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""" | |
----------------------------------------------------------------------- | |
This module implements gamma- and zeta-related functions: | |
* Bernoulli numbers | |
* Factorials | |
* The gamma function | |
* Polygamma functions | |
* Harmonic numbers | |
* The Riemann zeta function | |
* Constants related to these functions | |
----------------------------------------------------------------------- | |
""" | |
import math | |
import sys | |
from .backend import xrange | |
from .backend import MPZ, MPZ_ZERO, MPZ_ONE, MPZ_THREE, gmpy | |
from .libintmath import list_primes, ifac, ifac2, moebius | |
from .libmpf import (\ | |
round_floor, round_ceiling, round_down, round_up, | |
round_nearest, round_fast, | |
lshift, sqrt_fixed, isqrt_fast, | |
fzero, fone, fnone, fhalf, ftwo, finf, fninf, fnan, | |
from_int, to_int, to_fixed, from_man_exp, from_rational, | |
mpf_pos, mpf_neg, mpf_abs, mpf_add, mpf_sub, | |
mpf_mul, mpf_mul_int, mpf_div, mpf_sqrt, mpf_pow_int, | |
mpf_rdiv_int, | |
mpf_perturb, mpf_le, mpf_lt, mpf_gt, mpf_shift, | |
negative_rnd, reciprocal_rnd, | |
bitcount, to_float, mpf_floor, mpf_sign, ComplexResult | |
) | |
from .libelefun import (\ | |
constant_memo, | |
def_mpf_constant, | |
mpf_pi, pi_fixed, ln2_fixed, log_int_fixed, mpf_ln2, | |
mpf_exp, mpf_log, mpf_pow, mpf_cosh, | |
mpf_cos_sin, mpf_cosh_sinh, mpf_cos_sin_pi, mpf_cos_pi, mpf_sin_pi, | |
ln_sqrt2pi_fixed, mpf_ln_sqrt2pi, sqrtpi_fixed, mpf_sqrtpi, | |
cos_sin_fixed, exp_fixed | |
) | |
from .libmpc import (\ | |
mpc_zero, mpc_one, mpc_half, mpc_two, | |
mpc_abs, mpc_shift, mpc_pos, mpc_neg, | |
mpc_add, mpc_sub, mpc_mul, mpc_div, | |
mpc_add_mpf, mpc_mul_mpf, mpc_div_mpf, mpc_mpf_div, | |
mpc_mul_int, mpc_pow_int, | |
mpc_log, mpc_exp, mpc_pow, | |
mpc_cos_pi, mpc_sin_pi, | |
mpc_reciprocal, mpc_square, | |
mpc_sub_mpf | |
) | |
# Catalan's constant is computed using Lupas's rapidly convergent series | |
# (listed on http://mathworld.wolfram.com/CatalansConstant.html) | |
# oo | |
# ___ n-1 8n 2 3 2 | |
# 1 \ (-1) 2 (40n - 24n + 3) [(2n)!] (n!) | |
# K = --- ) ----------------------------------------- | |
# 64 /___ 3 2 | |
# n (2n-1) [(4n)!] | |
# n = 1 | |
def catalan_fixed(prec): | |
prec = prec + 20 | |
a = one = MPZ_ONE << prec | |
s, t, n = 0, 1, 1 | |
while t: | |
a *= 32 * n**3 * (2*n-1) | |
a //= (3-16*n+16*n**2)**2 | |
t = a * (-1)**(n-1) * (40*n**2-24*n+3) // (n**3 * (2*n-1)) | |
s += t | |
n += 1 | |
return s >> (20 + 6) | |
# Khinchin's constant is relatively difficult to compute. Here | |
# we use the rational zeta series | |
# oo 2*n-1 | |
# ___ ___ | |
# \ ` zeta(2*n)-1 \ ` (-1)^(k+1) | |
# log(K)*log(2) = ) ------------ ) ---------- | |
# /___. n /___. k | |
# n = 1 k = 1 | |
# which adds half a digit per term. The essential trick for achieving | |
# reasonable efficiency is to recycle both the values of the zeta | |
# function (essentially Bernoulli numbers) and the partial terms of | |
# the inner sum. | |
# An alternative might be to use K = 2*exp[1/log(2) X] where | |
# / 1 1 [ pi*x*(1-x^2) ] | |
# X = | ------ log [ ------------ ]. | |
# / 0 x(1+x) [ sin(pi*x) ] | |
# and integrate numerically. In practice, this seems to be slightly | |
# slower than the zeta series at high precision. | |
def khinchin_fixed(prec): | |
wp = int(prec + prec**0.5 + 15) | |
s = MPZ_ZERO | |
fac = from_int(4) | |
t = ONE = MPZ_ONE << wp | |
pi = mpf_pi(wp) | |
pipow = twopi2 = mpf_shift(mpf_mul(pi, pi, wp), 2) | |
n = 1 | |
while 1: | |
zeta2n = mpf_abs(mpf_bernoulli(2*n, wp)) | |
zeta2n = mpf_mul(zeta2n, pipow, wp) | |
zeta2n = mpf_div(zeta2n, fac, wp) | |
zeta2n = to_fixed(zeta2n, wp) | |
term = (((zeta2n - ONE) * t) // n) >> wp | |
if term < 100: | |
break | |
#if not n % 10: | |
# print n, math.log(int(abs(term))) | |
s += term | |
t += ONE//(2*n+1) - ONE//(2*n) | |
n += 1 | |
fac = mpf_mul_int(fac, (2*n)*(2*n-1), wp) | |
pipow = mpf_mul(pipow, twopi2, wp) | |
s = (s << wp) // ln2_fixed(wp) | |
K = mpf_exp(from_man_exp(s, -wp), wp) | |
K = to_fixed(K, prec) | |
return K | |
# Glaisher's constant is defined as A = exp(1/2 - zeta'(-1)). | |
# One way to compute it would be to perform direct numerical | |
# differentiation, but computing arbitrary Riemann zeta function | |
# values at high precision is expensive. We instead use the formula | |
# A = exp((6 (-zeta'(2))/pi^2 + log 2 pi + gamma)/12) | |
# and compute zeta'(2) from the series representation | |
# oo | |
# ___ | |
# \ log k | |
# -zeta'(2) = ) ----- | |
# /___ 2 | |
# k | |
# k = 2 | |
# This series converges exceptionally slowly, but can be accelerated | |
# using Euler-Maclaurin formula. The important insight is that the | |
# E-M integral can be done in closed form and that the high order | |
# are given by | |
# n / \ | |
# d | log x | a + b log x | |
# --- | ----- | = ----------- | |
# n | 2 | 2 + n | |
# dx \ x / x | |
# where a and b are integers given by a simple recurrence. Note | |
# that just one logarithm is needed. However, lots of integer | |
# logarithms are required for the initial summation. | |
# This algorithm could possibly be turned into a faster algorithm | |
# for general evaluation of zeta(s) or zeta'(s); this should be | |
# looked into. | |
def glaisher_fixed(prec): | |
wp = prec + 30 | |
# Number of direct terms to sum before applying the Euler-Maclaurin | |
# formula to the tail. TODO: choose more intelligently | |
N = int(0.33*prec + 5) | |
ONE = MPZ_ONE << wp | |
# Euler-Maclaurin, step 1: sum log(k)/k**2 for k from 2 to N-1 | |
s = MPZ_ZERO | |
for k in range(2, N): | |
#print k, N | |
s += log_int_fixed(k, wp) // k**2 | |
logN = log_int_fixed(N, wp) | |
#logN = to_fixed(mpf_log(from_int(N), wp+20), wp) | |
# E-M step 2: integral of log(x)/x**2 from N to inf | |
s += (ONE + logN) // N | |
# E-M step 3: endpoint correction term f(N)/2 | |
s += logN // (N**2 * 2) | |
# E-M step 4: the series of derivatives | |
pN = N**3 | |
a = 1 | |
b = -2 | |
j = 3 | |
fac = from_int(2) | |
k = 1 | |
while 1: | |
# D(2*k-1) * B(2*k) / fac(2*k) [D(n) = nth derivative] | |
D = ((a << wp) + b*logN) // pN | |
D = from_man_exp(D, -wp) | |
B = mpf_bernoulli(2*k, wp) | |
term = mpf_mul(B, D, wp) | |
term = mpf_div(term, fac, wp) | |
term = to_fixed(term, wp) | |
if abs(term) < 100: | |
break | |
#if not k % 10: | |
# print k, math.log(int(abs(term)), 10) | |
s -= term | |
# Advance derivative twice | |
a, b, pN, j = b-a*j, -j*b, pN*N, j+1 | |
a, b, pN, j = b-a*j, -j*b, pN*N, j+1 | |
k += 1 | |
fac = mpf_mul_int(fac, (2*k)*(2*k-1), wp) | |
# A = exp((6*s/pi**2 + log(2*pi) + euler)/12) | |
pi = pi_fixed(wp) | |
s *= 6 | |
s = (s << wp) // (pi**2 >> wp) | |
s += euler_fixed(wp) | |
s += to_fixed(mpf_log(from_man_exp(2*pi, -wp), wp), wp) | |
s //= 12 | |
A = mpf_exp(from_man_exp(s, -wp), wp) | |
return to_fixed(A, prec) | |
# Apery's constant can be computed using the very rapidly convergent | |
# series | |
# oo | |
# ___ 2 10 | |
# \ n 205 n + 250 n + 77 (n!) | |
# zeta(3) = ) (-1) ------------------- ---------- | |
# /___ 64 5 | |
# n = 0 ((2n+1)!) | |
def apery_fixed(prec): | |
prec += 20 | |
d = MPZ_ONE << prec | |
term = MPZ(77) << prec | |
n = 1 | |
s = MPZ_ZERO | |
while term: | |
s += term | |
d *= (n**10) | |
d //= (((2*n+1)**5) * (2*n)**5) | |
term = (-1)**n * (205*(n**2) + 250*n + 77) * d | |
n += 1 | |
return s >> (20 + 6) | |
""" | |
Euler's constant (gamma) is computed using the Brent-McMillan formula, | |
gamma ~= I(n)/J(n) - log(n), where | |
I(n) = sum_{k=0,1,2,...} (n**k / k!)**2 * H(k) | |
J(n) = sum_{k=0,1,2,...} (n**k / k!)**2 | |
H(k) = 1 + 1/2 + 1/3 + ... + 1/k | |
The error is bounded by O(exp(-4n)). Choosing n to be a power | |
