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from ..libmp.backend import xrange | |
from .functions import defun, defun_wrapped | |
def _check_need_perturb(ctx, terms, prec, discard_known_zeros): | |
perturb = recompute = False | |
extraprec = 0 | |
discard = [] | |
for term_index, term in enumerate(terms): | |
w_s, c_s, alpha_s, beta_s, a_s, b_s, z = term | |
have_singular_nongamma_weight = False | |
# Avoid division by zero in leading factors (TODO: | |
# also check for near division by zero?) | |
for k, w in enumerate(w_s): | |
if not w: | |
if ctx.re(c_s[k]) <= 0 and c_s[k]: | |
perturb = recompute = True | |
have_singular_nongamma_weight = True | |
pole_count = [0, 0, 0] | |
# Check for gamma and series poles and near-poles | |
for data_index, data in enumerate([alpha_s, beta_s, b_s]): | |
for i, x in enumerate(data): | |
n, d = ctx.nint_distance(x) | |
# Poles | |
if n > 0: | |
continue | |
if d == ctx.ninf: | |
# OK if we have a polynomial | |
# ------------------------------ | |
ok = False | |
if data_index == 2: | |
for u in a_s: | |
if ctx.isnpint(u) and u >= int(n): | |
ok = True | |
break | |
if ok: | |
continue | |
pole_count[data_index] += 1 | |
# ------------------------------ | |
#perturb = recompute = True | |
#return perturb, recompute, extraprec | |
elif d < -4: | |
extraprec += -d | |
recompute = True | |
if discard_known_zeros and pole_count[1] > pole_count[0] + pole_count[2] \ | |
and not have_singular_nongamma_weight: | |
discard.append(term_index) | |
elif sum(pole_count): | |
perturb = recompute = True | |
return perturb, recompute, extraprec, discard | |
_hypercomb_msg = """ | |
hypercomb() failed to converge to the requested %i bits of accuracy | |
using a working precision of %i bits. The function value may be zero or | |
infinite; try passing zeroprec=N or infprec=M to bound finite values between | |
2^(-N) and 2^M. Otherwise try a higher maxprec or maxterms. | |
""" | |
def hypercomb(ctx, function, params=[], discard_known_zeros=True, **kwargs): | |
orig = ctx.prec | |
sumvalue = ctx.zero | |
dist = ctx.nint_distance | |
ninf = ctx.ninf | |
orig_params = params[:] | |
verbose = kwargs.get('verbose', False) | |
maxprec = kwargs.get('maxprec', ctx._default_hyper_maxprec(orig)) | |
kwargs['maxprec'] = maxprec # For calls to hypsum | |
zeroprec = kwargs.get('zeroprec') | |
infprec = kwargs.get('infprec') | |
perturbed_reference_value = None | |
hextra = 0 | |
try: | |
while 1: | |
ctx.prec += 10 | |
if ctx.prec > maxprec: | |
raise ValueError(_hypercomb_msg % (orig, ctx.prec)) | |
orig2 = ctx.prec | |
params = orig_params[:] | |
terms = function(*params) | |
if verbose: | |
print() | |
print("ENTERING hypercomb main loop") | |
print("prec =", ctx.prec) | |
print("hextra", hextra) | |
perturb, recompute, extraprec, discard = \ | |
_check_need_perturb(ctx, terms, orig, discard_known_zeros) | |
ctx.prec += extraprec | |
if perturb: | |
if "hmag" in kwargs: | |
hmag = kwargs["hmag"] | |
