r, wp), wp)
        return mpc_div((tre, tim), q, prec, rnd)
Ejemplo n.º 6
0
def mpc_ei(z, prec, rnd=round_fast, e1=False):
    if e1:
        z = mpc_neg(z)
    a, b = z
    asign, aman, aexp, abc = a
    bsign, bman, bexp, bbc = b
    if b == fzero:
        if e1:
            x = mpf_neg(mpf_ei(a, prec, rnd))
            if not asign:
                y = mpf_neg(mpf_pi(prec, rnd))
            else:
                y = fzero
            return x, y
        else:
            return mpf_ei(a, prec, rnd), fzero
    if a != fzero:
        if not aman or not bman:
            return (fnan, fnan)
    wp = prec + 40
    amag = aexp+abc
    bmag = bexp+bbc
    zmag = max(amag, bmag)
    can_use_asymp = zmag > wp
    if not can_use_asymp:
        zabsint = abs(to_int(a)) + abs(to_int(b))
        can_use_asymp = zabsint > int(wp*0.693) + 20
    try:
        if can_use_asymp:
            if zmag > wp:
                v = fone, fzero
            else:
                zre = to_fixed(a, wp)
                zim = to_fixed(b, wp)
                vre, vim = complex_ei_asymptotic(zre, zim, wp)
                v = from_man_exp(vre, -wp), from_man_exp(vim, -wp)
            v = mpc_mul(v, mpc_exp(z, wp), wp)
            v = mpc_div(v, z, wp)
            if e1:
                v = mpc_neg(v, prec, rnd)
            else:
                x, y = v
                if bsign:
                    v = mpf_pos(x, prec, rnd), mpf_sub(y, mpf_pi(wp), prec, rnd)
                else:
                    v = mpf_pos(x, prec, rnd), mpf_add(y, mpf_pi(wp), prec, rnd)
            return v
    except NoConvergence:
        pass
    #wp += 2*max(0,zmag)
    wp += 2*int(to_int(mpc_abs(z, 5)))
    zre = to_fixed(a, wp)
    zim = to_fixed(b, wp)
    vre, vim = complex_ei_taylor(zre, zim, wp)
    vre += euler_fixed(wp)
    v = from_man_exp(vre,-wp), from_man_exp(vim,-wp)
    if e1:
        u = mpc_log(mpc_neg(z),wp)
    else:
        u = mpc_log(z,wp)
    v = mpc_add(v, u, prec, rnd)
    if e1:
        v = mpc_neg(v)
    return v
Ejemplo n.º 7
0
def mpc_ei(z, prec, rnd=round_fast, e1=False):
    if e1:
        z = mpc_neg(z)
    a, b = z
    asign, aman, aexp, abc = a
    bsign, bman, bexp, bbc = b
    if b == fzero:
        if e1:
            x = mpf_neg(mpf_ei(a, prec, rnd))
            if not asign:
                y = mpf_neg(mpf_pi(prec, rnd))
            else:
                y = fzero
            return x, y
        else:
            return mpf_ei(a, prec, rnd), fzero
    if a != fzero:
        if not aman or not bman:
            return (fnan, fnan)
    wp = prec + 40
    amag = aexp + abc
    bmag = bexp + bbc
    zmag = max(amag, bmag)
    can_use_asymp = zmag > wp
    if not can_use_asymp:
        zabsint = abs(to_int(a)) + abs(to_int(b))
        can_use_asymp = zabsint > int(wp * 0.693) + 20
    try:
        if can_use_asymp:
            if zmag > wp:
                v = fone, fzero
            else:
                zre = to_fixed(a, wp)
                zim = to_fixed(b, wp)
                vre, vim = complex_ei_asymptotic(zre, zim, wp)
                v = from_man_exp(vre, -wp), from_man_exp(vim, -wp)
            v = mpc_mul(v, mpc_exp(z, wp), wp)
            v = mpc_div(v, z, wp)
            if e1:
                v = mpc_neg(v, prec, rnd)
            else:
                x, y = v
                if bsign:
                    v = mpf_pos(x, prec, rnd), mpf_sub(y, mpf_pi(wp), prec,
                                                       rnd)
                else:
                    v = mpf_pos(x, prec, rnd), mpf_add(y, mpf_pi(wp), prec,
                                                       rnd)
            return v
    except NoConvergence:
        pass
    #wp += 2*max(0,zmag)
    wp += 2 * int(to_int(mpc_abs(z, 5)))
    zre = to_fixed(a, wp)
    zim = to_fixed(b, wp)
    vre, vim = complex_ei_taylor(zre, zim, wp)
    vre += euler_fixed(wp)
    v = from_man_exp(vre, -wp), from_man_exp(vim, -wp)
    if e1:
        u = mpc_log(mpc_neg(z), wp)
    else:
        u = mpc_log(z, wp)
    v = mpc_add(v, u, prec, rnd)
    if e1:
        v = mpc_neg(v)
    return v
Ejemplo n.º 8
0
def mpc_zeta(s, prec, rnd=round_fast, alt=0, force=False):
    re, im = s
    if im == fzero:
        return mpf_zeta(re, prec, rnd, alt), fzero