of two, 2**p, the logarithm becomes particularly easy to calculate.[1] | |
We use the formulation of Algorithm 3.9 in [2] to make the summation | |
more efficient. | |
Reference: | |
[1] Xavier Gourdon & Pascal Sebah, The Euler constant: gamma | |
http://numbers.computation.free.fr/Constants/Gamma/gamma.pdf | |
[2] [BorweinBailey]_ | |
""" | |
def euler_fixed(prec): | |
extra = 30 | |
prec += extra | |
# choose p such that exp(-4*(2**p)) < 2**-n | |
p = int(math.log((prec/4) * math.log(2), 2)) + 1 | |
n = 2**p | |
A = U = -p*ln2_fixed(prec) | |
B = V = MPZ_ONE << prec | |
k = 1 | |
while 1: | |
B = B*n**2//k**2 | |
A = (A*n**2//k + B)//k | |
U += A | |
V += B | |
if max(abs(A), abs(B)) < 100: | |
break | |
k += 1 | |
return (U<<(prec-extra))//V | |
# Use zeta accelerated formulas for the Mertens and twin | |
# prime constants; see | |
# http://mathworld.wolfram.com/MertensConstant.html | |
# http://mathworld.wolfram.com/TwinPrimesConstant.html | |
def mertens_fixed(prec): | |
wp = prec + 20 | |
m = 2 | |
s = mpf_euler(wp) | |
while 1: | |
t = mpf_zeta_int(m, wp) | |
if t == fone: | |
break | |
t = mpf_log(t, wp) | |
t = mpf_mul_int(t, moebius(m), wp) | |
t = mpf_div(t, from_int(m), wp) | |
s = mpf_add(s, t) | |
m += 1 | |
return to_fixed(s, prec) | |
def twinprime_fixed(prec): | |
def I(n): | |
return sum(moebius(d)<<(n//d) for d in xrange(1,n+1) if not n%d)//n | |
wp = 2*prec + 30 | |
res = fone | |
primes = [from_rational(1,p,wp) for p in [2,3,5,7]] | |
ppowers = [mpf_mul(p,p,wp) for p in primes] | |
n = 2 | |
while 1: | |
a = mpf_zeta_int(n, wp) | |
for i in range(4): | |
a = mpf_mul(a, mpf_sub(fone, ppowers[i]), wp) | |
ppowers[i] = mpf_mul(ppowers[i], primes[i], wp) | |
a = mpf_pow_int(a, -I(n), wp) | |
if mpf_pos(a, prec+10, 'n') == fone: | |
break | |
#from libmpf import to_str | |
#print n, to_str(mpf_sub(fone, a), 6) | |
res = mpf_mul(res, a, wp) | |
n += 1 | |
res = mpf_mul(res, from_int(3*15*35), wp) | |
res = mpf_div(res, from_int(4*16*36), wp) | |
return to_fixed(res, prec) | |
mpf_euler = def_mpf_constant(euler_fixed) | |
mpf_apery = def_mpf_constant(apery_fixed) | |
mpf_khinchin = def_mpf_constant(khinchin_fixed) | |
mpf_glaisher = def_mpf_constant(glaisher_fixed) | |
mpf_catalan = def_mpf_constant(catalan_fixed) | |
mpf_mertens = def_mpf_constant(mertens_fixed) | |
mpf_twinprime = def_mpf_constant(twinprime_fixed) | |
#-----------------------------------------------------------------------# | |
# # | |
# Bernoulli numbers # | |
# # | |
#-----------------------------------------------------------------------# | |
MAX_BERNOULLI_CACHE = 3000 | |
r""" | |
Small Bernoulli numbers and factorials are used in numerous summations, | |
so it is critical for speed that sequential computation is fast and that | |
values are cached up to a fairly high threshold. | |
On the other hand, we also want to support fast computation of isolated | |
large numbers. Currently, no such acceleration is provided for integer | |
factorials (though it is for large floating-point factorials, which are | |
computed via gamma if the precision is low enough). | |
For sequential computation of Bernoulli numbers, we use Ramanujan's formula | |
/ n + 3 \ | |
B = (A(n) - S(n)) / | | | |
n \ n / | |
where A(n) = (n+3)/3 when n = 0 or 2 (mod 6), A(n) = -(n+3)/6 | |
when n = 4 (mod 6), and | |
[n/6] | |
___ | |
\ / n + 3 \ | |
S(n) = ) | | * B | |
/___ \ n - 6*k / n-6*k | |
k = 1 | |
For isolated large Bernoulli numbers, we use the Riemann zeta function | |
to calculate a numerical value for B_n. The von Staudt-Clausen theorem | |
can then be used to optionally find the exact value of the | |
numerator and denominator. | |
""" | |
bernoulli_cache = {} | |
f3 = from_int(3) | |
f6 = from_int(6) | |
def bernoulli_size(n): | |
"""Accurately estimate the size of B_n (even n > 2 only)""" | |
lgn = math.log(n,2) | |
return int(2.326 + 0.5*lgn + n*(lgn - 4.094)) | |
BERNOULLI_PREC_CUTOFF = bernoulli_size(MAX_BERNOULLI_CACHE) | |
def mpf_bernoulli(n, prec, rnd=None): | |
"""Computation of Bernoulli numbers (numerically)""" | |
if n < 2: | |
if n < 0: | |
raise ValueError("Bernoulli numbers only defined for n >= 0") | |
if n == 0: | |
return fone | |
if n == 1: | |
return mpf_neg(fhalf) | |
# For odd n > 1, the Bernoulli numbers are zero | |
if n & 1: | |
return fzero | |
# If precision is extremely high, we can save time by computing | |
# the Bernoulli number at a lower precision that is sufficient to | |
# obtain the exact fraction, round to the exact fraction, and | |
# convert the fraction back to an mpf value at the original precision | |
if prec > BERNOULLI_PREC_CUTOFF and prec > bernoulli_size(n)*1.1 + 1000: | |
p, q = bernfrac(n) | |
return from_rational(p, q, prec, rnd or round_floor) | |
if n > MAX_BERNOULLI_CACHE: | |
return mpf_bernoulli_huge(n, prec, rnd) | |
wp = prec + 30 | |
# Reuse nearby precisions | |
wp += 32 - (prec & 31) | |
cached = bernoulli_cache.get(wp) | |
if cached: | |
numbers, state = cached | |
if n in numbers: | |
if not rnd: | |
return numbers[n] | |
return mpf_pos(numbers[n], prec, rnd) | |
m, bin, bin1 = state | |
if n - m > 10: | |
return mpf_bernoulli_huge(n, prec, rnd) | |
else: | |
if n > 10: | |
return mpf_bernoulli_huge(n, prec, rnd) | |
numbers = {0:fone} | |
m, bin, bin1 = state = [2, MPZ(10), MPZ_ONE] | |
bernoulli_cache[wp] = (numbers, state) | |
while m <= n: | |
#print m | |
case = m % 6 | |
# Accurately estimate size of B_m so we can use | |
# fixed point math without using too much precision | |
szbm = bernoulli_size(m) | |
s = 0 | |
sexp = max(0, szbm) - wp | |
if m < 6: | |
a = MPZ_ZERO | |
else: | |
a = bin1 | |
for j in xrange(1, m//6+1): | |
usign, uman, uexp, ubc = u = numbers[m-6*j] | |
if usign: | |
uman = -uman | |
s += lshift(a*uman, uexp-sexp) | |
# Update inner binomial coefficient | |
j6 = 6*j | |
a *= ((m-5-j6)*(m-4-j6)*(m-3-j6)*(m-2-j6)*(m-1-j6)*(m-j6)) | |
a //= ((4+j6)*(5+j6)*(6+j6)*(7+j6)*(8+j6)*(9+j6)) | |
if case == 0: b = mpf_rdiv_int(m+3, f3, wp) | |
if case == 2: b = mpf_rdiv_int(m+3, f3, wp) | |
if case == 4: b = mpf_rdiv_int(-m-3, f6, wp) | |
s = from_man_exp(s, sexp, wp) | |
b = mpf_div(mpf_sub(b, s, wp), from_int(bin), wp) | |
numbers[m] = b | |
m += 2 | |
# Update outer binomial coefficient | |
bin = bin * ((m+2)*(m+3)) // (m*(m-1)) | |
if m > 6: | |
bin1 = bin1 * ((2+m)*(3+m)) // ((m-7)*(m-6)) | |
state[:] = [m, bin, bin1] | |
return numbers[n] | |
def mpf_bernoulli_huge(n, prec, rnd=None): | |
wp = prec + 10 | |
piprec = wp + int(math.log(n,2)) | |
v = mpf_gamma_int(n+1, wp) | |
v = mpf_mul(v, mpf_zeta_int(n, wp), wp) | |
v = mpf_mul(v, mpf_pow_int(mpf_pi(piprec), -n, wp)) | |
v = mpf_shift(v, 1-n) | |
if not n & 3: | |
v = mpf_neg(v) | |
return mpf_pos(v, prec, rnd or round_fast) | |
def bernfrac(n): | |
r""" | |
Returns a tuple of integers `(p, q)` such that `p/q = B_n` exactly, | |
where `B_n` denotes the `n`-th Bernoulli number. The fraction is | |
always reduced to lowest terms. Note that for `n > 1` and `n` odd, | |
`B_n = 0`, and `(0, 1)` is returned. | |
**Examples** | |
The first few Bernoulli numbers are exactly:: | |
>>> from mpmath import * | |
>>> for n in range(15): | |
... p, q = bernfrac(n) | |
... print("%s %s/%s" % (n, p, q)) | |
... | |
0 1/1 | |
1 -1/2 | |
2 1/6 | |
3 0/1 | |
4 -1/30 | |
5 0/1 | |
6 1/42 | |
7 0/1 | |
8 -1/30 | |
9 0/1 | |
10 5/66 | |
11 0/1 | |
12 -691/2730 | |
13 0/1 | |
14 7/6 | |
This function works for arbitrarily large `n`:: | |
>>> p, q = bernfrac(10**4) | |
>>> print(q) | |
2338224387510 | |
>>> print(len(str(p))) | |
27692 | |
>>> mp.dps = 15 | |
>>> print(mpf(p) / q) | |
-9.04942396360948e+27677 | |
>>> print(bernoulli(10**4)) | |
-9.04942396360948e+27677 | |
.. note :: | |