elif ctx._fixed_precision: | |
hmag = int(ctx.prec*0.3) | |
else: | |
hmag = orig + 10 + hextra | |
h = ctx.ldexp(ctx.one, -hmag) | |
ctx.prec = orig2 + 10 + hmag + 10 | |
for k in range(len(params)): | |
params[k] += h | |
# Heuristically ensure that the perturbations | |
# are "independent" so that two perturbations | |
# don't accidentally cancel each other out | |
# in a subtraction. | |
h += h/(k+1) | |
if recompute: | |
terms = function(*params) | |
if discard_known_zeros: | |
terms = [term for (i, term) in enumerate(terms) if i not in discard] | |
if not terms: | |
return ctx.zero | |
evaluated_terms = [] | |
for term_index, term_data in enumerate(terms): | |
w_s, c_s, alpha_s, beta_s, a_s, b_s, z = term_data | |
if verbose: | |
print() | |
print(" Evaluating term %i/%i : %iF%i" % \ | |
(term_index+1, len(terms), len(a_s), len(b_s))) | |
print(" powers", ctx.nstr(w_s), ctx.nstr(c_s)) | |
print(" gamma", ctx.nstr(alpha_s), ctx.nstr(beta_s)) | |
print(" hyper", ctx.nstr(a_s), ctx.nstr(b_s)) | |
print(" z", ctx.nstr(z)) | |
#v = ctx.hyper(a_s, b_s, z, **kwargs) | |
#for a in alpha_s: v *= ctx.gamma(a) | |
#for b in beta_s: v *= ctx.rgamma(b) | |
#for w, c in zip(w_s, c_s): v *= ctx.power(w, c) | |
v = ctx.fprod([ctx.hyper(a_s, b_s, z, **kwargs)] + \ | |
[ctx.gamma(a) for a in alpha_s] + \ | |
[ctx.rgamma(b) for b in beta_s] + \ | |
[ctx.power(w,c) for (w,c) in zip(w_s,c_s)]) | |
if verbose: | |
print(" Value:", v) | |
evaluated_terms.append(v) | |
if len(terms) == 1 and (not perturb): | |
sumvalue = evaluated_terms[0] | |
break | |
if ctx._fixed_precision: | |
sumvalue = ctx.fsum(evaluated_terms) | |
break | |
sumvalue = ctx.fsum(evaluated_terms) | |
term_magnitudes = [ctx.mag(x) for x in evaluated_terms] | |
max_magnitude = max(term_magnitudes) | |
sum_magnitude = ctx.mag(sumvalue) | |
cancellation = max_magnitude - sum_magnitude | |
if verbose: | |
print() | |
print(" Cancellation:", cancellation, "bits") | |
print(" Increased precision:", ctx.prec - orig, "bits") | |
precision_ok = cancellation < ctx.prec - orig | |
if zeroprec is None: | |
zero_ok = False | |
else: | |
zero_ok = max_magnitude - ctx.prec < -zeroprec | |
if infprec is None: | |
inf_ok = False | |
else: | |
inf_ok = max_magnitude > infprec | |
if precision_ok and (not perturb) or ctx.isnan(cancellation): | |
break | |
elif precision_ok: | |
if perturbed_reference_value is None: | |
hextra += 20 | |
perturbed_reference_value = sumvalue | |
continue | |
elif ctx.mag(sumvalue - perturbed_reference_value) <= \ | |
ctx.mag(sumvalue) - orig: | |
break | |
elif zero_ok: | |
sumvalue = ctx.zero | |
break | |
elif inf_ok: | |
sumvalue = ctx.inf | |
break | |
elif 'hmag' in kwargs: | |
break | |
else: | |
hextra *= 2 | |
perturbed_reference_value = sumvalue | |
# Increase precision | |
else: | |
increment = min(max(cancellation, orig//2), max(extraprec,orig)) | |
ctx.prec += increment | |
if verbose: | |
print(" Must start over with increased precision") | |