    # slow for large s
    if (not force) and mpf_gt(mpc_abs(s, 10), from_int(prec)):
        raise NotImplementedError

    wp = prec + 20

    # Near pole
    r = mpc_sub(mpc_one, s, wp)
    asign, aman, aexp, abc = mpc_abs(r, 10)
    pole_dist = -2 * (aexp + abc)
    if pole_dist > wp:
        if alt:
            q = mpf_ln2(wp)
            y = mpf_mul(q, mpf_euler(wp), wp)
            g = mpf_shift(mpf_mul(q, q, wp), -1)
            g = mpf_sub(y, g)
            z = mpc_mul_mpf(r, mpf_neg(g), wp)
            z = mpc_add_mpf(z, q, wp)
            return mpc_pos(z, prec, rnd)
        else:
            q = mpc_neg(mpc_div(mpc_one, r, wp))
            q = mpc_add_mpf(q, mpf_euler(wp), wp)
            return mpc_pos(q, prec, rnd)
    else:
        wp += max(0, pole_dist)

    # Reflection formula. To be rigorous, we should reflect to the left of
    # re = 1/2 (see comments for mpf_zeta), but this leads to unnecessary
    # slowdown for interesting values of s
    if mpf_lt(re, fzero):
        # XXX: could use the separate refl. formula for Dirichlet eta
        if alt:
            q = mpc_sub(mpc_one, mpc_pow(mpc_two, mpc_sub(mpc_one, s, wp), wp),
                        wp)
            return mpc_mul(mpc_zeta(s, wp), q, prec, rnd)
        # XXX: -1 should be done exactly
        y = mpc_sub(mpc_one, s, 10 * wp)
        a = mpc_gamma(y, wp)
        b = mpc_zeta(y, wp)
        c = mpc_sin_pi(mpc_shift(s, -1), wp)
        rsign, rman, rexp, rbc = re
        isign, iman, iexp, ibc = im
        mag = max(rexp + rbc, iexp + ibc)
        wp2 = wp + mag
        pi = mpf_pi(wp + wp2)
        pi2 = (mpf_shift(pi, 1), fzero)
        d = mpc_div_mpf(mpc_pow(pi2, s, wp2), pi, wp2)
        return mpc_mul(a, mpc_mul(b, mpc_mul(c, d, wp), wp), prec, rnd)
    n = int(wp / 2.54 + 5)
    n += int(0.9 * abs(to_int(im)))
    d = borwein_coefficients(n)
    ref = to_fixed(re, wp)
    imf = to_fixed(im, wp)
    tre = MPZ_ZERO
    tim = MPZ_ZERO
    one = MPZ_ONE << wp
    one_2wp = MPZ_ONE << (2 * wp)
    critical_line = re == fhalf
    for k in xrange(n):
        log = log_int_fixed(k + 1, wp)
        # A square root is much cheaper than an exp
        if critical_line:
            w = one_2wp // sqrt_fixed((k + 1) << wp, wp)
        else:
            w = to_fixed(mpf_exp(from_man_exp(-ref * log, -2 * wp), wp), wp)
        if k & 1:
            w *= (d[n] - d[k])
        else:
            w *= (d[k] - d[n])
        wre, wim = mpf_cos_sin(from_man_exp(-imf * log, -2 * wp), wp)
        tre += (w * to_fixed(wre, wp)) >> wp
        tim += (w * to_fixed(wim, wp)) >> wp
    tre //= (-d[n])
    tim //= (-d[n])
    tre = from_man_exp(tre, -wp, wp)
    tim = from_man_exp(tim, -wp, wp)
    if alt:
        return mpc_pos((tre, tim), prec, rnd)
    else:
        q = mpc_sub(mpc_one, mpc_pow(mpc_two, r, wp), wp)
        return mpc_div((tre, tim), q, prec, rnd)