:func:`~mpmath.bernoulli` computes a floating-point approximation | |
directly, without computing the exact fraction first. | |
This is much faster for large `n`. | |
**Algorithm** | |
:func:`~mpmath.bernfrac` works by computing the value of `B_n` numerically | |
and then using the von Staudt-Clausen theorem [1] to reconstruct | |
the exact fraction. For large `n`, this is significantly faster than | |
computing `B_1, B_2, \ldots, B_2` recursively with exact arithmetic. | |
The implementation has been tested for `n = 10^m` up to `m = 6`. | |
In practice, :func:`~mpmath.bernfrac` appears to be about three times | |
slower than the specialized program calcbn.exe [2] | |
**References** | |
1. MathWorld, von Staudt-Clausen Theorem: | |
http://mathworld.wolfram.com/vonStaudt-ClausenTheorem.html | |
2. The Bernoulli Number Page: | |
http://www.bernoulli.org/ | |
""" | |
n = int(n) | |
if n < 3: | |
return [(1, 1), (-1, 2), (1, 6)][n] | |
if n & 1: | |
return (0, 1) | |
q = 1 | |
for k in list_primes(n+1): | |
if not (n % (k-1)): | |
q *= k | |
prec = bernoulli_size(n) + int(math.log(q,2)) + 20 | |
b = mpf_bernoulli(n, prec) | |
p = mpf_mul(b, from_int(q)) | |
pint = to_int(p, round_nearest) | |
return (pint, q) | |
#-----------------------------------------------------------------------# | |
# # | |
# Polygamma functions # | |
# # | |
#-----------------------------------------------------------------------# | |
r""" | |
For all polygamma (psi) functions, we use the Euler-Maclaurin summation | |
formula. It looks slightly different in the m = 0 and m > 0 cases. | |
For m = 0, we have | |
oo | |
___ B | |
(0) 1 \ 2 k -2 k | |
psi (z) ~ log z + --- - ) ------ z | |
2 z /___ (2 k)! | |
k = 1 | |
Experiment shows that the minimum term of the asymptotic series | |
reaches 2^(-p) when Re(z) > 0.11*p. So we simply use the recurrence | |
for psi (equivalent, in fact, to summing to the first few terms | |
directly before applying E-M) to obtain z large enough. | |
Since, very crudely, log z ~= 1 for Re(z) > 1, we can use | |
fixed-point arithmetic (if z is extremely large, log(z) itself | |
is a sufficient approximation, so we can stop there already). | |
For Re(z) << 0, we could use recurrence, but this is of course | |
inefficient for large negative z, so there we use the | |
reflection formula instead. | |
For m > 0, we have | |
N - 1 | |
___ | |
~~~(m) [ \ 1 ] 1 1 | |
psi (z) ~ [ ) -------- ] + ---------- + -------- + | |
[ /___ m+1 ] m+1 m | |
k = 1 (z+k) ] 2 (z+N) m (z+N) | |
oo | |
___ B | |
\ 2 k (m+1) (m+2) ... (m+2k-1) | |
+ ) ------ ------------------------ | |
/___ (2 k)! m + 2 k | |
k = 1 (z+N) | |
where ~~~ denotes the function rescaled by 1/((-1)^(m+1) m!). | |
Here again N is chosen to make z+N large enough for the minimum | |
term in the last series to become smaller than eps. | |
TODO: the current estimation of N for m > 0 is *very suboptimal*. | |
TODO: implement the reflection formula for m > 0, Re(z) << 0. | |
It is generally a combination of multiple cotangents. Need to | |
figure out a reasonably simple way to generate these formulas | |
on the fly. | |
TODO: maybe use exact algorithms to compute psi for integral | |
and certain rational arguments, as this can be much more | |
efficient. (On the other hand, the availability of these | |
special values provides a convenient way to test the general | |
algorithm.) | |
""" | |
# Harmonic numbers are just shifted digamma functions | |
# We should calculate these exactly when x is an integer | |
# and when doing so is faster. | |
def mpf_harmonic(x, prec, rnd): | |
if x in (fzero, fnan, finf): | |
return x | |
a = mpf_psi0(mpf_add(fone, x, prec+5), prec) | |
return mpf_add(a, mpf_euler(prec+5, rnd), prec, rnd) | |
def mpc_harmonic(z, prec, rnd): | |
if z[1] == fzero: | |
return (mpf_harmonic(z[0], prec, rnd), fzero) | |
a = mpc_psi0(mpc_add_mpf(z, fone, prec+5), prec) | |
return mpc_add_mpf(a, mpf_euler(prec+5, rnd), prec, rnd) | |
def mpf_psi0(x, prec, rnd=round_fast): | |
""" | |
Computation of the digamma function (psi function of order 0) | |
of a real argument. | |
""" | |
sign, man, exp, bc = x | |
wp = prec + 10 | |
if not man: | |
if x == finf: return x | |
if x == fninf or x == fnan: return fnan | |
if x == fzero or (exp >= 0 and sign): | |
raise ValueError("polygamma pole") | |
# Near 0 -- fixed-point arithmetic becomes bad | |
if exp+bc < -5: | |
v = mpf_psi0(mpf_add(x, fone, prec, rnd), prec, rnd) | |
return mpf_sub(v, mpf_div(fone, x, wp, rnd), prec, rnd) | |
# Reflection formula | |
if sign and exp+bc > 3: | |
c, s = mpf_cos_sin_pi(x, wp) | |
q = mpf_mul(mpf_div(c, s, wp), mpf_pi(wp), wp) | |
p = mpf_psi0(mpf_sub(fone, x, wp), wp) | |
return mpf_sub(p, q, prec, rnd) | |
# The logarithmic term is accurate enough | |
if (not sign) and bc + exp > wp: | |
return mpf_log(mpf_sub(x, fone, wp), prec, rnd) | |
# Initial recurrence to obtain a large enough x | |
m = to_int(x) | |
n = int(0.11*wp) + 2 | |
s = MPZ_ZERO | |
x = to_fixed(x, wp) | |
one = MPZ_ONE << wp | |
if m < n: | |
for k in xrange(m, n): | |
s -= (one << wp) // x | |
x += one | |
x -= one | |
# Logarithmic term | |
s += to_fixed(mpf_log(from_man_exp(x, -wp, wp), wp), wp) | |
# Endpoint term in Euler-Maclaurin expansion | |
s += (one << wp) // (2*x) | |
# Euler-Maclaurin remainder sum | |
x2 = (x*x) >> wp | |
t = one | |
prev = 0 | |
k = 1 | |
while 1: | |
t = (t*x2) >> wp | |
bsign, bman, bexp, bbc = mpf_bernoulli(2*k, wp) | |
offset = (bexp + 2*wp) | |
if offset >= 0: term = (bman << offset) // (t*(2*k)) | |
else: term = (bman >> (-offset)) // (t*(2*k)) | |
if k & 1: s -= term | |
else: s += term | |
if k > 2 and term >= prev: | |
break | |
prev = term | |
k += 1 | |
return from_man_exp(s, -wp, wp, rnd) | |
def mpc_psi0(z, prec, rnd=round_fast): | |
""" | |
Computation of the digamma function (psi function of order 0) | |
of a complex argument. | |
""" | |
re, im = z | |
# Fall back to the real case | |
if im == fzero: | |
return (mpf_psi0(re, prec, rnd), fzero) | |
wp = prec + 20 | |
sign, man, exp, bc = re | |
# Reflection formula | |
if sign and exp+bc > 3: | |
c = mpc_cos_pi(z, wp) | |
s = mpc_sin_pi(z, wp) | |
q = mpc_mul_mpf(mpc_div(c, s, wp), mpf_pi(wp), wp) | |
p = mpc_psi0(mpc_sub(mpc_one, z, wp), wp) | |
return mpc_sub(p, q, prec, rnd) | |
# Just the logarithmic term | |
if (not sign) and bc + exp > wp: | |
return mpc_log(mpc_sub(z, mpc_one, wp), prec, rnd) | |
# Initial recurrence to obtain a large enough z | |
w = to_int(re) | |
n = int(0.11*wp) + 2 | |
s = mpc_zero | |
if w < n: | |
for k in xrange(w, n): | |
s = mpc_sub(s, mpc_reciprocal(z, wp), wp) | |
z = mpc_add_mpf(z, fone, wp) | |
z = mpc_sub(z, mpc_one, wp) | |
# Logarithmic and endpoint term | |
s = mpc_add(s, mpc_log(z, wp), wp) | |
s = mpc_add(s, mpc_div(mpc_half, z, wp), wp) | |
# Euler-Maclaurin remainder sum | |
z2 = mpc_square(z, wp) | |
t = mpc_one | |
prev = mpc_zero | |
szprev = fzero | |
k = 1 | |
eps = mpf_shift(fone, -wp+2) | |
while 1: | |
t = mpc_mul(t, z2, wp) | |
bern = mpf_bernoulli(2*k, wp) | |
term = mpc_mpf_div(bern, mpc_mul_int(t, 2*k, wp), wp) | |
s = mpc_sub(s, term, wp) | |
szterm = mpc_abs(term, 10) | |
if k > 2 and (mpf_le(szterm, eps) or mpf_le(szprev, szterm)): | |
break | |
prev = term | |
szprev = szterm | |
k += 1 | |
return s | |
# Currently unoptimized | |
def mpf_psi(m, x, prec, rnd=round_fast): | |
""" | |
Computation of the polygamma function of arbitrary integer order | |
m >= 0, for a real argument x. | |
""" | |
if m == 0: | |
return mpf_psi0(x, prec, rnd=round_fast) | |
return mpc_psi(m, (x, fzero), prec, rnd)[0] | |
def mpc_psi(m, z, prec, rnd=round_fast): | |
""" | |
Computation of the polygamma function of arbitrary integer order | |