continue | |
finally: | |
ctx.prec = orig | |
return +sumvalue | |
def hyper(ctx, a_s, b_s, z, **kwargs): | |
""" | |
Hypergeometric function, general case. | |
""" | |
z = ctx.convert(z) | |
p = len(a_s) | |
q = len(b_s) | |
a_s = [ctx._convert_param(a) for a in a_s] | |
b_s = [ctx._convert_param(b) for b in b_s] | |
# Reduce degree by eliminating common parameters | |
if kwargs.get('eliminate', True): | |
elim_nonpositive = kwargs.get('eliminate_all', False) | |
i = 0 | |
while i < q and a_s: | |
b = b_s[i] | |
if b in a_s and (elim_nonpositive or not ctx.isnpint(b[0])): | |
a_s.remove(b) | |
b_s.remove(b) | |
p -= 1 | |
q -= 1 | |
else: | |
i += 1 | |
# Handle special cases | |
if p == 0: | |
if q == 1: return ctx._hyp0f1(b_s, z, **kwargs) | |
elif q == 0: return ctx.exp(z) | |
elif p == 1: | |
if q == 1: return ctx._hyp1f1(a_s, b_s, z, **kwargs) | |
elif q == 2: return ctx._hyp1f2(a_s, b_s, z, **kwargs) | |
elif q == 0: return ctx._hyp1f0(a_s[0][0], z) | |
elif p == 2: | |
if q == 1: return ctx._hyp2f1(a_s, b_s, z, **kwargs) | |
elif q == 2: return ctx._hyp2f2(a_s, b_s, z, **kwargs) | |
elif q == 3: return ctx._hyp2f3(a_s, b_s, z, **kwargs) | |
elif q == 0: return ctx._hyp2f0(a_s, b_s, z, **kwargs) | |
elif p == q+1: | |
return ctx._hypq1fq(p, q, a_s, b_s, z, **kwargs) | |
elif p > q+1 and not kwargs.get('force_series'): | |
return ctx._hyp_borel(p, q, a_s, b_s, z, **kwargs) | |
coeffs, types = zip(*(a_s+b_s)) | |
return ctx.hypsum(p, q, types, coeffs, z, **kwargs) | |
def hyp0f1(ctx,b,z,**kwargs): | |
return ctx.hyper([],[b],z,**kwargs) | |
def hyp1f1(ctx,a,b,z,**kwargs): | |
return ctx.hyper([a],[b],z,**kwargs) | |
def hyp1f2(ctx,a1,b1,b2,z,**kwargs): | |
return ctx.hyper([a1],[b1,b2],z,**kwargs) | |
def hyp2f1(ctx,a,b,c,z,**kwargs): | |
return ctx.hyper([a,b],[c],z,**kwargs) | |
def hyp2f2(ctx,a1,a2,b1,b2,z,**kwargs): | |
return ctx.hyper([a1,a2],[b1,b2],z,**kwargs) | |
def hyp2f3(ctx,a1,a2,b1,b2,b3,z,**kwargs): | |
return ctx.hyper([a1,a2],[b1,b2,b3],z,**kwargs) | |
def hyp2f0(ctx,a,b,z,**kwargs): | |
return ctx.hyper([a,b],[],z,**kwargs) | |
def hyp3f2(ctx,a1,a2,a3,b1,b2,z,**kwargs): | |
return ctx.hyper([a1,a2,a3],[b1,b2],z,**kwargs) | |
def _hyp1f0(ctx, a, z): | |
return (1-z) ** (-a) | |
def _hyp0f1(ctx, b_s, z, **kwargs): | |
(b, btype), = b_s | |
if z: | |
magz = ctx.mag(z) | |
else: | |
magz = 0 | |
if magz >= 8 and not kwargs.get('force_series'): | |
try: | |
# http://functions.wolfram.com/HypergeometricFunctions/ | |
# Hypergeometric0F1/06/02/03/0004/ | |
# TODO: handle the all-real case more efficiently! | |
# TODO: figure out how much precision is needed (exponential growth) | |
orig = ctx.prec | |
try: | |
ctx.prec += 12 + magz//2 | |
def h(): | |
w = ctx.sqrt(-z) | |
jw = ctx.j*w | |
u = 1/(4*jw) | |
c = ctx.mpq_1_2 - b | |
E = ctx.exp(2*jw) | |
T1 = ([-jw,E], [c,-1], [], [], [b-ctx.mpq_1_2, ctx.mpq_3_2-b], [], -u) | |
T2 = ([jw,E], [c,1], [], [], [b-ctx.mpq_1_2, ctx.mpq_3_2-b], [], u) | |