m >= 0, for a complex argument z. | |
""" | |
if m == 0: | |
return mpc_psi0(z, prec, rnd) | |
re, im = z | |
wp = prec + 20 | |
sign, man, exp, bc = re | |
if not im[1]: | |
if im in (finf, fninf, fnan): | |
return (fnan, fnan) | |
if not man: | |
if re == finf and im == fzero: | |
return (fzero, fzero) | |
if re == fnan: | |
return (fnan, fnan) | |
# Recurrence | |
w = to_int(re) | |
n = int(0.4*wp + 4*m) | |
s = mpc_zero | |
if w < n: | |
for k in xrange(w, n): | |
t = mpc_pow_int(z, -m-1, wp) | |
s = mpc_add(s, t, wp) | |
z = mpc_add_mpf(z, fone, wp) | |
zm = mpc_pow_int(z, -m, wp) | |
z2 = mpc_pow_int(z, -2, wp) | |
# 1/m*(z+N)^m | |
integral_term = mpc_div_mpf(zm, from_int(m), wp) | |
s = mpc_add(s, integral_term, wp) | |
# 1/2*(z+N)^(-(m+1)) | |
s = mpc_add(s, mpc_mul_mpf(mpc_div(zm, z, wp), fhalf, wp), wp) | |
a = m + 1 | |
b = 2 | |
k = 1 | |
# Important: we want to sum up to the *relative* error, | |
# not the absolute error, because psi^(m)(z) might be tiny | |
magn = mpc_abs(s, 10) | |
magn = magn[2]+magn[3] | |
eps = mpf_shift(fone, magn-wp+2) | |
while 1: | |
zm = mpc_mul(zm, z2, wp) | |
bern = mpf_bernoulli(2*k, wp) | |
scal = mpf_mul_int(bern, a, wp) | |
scal = mpf_div(scal, from_int(b), wp) | |
term = mpc_mul_mpf(zm, scal, wp) | |
s = mpc_add(s, term, wp) | |
szterm = mpc_abs(term, 10) | |
if k > 2 and mpf_le(szterm, eps): | |
break | |
#print k, to_str(szterm, 10), to_str(eps, 10) | |
a *= (m+2*k)*(m+2*k+1) | |
b *= (2*k+1)*(2*k+2) | |
k += 1 | |
# Scale and sign factor | |
v = mpc_mul_mpf(s, mpf_gamma(from_int(m+1), wp), prec, rnd) | |
if not (m & 1): | |
v = mpf_neg(v[0]), mpf_neg(v[1]) | |
return v | |
#-----------------------------------------------------------------------# | |
# # | |
# Riemann zeta function # | |
# # | |
#-----------------------------------------------------------------------# | |
r""" | |
We use zeta(s) = eta(s) / (1 - 2**(1-s)) and Borwein's approximation | |
n-1 | |
___ k | |
-1 \ (-1) (d_k - d_n) | |
eta(s) ~= ---- ) ------------------ | |
d_n /___ s | |
k = 0 (k + 1) | |
where | |
k | |
___ i | |
\ (n + i - 1)! 4 | |
d_k = n ) ---------------. | |
/___ (n - i)! (2i)! | |
i = 0 | |
If s = a + b*I, the absolute error for eta(s) is bounded by | |
3 (1 + 2|b|) | |
------------ * exp(|b| pi/2) | |
n | |
(3+sqrt(8)) | |
Disregarding the linear term, we have approximately, | |
log(err) ~= log(exp(1.58*|b|)) - log(5.8**n) | |
log(err) ~= 1.58*|b| - log(5.8)*n | |
log(err) ~= 1.58*|b| - 1.76*n | |
log2(err) ~= 2.28*|b| - 2.54*n | |
So for p bits, we should choose n > (p + 2.28*|b|) / 2.54. | |
References: | |
----------- | |
Peter Borwein, "An Efficient Algorithm for the Riemann Zeta Function" | |
http://www.cecm.sfu.ca/personal/pborwein/PAPERS/P117.ps | |
http://en.wikipedia.org/wiki/Dirichlet_eta_function | |
""" | |
borwein_cache = {} | |
def borwein_coefficients(n): | |
if n in borwein_cache: | |
return borwein_cache[n] | |
ds = [MPZ_ZERO] * (n+1) | |
d = MPZ_ONE | |
s = ds[0] = MPZ_ONE | |
for i in range(1, n+1): | |
d = d * 4 * (n+i-1) * (n-i+1) | |
d //= ((2*i) * ((2*i)-1)) | |
s += d | |
ds[i] = s | |
borwein_cache[n] = ds | |
return ds | |
ZETA_INT_CACHE_MAX_PREC = 1000 | |
zeta_int_cache = {} | |
def mpf_zeta_int(s, prec, rnd=round_fast): | |
""" | |
Optimized computation of zeta(s) for an integer s. | |
""" | |
wp = prec + 20 | |
s = int(s) | |
if s in zeta_int_cache and zeta_int_cache[s][0] >= wp: | |
return mpf_pos(zeta_int_cache[s][1], prec, rnd) | |
if s < 2: | |
if s == 1: | |
raise ValueError("zeta(1) pole") | |
if not s: | |
return mpf_neg(fhalf) | |
return mpf_div(mpf_bernoulli(-s+1, wp), from_int(s-1), prec, rnd) | |
# 2^-s term vanishes? | |
if s >= wp: | |
return mpf_perturb(fone, 0, prec, rnd) | |
# 5^-s term vanishes? | |
elif s >= wp*0.431: | |
t = one = 1 << wp | |
t += 1 << (wp - s) | |
t += one // (MPZ_THREE ** s) | |
t += 1 << max(0, wp - s*2) | |
return from_man_exp(t, -wp, prec, rnd) | |
else: | |
# Fast enough to sum directly? | |
# Even better, we use the Euler product (idea stolen from pari) | |
m = (float(wp)/(s-1) + 1) | |
if m < 30: | |
needed_terms = int(2.0**m + 1) | |
if needed_terms < int(wp/2.54 + 5) / 10: | |
t = fone | |
for k in list_primes(needed_terms): | |
#print k, needed_terms | |
powprec = int(wp - s*math.log(k,2)) | |
if powprec < 2: | |
break | |
a = mpf_sub(fone, mpf_pow_int(from_int(k), -s, powprec), wp) | |
t = mpf_mul(t, a, wp) | |
return mpf_div(fone, t, wp) | |
# Use Borwein's algorithm | |
n = int(wp/2.54 + 5) | |
d = borwein_coefficients(n) | |
t = MPZ_ZERO | |
s = MPZ(s) | |
for k in xrange(n): | |
t += (((-1)**k * (d[k] - d[n])) << wp) // (k+1)**s | |
t = (t << wp) // (-d[n]) | |
t = (t << wp) // ((1 << wp) - (1 << (wp+1-s))) | |
if (s in zeta_int_cache and zeta_int_cache[s][0] < wp) or (s not in zeta_int_cache): | |
zeta_int_cache[s] = (wp, from_man_exp(t, -wp-wp)) | |
return from_man_exp(t, -wp-wp, prec, rnd) | |
def mpf_zeta(s, prec, rnd=round_fast, alt=0): | |
sign, man, exp, bc = s | |
if not man: | |
if s == fzero: | |
if alt: | |
return fhalf | |
else: | |
return mpf_neg(fhalf) | |
if s == finf: | |
return fone | |
return fnan | |
wp = prec + 20 | |
# First term vanishes? | |
if (not sign) and (exp + bc > (math.log(wp,2) + 2)): | |
return mpf_perturb(fone, alt, prec, rnd) | |
# Optimize for integer arguments | |
elif exp >= 0: | |
if alt: | |
if s == fone: | |
return mpf_ln2(prec, rnd) | |
z = mpf_zeta_int(to_int(s), wp, negative_rnd[rnd]) | |
q = mpf_sub(fone, mpf_pow(ftwo, mpf_sub(fone, s, wp), wp), wp) | |
return mpf_mul(z, q, prec, rnd) | |
else: | |
return mpf_zeta_int(to_int(s), prec, rnd) | |
# Negative: use the reflection formula | |
# Borwein only proves the accuracy bound for x >= 1/2. However, based on | |
# tests, the accuracy without reflection is quite good even some distance | |
# to the left of 1/2. XXX: verify this. | |
if sign: | |
# XXX: could use the separate refl. formula for Dirichlet eta | |
if alt: | |
q = mpf_sub(fone, mpf_pow(ftwo, mpf_sub(fone, s, wp), wp), wp) | |
return mpf_mul(mpf_zeta(s, wp), q, prec, rnd) | |
# XXX: -1 should be done exactly | |
y = mpf_sub(fone, s, 10*wp) | |
a = mpf_gamma(y, wp) | |
b = mpf_zeta(y, wp) | |
c = mpf_sin_pi(mpf_shift(s, -1), wp) | |
wp2 = wp + max(0,exp+bc) | |
pi = mpf_pi(wp+wp2) | |
d = mpf_div(mpf_pow(mpf_shift(pi, 1), s, wp2), pi, wp2) | |
return mpf_mul(a,mpf_mul(b,mpf_mul(c,d,wp),wp),prec,rnd) | |
# Near pole | |
r = mpf_sub(fone, s, wp) | |
asign, aman, aexp, abc = mpf_abs(r) | |
pole_dist = -2*(aexp+abc) | |
if pole_dist > wp: | |
if alt: | |
return mpf_ln2(prec, rnd) | |
else: | |
q = mpf_neg(mpf_div(fone, r, wp)) | |
return mpf_add(q, mpf_euler(wp), prec, rnd) | |
else: | |
wp += max(0, pole_dist) | |
t = MPZ_ZERO | |
#wp += 16 - (prec & 15) | |
# Use Borwein's algorithm | |
n = int(wp/2.54 + 5) | |
d = borwein_coefficients(n) | |
t = MPZ_ZERO | |
sf = to_fixed(s, wp) | |
ln2 = ln2_fixed(wp) | |
for k in xrange(n): | |
u = (-sf*log_int_fixed(k+1, wp, ln2)) >> wp | |
#esign, eman, eexp, ebc = mpf_exp(u, wp) | |
#offset = eexp + wp | |
#if offset >= 0: | |
# w = ((d[k] - d[n]) * eman) << offset | |
#else: | |
# w = ((d[k] - d[n]) * eman) >> (-offset) | |
eman = exp_fixed(u, wp, ln2) | |
w = (d[k] - d[n]) * eman | |
if k & 1: | |
t -= w | |
else: | |
t += w | |
t = t // (-d[n]) | |
t = from_man_exp(t, -wp, wp) | |
if alt: | |
return mpf_pos(t, prec, rnd) | |
else: | |
q = mpf_sub(fone, mpf_pow(ftwo, mpf_sub(fone, s, wp), wp), wp) | |
return mpf_div(t, q, prec, rnd) | |
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 + max(0, 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 | |
ln2 = ln2_fixed(wp) | |
pi2 = pi_fixed(wp-1) | |
wp2 = wp+wp | |
for k in xrange(n): | |
log = log_int_fixed(k+1, wp, ln2) | |
# A square root is much cheaper than an exp | |
if critical_line: | |
w = one_2wp // isqrt_fast((k+1) << wp2) | |
else: | |
w = exp_fixed((-ref*log) >> wp, wp) | |
if k & 1: | |
w *= (d[n] - d[k]) | |
else: | |
w *= (d[k] - d[n]) | |
wre, wim = cos_sin_fixed((-imf*log)>>wp, wp, pi2) | |
tre += (w * wre) >> wp | |
tim += (w * wim) >> 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) | |
def mpf_altzeta(s, prec, rnd=round_fast): | |
return mpf_zeta(s, prec, rnd, 1) | |
def mpc_altzeta(s, prec, rnd=round_fast): | |
return mpc_zeta(s, prec, rnd, 1) | |
# Not optimized currently | |
mpf_zetasum = None | |
def pow_fixed(x, n, wp): | |
if n == 1: | |
return x | |
y = MPZ_ONE << wp | |
while n: | |
if n & 1: | |
y = (y*x) >> wp | |
n -= 1 | |
x = (x*x) >> wp | |
n //= 2 | |
return y | |
# TODO: optimize / cleanup interface / unify with list_primes | |
sieve_cache = [] | |
primes_cache = [] | |
mult_cache = [] | |
def primesieve(n): | |
global sieve_cache, primes_cache, mult_cache | |
if n < len(sieve_cache): | |
sieve = sieve_cache#[:n+1] | |
primes = primes_cache[:primes_cache.index(max(sieve))+1] | |
mult = mult_cache#[:n+1] | |
return sieve, primes, mult | |
sieve = [0] * (n+1) | |
mult = [0] * (n+1) | |
primes = list_primes(n) | |
for p in primes: | |
#sieve[p::p] = p | |
for k in xrange(p,n+1,p): | |
sieve[k] = p | |
for i, p in enumerate(sieve): | |
if i >= 2: | |
m = 1 | |
n = i // p | |
while not n % p: | |
n //= p | |
m += 1 | |
mult[i] = m | |
sieve_cache = sieve | |
primes_cache = primes | |
mult_cache = mult | |
return sieve, primes, mult | |
def zetasum_sieved(critical_line, sre, sim, a, n, wp): | |
if a < 1: | |
raise ValueError("a cannot be less than 1") | |
sieve, primes, mult = primesieve(a+n) | |
basic_powers = {} | |
one = MPZ_ONE << wp | |
one_2wp = MPZ_ONE << (2*wp) | |
wp2 = wp+wp | |
ln2 = ln2_fixed(wp) | |
pi2 = pi_fixed(wp-1) | |
for p in primes: | |
if p*2 > a+n: | |
break | |
log = log_int_fixed(p, wp, ln2) | |
cos, sin = cos_sin_fixed((-sim*log)>>wp, wp, pi2) | |
if critical_line: | |
u = one_2wp // isqrt_fast(p<<wp2) | |
else: | |
u = exp_fixed((-sre*log)>>wp, wp) | |
pre = (u*cos) >> wp | |
pim = (u*sin) >> wp | |
basic_powers[p] = [(pre, pim)] | |
tre, tim = pre, pim | |
for m in range(1,int(math.log(a+n,p)+0.01)+1): | |
tre, tim = ((pre*tre-pim*tim)>>wp), ((pim*tre+pre*tim)>>wp) | |
basic_powers[p].append((tre,tim)) | |
xre = MPZ_ZERO | |
xim = MPZ_ZERO | |
if a == 1: | |
xre += one | |
aa = max(a,2) | |
for k in xrange(aa, a+n+1): | |
p = sieve[k] | |
if p in basic_powers: | |
m = mult[k] | |
tre, tim = basic_powers[p][m-1] | |
while 1: | |
k //= p**m | |
if k == 1: | |
break | |
p = sieve[k] | |
m = mult[k] | |
pre, pim = basic_powers[p][m-1] | |
tre, tim = ((pre*tre-pim*tim)>>wp), ((pim*tre+pre*tim)>>wp) | |
else: | |
log = log_int_fixed(k, wp, ln2) | |
cos, sin = cos_sin_fixed((-sim*log)>>wp, wp, pi2) | |
if critical_line: | |
u = one_2wp // isqrt_fast(k<<wp2) | |
else: | |
u = exp_fixed((-sre*log)>>wp, wp) | |
tre = (u*cos) >> wp | |
tim = (u*sin) >> wp | |
xre += tre | |
xim += tim | |
return xre, xim | |
# Set to something large to disable | |
ZETASUM_SIEVE_CUTOFF = 10 | |
def mpc_zetasum(s, a, n, derivatives, reflect, prec): | |
""" | |
Fast version of mp._zetasum, assuming s = complex, a = integer. | |
""" | |
wp = prec + 10 | |
derivatives = list(derivatives) | |
have_derivatives = derivatives != [0] | |
have_one_derivative = len(derivatives) == 1 | |
# parse s | |
sre, sim = s | |
critical_line = (sre == fhalf) | |
sre = to_fixed(sre, wp) | |
sim = to_fixed(sim, wp) | |
if a > 0 and n > ZETASUM_SIEVE_CUTOFF and not have_derivatives \ | |
and not reflect and (n < 4e7 or sys.maxsize > 2**32): | |
re, im = zetasum_sieved(critical_line, sre, sim, a, n, wp) | |
xs = [(from_man_exp(re, -wp, prec, 'n'), from_man_exp(im, -wp, prec, 'n'))] | |
return xs, [] | |
maxd = max(derivatives) | |
if not have_one_derivative: | |
derivatives = range(maxd+1) | |
# x_d = 0, y_d = 0 | |
xre = [MPZ_ZERO for d in derivatives] | |
xim = [MPZ_ZERO for d in derivatives] | |
if reflect: | |
yre = [MPZ_ZERO for d in derivatives] | |
yim = [MPZ_ZERO for d in derivatives] | |
else: | |
yre = yim = [] | |
one = MPZ_ONE << wp | |
one_2wp = MPZ_ONE << (2*wp) | |
ln2 = ln2_fixed(wp) | |
pi2 = pi_fixed(wp-1) | |
wp2 = wp+wp | |
for w in xrange(a, a+n+1): | |
log = log_int_fixed(w, wp, ln2) | |
cos, sin = cos_sin_fixed((-sim*log)>>wp, wp, pi2) | |
if critical_line: | |
u = one_2wp // isqrt_fast(w<<wp2) | |
else: | |
u = exp_fixed((-sre*log)>>wp, wp) | |
xterm_re = (u * cos) >> wp | |
xterm_im = (u * sin) >> wp | |
if reflect: | |
reciprocal = (one_2wp // (u*w)) | |
yterm_re = (reciprocal * cos) >> wp | |
yterm_im = (reciprocal * sin) >> wp | |
if have_derivatives: | |
if have_one_derivative: | |
log = pow_fixed(log, maxd, wp) | |
xre[0] += (xterm_re * log) >> wp | |
xim[0] += (xterm_im * log) >> wp | |
if reflect: | |
yre[0] += (yterm_re * log) >> wp | |
yim[0] += (yterm_im * log) >> wp | |
else: | |
t = MPZ_ONE << wp | |
for d in derivatives: | |
xre[d] += (xterm_re * t) >> wp | |
xim[d] += (xterm_im * t) >> wp | |
if reflect: | |
yre[d] += (yterm_re * t) >> wp | |
yim[d] += (yterm_im * t) >> wp | |
t = (t * log) >> wp | |
else: | |
xre[0] += xterm_re | |
xim[0] += xterm_im | |
if reflect: | |
yre[0] += yterm_re | |
yim[0] += yterm_im | |
if have_derivatives: | |
if have_one_derivative: | |
if maxd % 2: | |
xre[0] = -xre[0] | |
xim[0] = -xim[0] | |
if reflect: | |
yre[0] = -yre[0] | |
yim[0] = -yim[0] | |
else: | |
xre = [(-1)**d * xre[d] for d in derivatives] | |
xim = [(-1)**d * xim[d] for d in derivatives] | |
if reflect: | |
yre = [(-1)**d * yre[d] for d in derivatives] | |
yim = [(-1)**d * yim[d] for d in derivatives] | |
xs = [(from_man_exp(xa, -wp, prec, 'n'), from_man_exp(xb, -wp, prec, 'n')) | |
for (xa, xb) in zip(xre, xim)] | |
ys = [(from_man_exp(ya, -wp, prec, 'n'), from_man_exp(yb, -wp, prec, 'n')) | |
for (ya, yb) in zip(yre, yim)] | |
return xs, ys | |
#-----------------------------------------------------------------------# | |
# # | |
# The gamma function (NEW IMPLEMENTATION) # | |
# # | |
#-----------------------------------------------------------------------# | |
# Higher means faster, but more precomputation time | |
MAX_GAMMA_TAYLOR_PREC = 5000 | |
# Need to derive higher bounds for Taylor series to go higher | |
assert MAX_GAMMA_TAYLOR_PREC < 15000 | |
# Use Stirling's series if abs(x) > beta*prec | |
# Important: must be large enough for convergence! | |
GAMMA_STIRLING_BETA = 0.2 | |
SMALL_FACTORIAL_CACHE_SIZE = 150 | |
gamma_taylor_cache = {} | |
gamma_stirling_cache = {} | |
small_factorial_cache = [from_int(ifac(n)) for \ | |
n in range(SMALL_FACTORIAL_CACHE_SIZE+1)] | |
def zeta_array(N, prec): | |
""" | |
zeta(n) = A * pi**n / n! + B | |
where A is a rational number (A = Bernoulli number | |
for n even) and B is an infinite sum over powers of exp(2*pi). | |
(B = 0 for n even). | |
TODO: this is currently only used for gamma, but could | |
be very useful elsewhere. | |
""" | |
extra = 30 | |
wp = prec+extra | |
zeta_values = [MPZ_ZERO] * (N+2) | |
pi = pi_fixed(wp) | |
# STEP 1: | |
one = MPZ_ONE << wp | |
zeta_values[0] = -one//2 | |
f_2pi = mpf_shift(mpf_pi(wp),1) | |
exp_2pi_k = exp_2pi = mpf_exp(f_2pi, wp) | |
# Compute exponential series | |
# Store values of 1/(exp(2*pi*k)-1), | |
# exp(2*pi*k)/(exp(2*pi*k)-1)**2, 1/(exp(2*pi*k)-1)**2 | |
# pi*k*exp(2*pi*k)/(exp(2*pi*k)-1)**2 | |
exps3 = [] | |
k = 1 | |
while 1: | |
tp = wp - 9*k | |
if tp < 1: | |
break | |
# 1/(exp(2*pi*k-1) | |
q1 = mpf_div(fone, mpf_sub(exp_2pi_k, fone, tp), tp) | |