return T1, T2 | |
v = ctx.hypercomb(h, [], force_series=True) | |
v = ctx.gamma(b)/(2*ctx.sqrt(ctx.pi))*v | |
finally: | |
ctx.prec = orig | |
if ctx._is_real_type(b) and ctx._is_real_type(z): | |
v = ctx._re(v) | |
return +v | |
except ctx.NoConvergence: | |
pass | |
return ctx.hypsum(0, 1, (btype,), [b], z, **kwargs) | |
def _hyp1f1(ctx, a_s, b_s, z, **kwargs): | |
(a, atype), = a_s | |
(b, btype), = b_s | |
if not z: | |
return ctx.one+z | |
magz = ctx.mag(z) | |
if magz >= 7 and not (ctx.isint(a) and ctx.re(a) <= 0): | |
if ctx.isinf(z): | |
if ctx.sign(a) == ctx.sign(b) == ctx.sign(z) == 1: | |
return ctx.inf | |
return ctx.nan * z | |
try: | |
try: | |
ctx.prec += magz | |
sector = ctx._im(z) < 0 | |
def h(a,b): | |
if sector: | |
E = ctx.expjpi(ctx.fneg(a, exact=True)) | |
else: | |
E = ctx.expjpi(a) | |
rz = 1/z | |
T1 = ([E,z], [1,-a], [b], [b-a], [a, 1+a-b], [], -rz) | |
T2 = ([ctx.exp(z),z], [1,a-b], [b], [a], [b-a, 1-a], [], rz) | |
return T1, T2 | |
v = ctx.hypercomb(h, [a,b], force_series=True) | |
if ctx._is_real_type(a) and ctx._is_real_type(b) and ctx._is_real_type(z): | |
v = ctx._re(v) | |
return +v | |
except ctx.NoConvergence: | |
pass | |
finally: | |
ctx.prec -= magz | |
v = ctx.hypsum(1, 1, (atype, btype), [a, b], z, **kwargs) | |
return v | |
def _hyp2f1_gosper(ctx,a,b,c,z,**kwargs): | |
# Use Gosper's recurrence | |
# See http://www.math.utexas.edu/pipermail/maxima/2006/000126.html | |
_a,_b,_c,_z = a, b, c, z | |
orig = ctx.prec | |
maxprec = kwargs.get('maxprec', 100*orig) | |
extra = 10 | |
while 1: | |
ctx.prec = orig + extra | |
#a = ctx.convert(_a) | |
#b = ctx.convert(_b) | |
#c = ctx.convert(_c) | |
z = ctx.convert(_z) | |
d = ctx.mpf(0) | |
e = ctx.mpf(1) | |
f = ctx.mpf(0) | |
k = 0 | |
# Common subexpression elimination, unfortunately making | |
# things a bit unreadable. The formula is quite messy to begin | |
# with, though... | |
abz = a*b*z | |
ch = c * ctx.mpq_1_2 | |
c1h = (c+1) * ctx.mpq_1_2 | |
nz = 1-z | |
g = z/nz | |
abg = a*b*g | |
cba = c-b-a | |
z2 = z-2 | |
tol = -ctx.prec - 10 | |
nstr = ctx.nstr | |
nprint = ctx.nprint | |
mag = ctx.mag | |
maxmag = ctx.ninf | |
while 1: | |
kch = k+ch | |
kakbz = (k+a)*(k+b)*z / (4*(k+1)*kch*(k+c1h)) | |
d1 = kakbz*(e-(k+cba)*d*g) | |
e1 = kakbz*(d*abg+(k+c)*e) | |
ft = d*(k*(cba*z+k*z2-c)-abz)/(2*kch*nz) | |
f1 = f + e - ft | |
maxmag = max(maxmag, mag(f1)) | |
if mag(f1-f) < tol: | |
break | |
d, e, f = d1, e1, f1 | |
k += 1 | |
cancellation = maxmag - mag(f1) | |
if cancellation < extra: | |
break | |
else: | |
extra += cancellation | |
if extra > maxprec: | |
raise ctx.NoConvergence | |
return f1 | |
def _hyp2f1(ctx, a_s, b_s, z, **kwargs): | |
(a, atype), (b, btype) = a_s | |
(c, ctype), = b_s | |
if z == 1: | |
# TODO: the following logic can be simplified | |
convergent = ctx.re(c-a-b) > 0 | |
finite = (ctx.isint(a) and a <= 0) or (ctx.isint(b) and b <= 0) | |
zerodiv = ctx.isint(c) and c <= 0 and not \ | |