# pi*k*exp(2*pi*k)/(exp(2*pi*k)-1)**2 | |
q2 = mpf_mul(exp_2pi_k, mpf_mul(q1,q1,tp), tp) | |
q1 = to_fixed(q1, wp) | |
q2 = to_fixed(q2, wp) | |
q2 = (k * q2 * pi) >> wp | |
exps3.append((q1, q2)) | |
# Multiply for next round | |
exp_2pi_k = mpf_mul(exp_2pi_k, exp_2pi, wp) | |
k += 1 | |
# Exponential sum | |
for n in xrange(3, N+1, 2): | |
s = MPZ_ZERO | |
k = 1 | |
for e1, e2 in exps3: | |
if n%4 == 3: | |
t = e1 // k**n | |
else: | |
U = (n-1)//4 | |
t = (e1 + e2//U) // k**n | |
if not t: | |
break | |
s += t | |
k += 1 | |
zeta_values[n] = -2*s | |
# Even zeta values | |
B = [mpf_abs(mpf_bernoulli(k,wp)) for k in xrange(N+2)] | |
pi_pow = fpi = mpf_pow_int(mpf_shift(mpf_pi(wp), 1), 2, wp) | |
pi_pow = mpf_div(pi_pow, from_int(4), wp) | |
for n in xrange(2,N+2,2): | |
z = mpf_mul(B[n], pi_pow, wp) | |
zeta_values[n] = to_fixed(z, wp) | |
pi_pow = mpf_mul(pi_pow, fpi, wp) | |
pi_pow = mpf_div(pi_pow, from_int((n+1)*(n+2)), wp) | |
# Zeta sum | |
reciprocal_pi = (one << wp) // pi | |
for n in xrange(3, N+1, 4): | |
U = (n-3)//4 | |
s = zeta_values[4*U+4]*(4*U+7)//4 | |
for k in xrange(1, U+1): | |
s -= (zeta_values[4*k] * zeta_values[4*U+4-4*k]) >> wp | |
zeta_values[n] += (2*s*reciprocal_pi) >> wp | |
for n in xrange(5, N+1, 4): | |
U = (n-1)//4 | |
s = zeta_values[4*U+2]*(2*U+1) | |
for k in xrange(1, 2*U+1): | |
s += ((-1)**k*2*k* zeta_values[2*k] * zeta_values[4*U+2-2*k])>>wp | |
zeta_values[n] += ((s*reciprocal_pi)>>wp)//(2*U) | |
return [x>>extra for x in zeta_values] | |
def gamma_taylor_coefficients(inprec): | |
""" | |
Gives the Taylor coefficients of 1/gamma(1+x) as | |
a list of fixed-point numbers. Enough coefficients are returned | |
to ensure that the series converges to the given precision | |
when x is in [0.5, 1.5]. | |
""" | |
# Reuse nearby cache values (small case) | |
if inprec < 400: | |
prec = inprec + (10-(inprec%10)) | |
elif inprec < 1000: | |
prec = inprec + (30-(inprec%30)) | |
else: | |
prec = inprec | |
if prec in gamma_taylor_cache: | |
return gamma_taylor_cache[prec], prec | |
# Experimentally determined bounds | |
if prec < 1000: | |
N = int(prec**0.76 + 2) | |
else: | |
# Valid to at least 15000 bits | |
N = int(prec**0.787 + 2) | |
# Reuse higher precision values | |
for cprec in gamma_taylor_cache: | |
if cprec > prec: | |
coeffs = [x>>(cprec-prec) for x in gamma_taylor_cache[cprec][-N:]] | |
if inprec < 1000: | |
gamma_taylor_cache[prec] = coeffs | |
return coeffs, prec | |
# Cache at a higher precision (large case) | |
if prec > 1000: | |
prec = int(prec * 1.2) | |
wp = prec + 20 | |
A = [0] * N | |
A[0] = MPZ_ZERO | |
A[1] = MPZ_ONE << wp | |
A[2] = euler_fixed(wp) | |
# SLOW, reference implementation | |
#zeta_values = [0,0]+[to_fixed(mpf_zeta_int(k,wp),wp) for k in xrange(2,N)] | |
zeta_values = zeta_array(N, wp) | |
for k in xrange(3, N): | |
a = (-A[2]*A[k-1])>>wp | |
for j in xrange(2,k): | |
a += ((-1)**j * zeta_values[j] * A[k-j]) >> wp | |
a //= (1-k) | |
A[k] = a | |
A = [a>>20 for a in A] | |
A = A[::-1] | |
A = A[:-1] | |
gamma_taylor_cache[prec] = A | |
#return A, prec | |
return gamma_taylor_coefficients(inprec) | |
def gamma_fixed_taylor(xmpf, x, wp, prec, rnd, type): | |
# Determine nearest multiple of N/2 | |
#n = int(x >> (wp-1)) | |
#steps = (n-1)>>1 | |
nearest_int = ((x >> (wp-1)) + MPZ_ONE) >> 1 | |
one = MPZ_ONE << wp | |
coeffs, cwp = gamma_taylor_coefficients(wp) | |
if nearest_int > 0: | |
r = one | |
for i in xrange(nearest_int-1): | |
x -= one | |
r = (r*x) >> wp | |
x -= one | |
p = MPZ_ZERO | |
for c in coeffs: | |
p = c + ((x*p)>>wp) | |
p >>= (cwp-wp) | |
if type == 0: | |
return from_man_exp((r<<wp)//p, -wp, prec, rnd) | |
if type == 2: | |
return mpf_shift(from_rational(p, (r<<wp), prec, rnd), wp) | |
if type == 3: | |
return mpf_log(mpf_abs(from_man_exp((r<<wp)//p, -wp)), prec, rnd) | |
else: | |
r = one | |
for i in xrange(-nearest_int): | |
r = (r*x) >> wp | |
x += one | |
p = MPZ_ZERO | |
for c in coeffs: | |
p = c + ((x*p)>>wp) | |
p >>= (cwp-wp) | |
if wp - bitcount(abs(x)) > 10: | |
# pass very close to 0, so do floating-point multiply | |
g = mpf_add(xmpf, from_int(-nearest_int)) # exact | |
r = from_man_exp(p*r,-wp-wp) | |
r = mpf_mul(r, g, wp) | |
if type == 0: | |
return mpf_div(fone, r, prec, rnd) | |
if type == 2: | |
return mpf_pos(r, prec, rnd) | |
if type == 3: | |
return mpf_log(mpf_abs(mpf_div(fone, r, wp)), prec, rnd) | |
else: | |
r = from_man_exp(x*p*r,-3*wp) | |
if type == 0: return mpf_div(fone, r, prec, rnd) | |
if type == 2: return mpf_pos(r, prec, rnd) | |
if type == 3: return mpf_neg(mpf_log(mpf_abs(r), prec, rnd)) | |
def stirling_coefficient(n): | |
if n in gamma_stirling_cache: | |
return gamma_stirling_cache[n] | |
p, q = bernfrac(n) | |
q *= MPZ(n*(n-1)) | |
gamma_stirling_cache[n] = p, q, bitcount(abs(p)), bitcount(q) | |
return gamma_stirling_cache[n] | |
def real_stirling_series(x, prec): | |
""" | |
Sums the rational part of Stirling's expansion, | |
log(sqrt(2*pi)) - z + 1/(12*z) - 1/(360*z^3) + ... | |
""" | |
t = (MPZ_ONE<<(prec+prec)) // x # t = 1/x | |
u = (t*t)>>prec # u = 1/x**2 | |
s = ln_sqrt2pi_fixed(prec) - x | |
# Add initial terms of Stirling's series | |
s += t//12; t = (t*u)>>prec | |
s -= t//360; t = (t*u)>>prec | |
s += t//1260; t = (t*u)>>prec | |
s -= t//1680; t = (t*u)>>prec | |
if not t: return s | |
s += t//1188; t = (t*u)>>prec | |
s -= 691*t//360360; t = (t*u)>>prec | |
s += t//156; t = (t*u)>>prec | |
if not t: return s | |
s -= 3617*t//122400; t = (t*u)>>prec | |
s += 43867*t//244188; t = (t*u)>>prec | |
s -= 174611*t//125400; t = (t*u)>>prec | |
if not t: return s | |
k = 22 | |
# From here on, the coefficients are growing, so we | |
# have to keep t at a roughly constant size | |
usize = bitcount(abs(u)) | |
tsize = bitcount(abs(t)) | |
texp = 0 | |
while 1: | |
p, q, pb, qb = stirling_coefficient(k) | |
term_mag = tsize + pb + texp | |
shift = -texp | |
m = pb - term_mag | |
if m > 0 and shift < m: | |
p >>= m | |
shift -= m | |
m = tsize - term_mag | |
if m > 0 and shift < m: | |
w = t >> m | |
shift -= m | |
else: | |
w = t | |
term = (t*p//q) >> shift | |
if not term: | |
break | |
s += term | |
t = (t*u) >> usize | |
texp -= (prec - usize) | |
k += 2 | |
return s | |
def complex_stirling_series(x, y, prec): | |
# t = 1/z | |
_m = (x*x + y*y) >> prec | |
tre = (x << prec) // _m | |
tim = (-y << prec) // _m | |
# u = 1/z**2 | |
ure = (tre*tre - tim*tim) >> prec | |
uim = tim*tre >> (prec-1) | |
# s = log(sqrt(2*pi)) - z | |
sre = ln_sqrt2pi_fixed(prec) - x | |
sim = -y | |
# Add initial terms of Stirling's series | |
sre += tre//12; sim += tim//12; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre -= tre//360; sim -= tim//360; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre += tre//1260; sim += tim//1260; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre -= tre//1680; sim -= tim//1680; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
if abs(tre) + abs(tim) < 5: return sre, sim | |
sre += tre//1188; sim += tim//1188; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre -= 691*tre//360360; sim -= 691*tim//360360; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre += tre//156; sim += tim//156; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
if abs(tre) + abs(tim) < 5: return sre, sim | |
sre -= 3617*tre//122400; sim -= 3617*tim//122400; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre += 43867*tre//244188; sim += 43867*tim//244188; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
sre -= 174611*tre//125400; sim -= 174611*tim//125400; | |
tre, tim = ((tre*ure-tim*uim)>>prec), ((tre*uim+tim*ure)>>prec) | |
if abs(tre) + abs(tim) < 5: return sre, sim | |
k = 22 | |