((ctx.isint(a) and c <= a <= 0) or (ctx.isint(b) and c <= b <= 0)) | |
#print "bz", a, b, c, z, convergent, finite, zerodiv | |
# Gauss's theorem gives the value if convergent | |
if (convergent or finite) and not zerodiv: | |
return ctx.gammaprod([c, c-a-b], [c-a, c-b], _infsign=True) | |
# Otherwise, there is a pole and we take the | |
# sign to be that when approaching from below | |
# XXX: this evaluation is not necessarily correct in all cases | |
return ctx.hyp2f1(a,b,c,1-ctx.eps*2) * ctx.inf | |
# Equal to 1 (first term), unless there is a subsequent | |
# division by zero | |
if not z: | |
# Division by zero but power of z is higher than | |
# first order so cancels | |
if c or a == 0 or b == 0: | |
return 1+z | |
# Indeterminate | |
return ctx.nan | |
# Hit zero denominator unless numerator goes to 0 first | |
if ctx.isint(c) and c <= 0: | |
if (ctx.isint(a) and c <= a <= 0) or \ | |
(ctx.isint(b) and c <= b <= 0): | |
pass | |
else: | |
# Pole in series | |
return ctx.inf | |
absz = abs(z) | |
# Fast case: standard series converges rapidly, | |
# possibly in finitely many terms | |
if absz <= 0.8 or (ctx.isint(a) and a <= 0 and a >= -1000) or \ | |
(ctx.isint(b) and b <= 0 and b >= -1000): | |
return ctx.hypsum(2, 1, (atype, btype, ctype), [a, b, c], z, **kwargs) | |
orig = ctx.prec | |
try: | |
ctx.prec += 10 | |
# Use 1/z transformation | |
if absz >= 1.3: | |
def h(a,b): | |
t = ctx.mpq_1-c; ab = a-b; rz = 1/z | |
T1 = ([-z],[-a], [c,-ab],[b,c-a], [a,t+a],[ctx.mpq_1+ab], rz) | |
T2 = ([-z],[-b], [c,ab],[a,c-b], [b,t+b],[ctx.mpq_1-ab], rz) | |
return T1, T2 | |
v = ctx.hypercomb(h, [a,b], **kwargs) | |
# Use 1-z transformation | |
elif abs(1-z) <= 0.75: | |
def h(a,b): | |
t = c-a-b; ca = c-a; cb = c-b; rz = 1-z | |
T1 = [], [], [c,t], [ca,cb], [a,b], [1-t], rz | |
T2 = [rz], [t], [c,a+b-c], [a,b], [ca,cb], [1+t], rz | |
return T1, T2 | |
v = ctx.hypercomb(h, [a,b], **kwargs) | |
# Use z/(z-1) transformation | |
elif abs(z/(z-1)) <= 0.75: | |
v = ctx.hyp2f1(a, c-b, c, z/(z-1)) / (1-z)**a | |
# Remaining part of unit circle | |
else: | |
v = _hyp2f1_gosper(ctx,a,b,c,z,**kwargs) | |
finally: | |
ctx.prec = orig | |
return +v | |
def _hypq1fq(ctx, p, q, a_s, b_s, z, **kwargs): | |
r""" | |
Evaluates 3F2, 4F3, 5F4, ... | |
""" | |
a_s, a_types = zip(*a_s) | |
b_s, b_types = zip(*b_s) | |
a_s = list(a_s) | |
b_s = list(b_s) | |
absz = abs(z) | |
ispoly = False | |
for a in a_s: | |
if ctx.isint(a) and a <= 0: | |
ispoly = True | |
break | |
# Direct summation | |
if absz < 1 or ispoly: | |
try: | |
return ctx.hypsum(p, q, a_types+b_types, a_s+b_s, z, **kwargs) | |
except ctx.NoConvergence: | |
if absz > 1.1 or ispoly: | |
raise | |
# Use expansion at |z-1| -> 0. | |
# Reference: Wolfgang Buhring, "Generalized Hypergeometric Functions at | |
# Unit Argument", Proc. Amer. Math. Soc., Vol. 114, No. 1 (Jan. 1992), | |
# pp.145-153 | |
# The current implementation has several problems: | |
# 1. We only implement it for 3F2. The expansion coefficients are | |
# given by extremely messy nested sums in the higher degree cases | |
# (see reference). Is efficient sequential generation of the coefficients | |
# possible in the > 3F2 case? | |
# 2. Although the series converges, it may do so slowly, so we need | |
# convergence acceleration. The acceleration implemented by | |
# nsum does not always help, so results returned are sometimes | |
# inaccurate! Can we do better? | |
# 3. We should check conditions for convergence, and possibly | |
# do a better job of cancelling out gamma poles if possible. | |
if z == 1: | |
# XXX: should also check for division by zero in the | |
# denominator of the series (cf. hyp2f1) | |
S = ctx.re(sum(b_s)-sum(a_s)) | |
if S <= 0: | |
#return ctx.hyper(a_s, b_s, 1-ctx.eps*2, **kwargs) * ctx.inf | |
return ctx.hyper(a_s, b_s, 0.9, **kwargs) * ctx.inf | |
if (p,q) == (3,2) and abs(z-1) < 0.05: # and kwargs.get('sum1') | |
#print "Using alternate summation (experimental)" | |
a1,a2,a3 = a_s | |
b1,b2 = b_s | |
u = b1+b2-a3 | |
initial = ctx.gammaprod([b2-a3,b1-a3,a1,a2],[b2-a3,b1-a3,1,u]) | |
def term(k, _cache={0:initial}): | |
u = b1+b2-a3+k | |
if k in _cache: | |
t = _cache[k] | |
else: | |
t = _cache[k-1] | |
t *= (b1+k-a3-1)*(b2+k-a3-1) | |
t /= k*(u-1) | |
_cache[k] = t | |
return t * ctx.hyp2f1(a1,a2,u,z) | |
try: | |
S = ctx.nsum(term, [0,ctx.inf], verbose=kwargs.get('verbose'), | |
strict=kwargs.get('strict', True)) | |
return S * ctx.gammaprod([b1,b2],[a1,a2,a3]) | |
except ctx.NoConvergence: | |
pass | |
# Try to use convergence acceleration on and close to the unit circle. | |
# Problem: the convergence acceleration degenerates as |z-1| -> 0, | |
# except for special cases. Everywhere else, the Shanks transformation | |
# is very efficient. | |
if absz < 1.1 and ctx._re(z) <= 1: | |
def term(kk, _cache={0:ctx.one}): | |
k = int(kk) | |
if k != kk: | |
t = z ** ctx.mpf(kk) / ctx.fac(kk) | |
for a in a_s: t *= ctx.rf(a,kk) | |
for b in b_s: t /= ctx.rf(b,kk) | |
return t | |
if k in _cache: | |
return _cache[k] | |
t = term(k-1) | |
m = k-1 | |
for j in xrange(p): t *= (a_s[j]+m) | |
for j in xrange(q): t /= (b_s[j]+m) | |
t *= z | |
t /= k | |
_cache[k] = t | |
return t | |
sum_method = kwargs.get('sum_method', 'r+s+e') | |
try: | |
return ctx.nsum(term, [0,ctx.inf], verbose=kwargs.get('verbose'), | |
strict=kwargs.get('strict', True), | |
method=sum_method.replace('e','')) | |
except ctx.NoConvergence: | |
if 'e' not in sum_method: | |
raise | |
pass | |
if kwargs.get('verbose'): | |
print("Attempting Euler-Maclaurin summation") | |
""" | |
Somewhat slower version (one diffs_exp for each factor). | |
However, this would be faster with fast direct derivatives | |
of the gamma function. | |
def power_diffs(k0): | |
r = 0 | |
l = ctx.log(z) | |
while 1: | |
yield z**ctx.mpf(k0) * l**r | |
r += 1 | |
def loggamma_diffs(x, reciprocal=False): | |
sign = (-1) ** reciprocal | |