# From here on, the coefficients are growing, so we | |
# have to keep t at a roughly constant size | |
usize = bitcount(max(abs(ure), abs(uim))) | |
tsize = bitcount(max(abs(tre), abs(tim))) | |
texp = 0 | |
while 1: | |
p, q, pb, qb = stirling_coefficient(k) | |
term_mag = tsize + pb + texp | |
shift = -texp | |
m = pb - term_mag | |
if m > 0 and shift < m: | |
p >>= m | |
shift -= m | |
m = tsize - term_mag | |
if m > 0 and shift < m: | |
wre = tre >> m | |
wim = tim >> m | |
shift -= m | |
else: | |
wre = tre | |
wim = tim | |
termre = (tre*p//q) >> shift | |
termim = (tim*p//q) >> shift | |
if abs(termre) + abs(termim) < 5: | |
break | |
sre += termre | |
sim += termim | |
tre, tim = ((tre*ure - tim*uim)>>usize), \ | |
((tre*uim + tim*ure)>>usize) | |
texp -= (prec - usize) | |
k += 2 | |
return sre, sim | |
def mpf_gamma(x, prec, rnd='d', type=0): | |
""" | |
This function implements multipurpose evaluation of the gamma | |
function, G(x), as well as the following versions of the same: | |
type = 0 -- G(x) [standard gamma function] | |
type = 1 -- G(x+1) = x*G(x+1) = x! [factorial] | |
type = 2 -- 1/G(x) [reciprocal gamma function] | |
type = 3 -- log(|G(x)|) [log-gamma function, real part] | |
""" | |
# Specal values | |
sign, man, exp, bc = x | |
if not man: | |
if x == fzero: | |
if type == 1: return fone | |
if type == 2: return fzero | |
raise ValueError("gamma function pole") | |
if x == finf: | |
if type == 2: return fzero | |
return finf | |
return fnan | |
# First of all, for log gamma, numbers can be well beyond the fixed-point | |
# range, so we must take care of huge numbers before e.g. trying | |
# to convert x to the nearest integer | |
if type == 3: | |
wp = prec+20 | |
if exp+bc > wp and not sign: | |
return mpf_sub(mpf_mul(x, mpf_log(x, wp), wp), x, prec, rnd) | |
# We strongly want to special-case small integers | |
is_integer = exp >= 0 | |
if is_integer: | |
# Poles | |
if sign: | |
if type == 2: | |
return fzero | |
raise ValueError("gamma function pole") | |
# n = x | |
n = man << exp | |
if n < SMALL_FACTORIAL_CACHE_SIZE: | |
if type == 0: | |
return mpf_pos(small_factorial_cache[n-1], prec, rnd) | |
if type == 1: | |
return mpf_pos(small_factorial_cache[n], prec, rnd) | |
if type == 2: | |
return mpf_div(fone, small_factorial_cache[n-1], prec, rnd) | |
if type == 3: | |
return mpf_log(small_factorial_cache[n-1], prec, rnd) | |
else: | |
# floor(abs(x)) | |
n = int(man >> (-exp)) | |
# Estimate size and precision | |
# Estimate log(gamma(|x|),2) as x*log(x,2) | |
mag = exp + bc | |
gamma_size = n*mag | |
if type == 3: | |
wp = prec + 20 | |
else: | |
wp = prec + bitcount(gamma_size) + 20 | |
# Very close to 0, pole | |
if mag < -wp: | |
if type == 0: | |
return mpf_sub(mpf_div(fone,x, wp),mpf_shift(fone,-wp),prec,rnd) | |
if type == 1: return mpf_sub(fone, x, prec, rnd) | |
if type == 2: return mpf_add(x, mpf_shift(fone,mag-wp), prec, rnd) | |
if type == 3: return mpf_neg(mpf_log(mpf_abs(x), prec, rnd)) | |
# From now on, we assume having a gamma function | |
if type == 1: | |
return mpf_gamma(mpf_add(x, fone), prec, rnd, 0) | |
# Special case integers (those not small enough to be caught above, | |
# but still small enough for an exact factorial to be faster | |
# than an approximate algorithm), and half-integers | |
if exp >= -1: | |
if is_integer: | |
if gamma_size < 10*wp: | |
if type == 0: | |
return from_int(ifac(n-1), prec, rnd) | |
if type == 2: | |
return from_rational(MPZ_ONE, ifac(n-1), prec, rnd) | |
if type == 3: | |
return mpf_log(from_int(ifac(n-1)), prec, rnd) | |
# half-integer | |
if n < 100 or gamma_size < 10*wp: | |
if sign: | |
w = sqrtpi_fixed(wp) | |
if n % 2: f = ifac2(2*n+1) | |
else: f = -ifac2(2*n+1) | |
if type == 0: | |
return mpf_shift(from_rational(w, f, prec, rnd), -wp+n+1) | |
if type == 2: | |
return mpf_shift(from_rational(f, w, prec, rnd), wp-n-1) | |
if type == 3: | |
return mpf_log(mpf_shift(from_rational(w, abs(f), | |
prec, rnd), -wp+n+1), prec, rnd) | |
elif n == 0: | |
if type == 0: return mpf_sqrtpi(prec, rnd) | |
if type == 2: return mpf_div(fone, mpf_sqrtpi(wp), prec, rnd) | |
if type == 3: return mpf_log(mpf_sqrtpi(wp), prec, rnd) | |
else: | |
w = sqrtpi_fixed(wp) | |
w = from_man_exp(w * ifac2(2*n-1), -wp-n) | |
if type == 0: return mpf_pos(w, prec, rnd) | |
if type == 2: return mpf_div(fone, w, prec, rnd) | |
if type == 3: return mpf_log(mpf_abs(w), prec, rnd) | |
# Convert to fixed point | |
offset = exp + wp | |
if offset >= 0: absxman = man << offset | |
else: absxman = man >> (-offset) | |
# For log gamma, provide accurate evaluation for x = 1+eps and 2+eps | |
if type == 3 and not sign: | |
one = MPZ_ONE << wp | |
one_dist = abs(absxman-one) | |
two_dist = abs(absxman-2*one) | |
cancellation = (wp - bitcount(min(one_dist, two_dist))) | |
if cancellation > 10: | |
xsub1 = mpf_sub(fone, x) | |
xsub2 = mpf_sub(ftwo, x) | |
xsub1mag = xsub1[2]+xsub1[3] | |
xsub2mag = xsub2[2]+xsub2[3] | |
if xsub1mag < -wp: | |
return mpf_mul(mpf_euler(wp), mpf_sub(fone, x), prec, rnd) | |
if xsub2mag < -wp: | |
return mpf_mul(mpf_sub(fone, mpf_euler(wp)), | |
mpf_sub(x, ftwo), prec, rnd) | |
# Proceed but increase precision | |
wp += max(-xsub1mag, -xsub2mag) | |
offset = exp + wp | |
if offset >= 0: absxman = man << offset | |
else: absxman = man >> (-offset) | |
# Use Taylor series if appropriate | |
n_for_stirling = int(GAMMA_STIRLING_BETA*wp) | |
if n < max(100, n_for_stirling) and wp < MAX_GAMMA_TAYLOR_PREC: | |
if sign: | |
absxman = -absxman | |
return gamma_fixed_taylor(x, absxman, wp, prec, rnd, type) | |
# Use Stirling's series | |
# First ensure that |x| is large enough for rapid convergence | |
xorig = x | |
# Argument reduction | |
r = 0 | |
if n < n_for_stirling: | |
r = one = MPZ_ONE << wp | |
d = n_for_stirling - n | |
for k in xrange(d): | |
r = (r * absxman) >> wp | |
absxman += one | |
x = xabs = from_man_exp(absxman, -wp) | |
if sign: | |
x = mpf_neg(x) | |
else: | |
xabs = mpf_abs(x) | |
# Asymptotic series | |
y = real_stirling_series(absxman, wp) | |
u = to_fixed(mpf_log(xabs, wp), wp) | |
u = ((absxman - (MPZ_ONE<<(wp-1))) * u) >> wp | |
y += u | |
w = from_man_exp(y, -wp) | |
# Compute final value | |
if sign: | |
# Reflection formula | |
A = mpf_mul(mpf_sin_pi(xorig, wp), xorig, wp) | |
B = mpf_neg(mpf_pi(wp)) | |
if type == 0 or type == 2: | |
A = mpf_mul(A, mpf_exp(w, wp)) | |
if r: | |
B = mpf_mul(B, from_man_exp(r, -wp), wp) | |
if type == 0: | |
return mpf_div(B, A, prec, rnd) | |
if type == 2: | |
return mpf_div(A, B, prec, rnd) | |
if type == 3: | |
if r: | |
B = mpf_mul(B, from_man_exp(r, -wp), wp) | |
A = mpf_add(mpf_log(mpf_abs(A), wp), w, wp) | |
return mpf_sub(mpf_log(mpf_abs(B), wp), A, prec, rnd) | |
else: | |
if type == 0: | |
if r: | |
return mpf_div(mpf_exp(w, wp), | |
from_man_exp(r, -wp), prec, rnd) | |
return mpf_exp(w, prec, rnd) | |
if type == 2: | |
if r: | |
return mpf_div(from_man_exp(r, -wp), | |
mpf_exp(w, wp), prec, rnd) | |
return mpf_exp(mpf_neg(w), prec, rnd) | |
if type == 3: | |
if r: | |
return mpf_sub(w, mpf_log(from_man_exp(r,-wp), wp), prec, rnd) | |
return mpf_pos(w, prec, rnd) | |
def mpc_gamma(z, prec, rnd='d', type=0): | |
a, b = z | |
asign, aman, aexp, abc = a | |
bsign, bman, bexp, bbc = b | |
if b == fzero: | |
# Imaginary part on negative half-axis for log-gamma function | |
if type == 3 and asign: | |
re = mpf_gamma(a, prec, rnd, 3) | |
n = (-aman) >> (-aexp) | |
im = mpf_mul_int(mpf_pi(prec+10), n, prec, rnd) | |
return re, im | |
return mpf_gamma(a, prec, rnd, type), fzero | |
# Some kind of complex inf/nan | |
if (not aman and aexp) or (not bman and bexp): | |
return (fnan, fnan) | |
# Initial working precision | |
wp = prec + 20 | |
amag = aexp+abc | |
bmag = bexp+bbc | |
if aman: | |
mag = max(amag, bmag) | |
else: | |
mag = bmag | |
# Close to 0 | |
if mag < -8: | |
if mag < -wp: | |
# 1/gamma(z) = z + euler*z^2 + O(z^3) | |
v = mpc_add(z, mpc_mul_mpf(mpc_mul(z,z,wp),mpf_euler(wp),wp), wp) | |
if type == 0: return mpc_reciprocal(v, prec, rnd) | |
if type == 1: return mpc_div(z, v, prec, rnd) | |
if type == 2: return mpc_pos(v, prec, rnd) | |
if type == 3: return mpc_log(mpc_reciprocal(v, prec), prec, rnd) | |
elif type != 1: | |
wp += (-mag) | |
# Handle huge log-gamma values; must do this before converting to | |
# a fixed-point value. TODO: determine a precise cutoff of validity | |
# depending on amag and bmag | |
if type == 3 and mag > wp and ((not asign) or (bmag >= amag)): | |
return mpc_sub(mpc_mul(z, mpc_log(z, wp), wp), z, prec, rnd) | |
# From now on, we assume having a gamma function | |
if type == 1: | |
return mpc_gamma((mpf_add(a, fone), b), prec, rnd, 0) | |
an = abs(to_int(a)) | |
bn = abs(to_int(b)) | |
absn = max(an, bn) | |
gamma_size = absn*mag | |
if type == 3: | |
pass | |
else: | |
wp += bitcount(gamma_size) | |
# Reflect to the right half-plane. Note that Stirling's expansion | |
# is valid in the left half-plane too, as long as we're not too close | |
# to the real axis, but in order to use this argument reduction | |
# in the negative direction must be implemented. | |
#need_reflection = asign and ((bmag < 0) or (amag-bmag > 4)) | |
need_reflection = asign | |
zorig = z | |
if need_reflection: | |
z = mpc_neg(z) | |
asign, aman, aexp, abc = a = z[0] | |
bsign, bman, bexp, bbc = b = z[1] | |
# Imaginary part very small compared to real one? | |
yfinal = 0 | |
balance_prec = 0 | |
if bmag < -10: | |
# Check z ~= 1 and z ~= 2 for loggamma | |
if type == 3: | |
zsub1 = mpc_sub_mpf(z, fone) | |
if zsub1[0] == fzero: | |
cancel1 = -bmag | |
else: | |
cancel1 = -max(zsub1[0][2]+zsub1[0][3], bmag) | |
if cancel1 > wp: | |
pi = mpf_pi(wp) | |
x = mpc_mul_mpf(zsub1, pi, wp) | |
x = mpc_mul(x, x, wp) | |
x = mpc_div_mpf(x, from_int(12), wp) | |
y = mpc_mul_mpf(zsub1, mpf_neg(mpf_euler(wp)), wp) | |
yfinal = mpc_add(x, y, wp) | |
if not need_reflection: | |
return mpc_pos(yfinal, prec, rnd) | |
elif cancel1 > 0: | |
wp += cancel1 | |
zsub2 = mpc_sub_mpf(z, ftwo) | |
if zsub2[0] == fzero: | |
cancel2 = -bmag | |
else: | |
cancel2 = -max(zsub2[0][2]+zsub2[0][3], bmag) | |
if cancel2 > wp: | |
pi = mpf_pi(wp) | |
t = mpf_sub(mpf_mul(pi, pi), from_int(6)) | |
x = mpc_mul_mpf(mpc_mul(zsub2, zsub2, wp), t, wp) | |
x = mpc_div_mpf(x, from_int(12), wp) | |
y = mpc_mul_mpf(zsub2, mpf_sub(fone, mpf_euler(wp)), wp) | |
yfinal = mpc_add(x, y, wp) | |
if not need_reflection: | |
return mpc_pos(yfinal, prec, rnd) | |
elif cancel2 > 0: | |
wp += cancel2 | |
if bmag < -wp: | |
# Compute directly from the real gamma function. | |
pp = 2*(wp+10) | |
aabs = mpf_abs(a) | |
eps = mpf_shift(fone, amag-wp) | |
x1 = mpf_gamma(aabs, pp, type=type) | |
x2 = mpf_gamma(mpf_add(aabs, eps), pp, type=type) | |
xprime = mpf_div(mpf_sub(x2, x1, pp), eps, pp) | |
y = mpf_mul(b, xprime, prec, rnd) | |
yfinal = (x1, y) | |
# Note: we still need to use the reflection formula for | |
# near-poles, and the correct branch of the log-gamma function | |
if not need_reflection: | |
return mpc_pos(yfinal, prec, rnd) | |
else: | |
balance_prec += (-bmag) | |
wp += balance_prec | |
n_for_stirling = int(GAMMA_STIRLING_BETA*wp) | |
need_reduction = absn < n_for_stirling | |
afix = to_fixed(a, wp) | |
bfix = to_fixed(b, wp) | |
r = 0 | |
if not yfinal: | |
zprered = z | |
# Argument reduction | |
if absn < n_for_stirling: | |
absn = complex(an, bn) | |
d = int((1 + n_for_stirling**2 - bn**2)**0.5 - an) | |
rre = one = MPZ_ONE << wp | |
rim = MPZ_ZERO | |
for k in xrange(d): | |
rre, rim = ((afix*rre-bfix*rim)>>wp), ((afix*rim + bfix*rre)>>wp) | |
afix += one | |
r = from_man_exp(rre, -wp), from_man_exp(rim, -wp) | |
a = from_man_exp(afix, -wp) | |
z = a, b | |
yre, yim = complex_stirling_series(afix, bfix, wp) | |
# (z-1/2)*log(z) + S | |
lre, lim = mpc_log(z, wp) | |
lre = to_fixed(lre, wp) | |
lim = to_fixed(lim, wp) | |
yre = ((lre*afix - lim*bfix)>>wp) - (lre>>1) + yre | |
yim = ((lre*bfix + lim*afix)>>wp) - (lim>>1) + yim | |
y = from_man_exp(yre, -wp), from_man_exp(yim, -wp) | |
if r and type == 3: | |
# If re(z) > 0 and abs(z) <= 4, the branches of loggamma(z) | |
# and log(gamma(z)) coincide. Otherwise, use the zeroth order | |
# Stirling expansion to compute the correct imaginary part. | |
y = mpc_sub(y, mpc_log(r, wp), wp) | |
zfa = to_float(zprered[0]) | |
zfb = to_float(zprered[1]) | |
zfabs = math.hypot(zfa,zfb) | |
#if not (zfa > 0.0 and zfabs <= 4): | |
yfb = to_float(y[1]) | |
u = math.atan2(zfb, zfa) | |
if zfabs <= 0.5: | |
gi = 0.577216*zfb - u | |
else: | |
gi = -zfb - 0.5*u + zfa*u + zfb*math.log(zfabs) | |
n = int(math.floor((gi-yfb)/(2*math.pi)+0.5)) | |
y = (y[0], mpf_add(y[1], mpf_mul_int(mpf_pi(wp), 2*n, wp), wp)) | |
if need_reflection: | |
if type == 0 or type == 2: | |
A = mpc_mul(mpc_sin_pi(zorig, wp), zorig, wp) | |
B = (mpf_neg(mpf_pi(wp)), fzero) | |
if yfinal: | |
if type == 2: | |
A = mpc_div(A, yfinal, wp) | |
else: | |
A = mpc_mul(A, yfinal, wp) | |
else: | |
A = mpc_mul(A, mpc_exp(y, wp), wp) | |
if r: | |
B = mpc_mul(B, r, wp) | |
if type == 0: return mpc_div(B, A, prec, rnd) | |
if type == 2: return mpc_div(A, B, prec, rnd) | |
# Reflection formula for the log-gamma function with correct branch | |
# http://functions.wolfram.com/GammaBetaErf/LogGamma/16/01/01/0006/ | |
# LogGamma[z] == -LogGamma[-z] - Log[-z] + | |
# Sign[Im[z]] Floor[Re[z]] Pi I + Log[Pi] - | |
# Log[Sin[Pi (z - Floor[Re[z]])]] - | |
# Pi I (1 - Abs[Sign[Im[z]]]) Abs[Floor[Re[z]]] | |
if type == 3: | |
if yfinal: | |
s1 = mpc_neg(yfinal) | |
else: | |
s1 = mpc_neg(y) | |
# s -= log(-z) | |
s1 = mpc_sub(s1, mpc_log(mpc_neg(zorig), wp), wp) | |
# floor(re(z)) | |
rezfloor = mpf_floor(zorig[0]) | |
imzsign = mpf_sign(zorig[1]) | |
pi = mpf_pi(wp) | |
t = mpf_mul(pi, rezfloor) | |
t = mpf_mul_int(t, imzsign, wp) | |
s1 = (s1[0], mpf_add(s1[1], t, wp)) | |
s1 = mpc_add_mpf(s1, mpf_log(pi, wp), wp) | |
t = mpc_sin_pi(mpc_sub_mpf(zorig, rezfloor), wp) | |
t = mpc_log(t, wp) | |
s1 = mpc_sub(s1, t, wp) | |
# Note: may actually be unused, because we fall back | |
# to the mpf_ function for real arguments | |
if not imzsign: | |
t = mpf_mul(pi, mpf_floor(rezfloor), wp) | |
s1 = (s1[0], mpf_sub(s1[1], t, wp)) | |
return mpc_pos(s1, prec, rnd) | |
else: | |
if type == 0: | |
if r: | |
return mpc_div(mpc_exp(y, wp), r, prec, rnd) | |
return mpc_exp(y, prec, rnd) | |
if type == 2: | |
if r: | |
return mpc_div(r, mpc_exp(y, wp), prec, rnd) | |
return mpc_exp(mpc_neg(y), prec, rnd) | |
if type == 3: | |
return mpc_pos(y, prec, rnd) | |
def mpf_factorial(x, prec, rnd='d'): | |
return mpf_gamma(x, prec, rnd, 1) | |
def mpc_factorial(x, prec, rnd='d'): | |
return mpc_gamma(x, prec, rnd, 1) | |
def mpf_rgamma(x, prec, rnd='d'): | |
return mpf_gamma(x, prec, rnd, 2) | |
def mpc_rgamma(x, prec, rnd='d'): | |
return mpc_gamma(x, prec, rnd, 2) | |
def mpf_loggamma(x, prec, rnd='d'): | |
sign, man, exp, bc = x | |
if sign: | |
raise ComplexResult | |
return mpf_gamma(x, prec, rnd, 3) | |
def mpc_loggamma(z, prec, rnd='d'): | |
a, b = z | |
asign, aman, aexp, abc = a | |
bsign, bman, bexp, bbc = b | |
if b == fzero and asign: | |
re = mpf_gamma(a, prec, rnd, 3) | |
n = (-aman) >> (-aexp) | |
im = mpf_mul_int(mpf_pi(prec+10), n, prec, rnd) | |
return re, im | |
return mpc_gamma(z, prec, rnd, 3) | |
def mpf_gamma_int(n, prec, rnd=round_fast): | |
if n < SMALL_FACTORIAL_CACHE_SIZE: | |
return mpf_pos(small_factorial_cache[n-1], prec, rnd) | |
return mpf_gamma(from_int(n), prec, rnd) | |