yield sign * ctx.loggamma(x) | |
i = 0 | |
while 1: | |
yield sign * ctx.psi(i,x) | |
i += 1 | |
def hyper_diffs(k0): | |
b2 = b_s + [1] | |
A = [ctx.diffs_exp(loggamma_diffs(a+k0)) for a in a_s] | |
B = [ctx.diffs_exp(loggamma_diffs(b+k0,True)) for b in b2] | |
Z = [power_diffs(k0)] | |
C = ctx.gammaprod([b for b in b2], [a for a in a_s]) | |
for d in ctx.diffs_prod(A + B + Z): | |
v = C * d | |
yield v | |
""" | |
def log_diffs(k0): | |
b2 = b_s + [1] | |
yield sum(ctx.loggamma(a+k0) for a in a_s) - \ | |
sum(ctx.loggamma(b+k0) for b in b2) + k0*ctx.log(z) | |
i = 0 | |
while 1: | |
v = sum(ctx.psi(i,a+k0) for a in a_s) - \ | |
sum(ctx.psi(i,b+k0) for b in b2) | |
if i == 0: | |
v += ctx.log(z) | |
yield v | |
i += 1 | |
def hyper_diffs(k0): | |
C = ctx.gammaprod([b for b in b_s], [a for a in a_s]) | |
for d in ctx.diffs_exp(log_diffs(k0)): | |
v = C * d | |
yield v | |
tol = ctx.eps / 1024 | |
prec = ctx.prec | |
try: | |
trunc = 50 * ctx.dps | |
ctx.prec += 20 | |
for i in xrange(5): | |
head = ctx.fsum(term(k) for k in xrange(trunc)) | |
tail, err = ctx.sumem(term, [trunc, ctx.inf], tol=tol, | |
adiffs=hyper_diffs(trunc), | |
verbose=kwargs.get('verbose'), | |
error=True, | |
_fast_abort=True) | |
if err < tol: | |
v = head + tail | |
break | |
trunc *= 2 | |
# Need to increase precision because calculation of | |
# derivatives may be inaccurate | |
ctx.prec += ctx.prec//2 | |
if i == 4: | |
raise ctx.NoConvergence(\ | |
"Euler-Maclaurin summation did not converge") | |
finally: | |
ctx.prec = prec | |
return +v | |
# Use 1/z transformation | |
# http://functions.wolfram.com/HypergeometricFunctions/ | |
# HypergeometricPFQ/06/01/05/02/0004/ | |
def h(*args): | |
a_s = list(args[:p]) | |
b_s = list(args[p:]) | |
Ts = [] | |
recz = ctx.one/z | |
negz = ctx.fneg(z, exact=True) | |
for k in range(q+1): | |
ak = a_s[k] | |
C = [negz] | |
Cp = [-ak] | |
Gn = b_s + [ak] + [a_s[j]-ak for j in range(q+1) if j != k] | |
Gd = a_s + [b_s[j]-ak for j in range(q)] | |
Fn = [ak] + [ak-b_s[j]+1 for j in range(q)] | |
Fd = [1-a_s[j]+ak for j in range(q+1) if j != k] | |
Ts.append((C, Cp, Gn, Gd, Fn, Fd, recz)) | |
return Ts | |
return ctx.hypercomb(h, a_s+b_s, **kwargs) | |
def _hyp_borel(ctx, p, q, a_s, b_s, z, **kwargs): | |
if a_s: | |
a_s, a_types = zip(*a_s) | |
a_s = list(a_s) | |
else: | |
a_s, a_types = [], () | |
if b_s: | |
b_s, b_types = zip(*b_s) | |
b_s = list(b_s) | |
else: | |
b_s, b_types = [], () | |
kwargs['maxterms'] = kwargs.get('maxterms', ctx.prec) | |
try: | |
return ctx.hypsum(p, q, a_types+b_types, a_s+b_s, z, **kwargs) | |
except ctx.NoConvergence: | |
pass | |
prec = ctx.prec | |
try: | |
tol = kwargs.get('asymp_tol', ctx.eps/4) | |
ctx.prec += 10 | |
# hypsum is has a conservative tolerance. So we try again: | |
def term(k, cache={0:ctx.one}): | |
if k in cache: | |
return cache[k] | |
t = term(k-1) | |
for a in a_s: t *= (a+(k-1)) | |
for b in b_s: t /= (b+(k-1)) | |
t *= z | |
t /= k | |
cache[k] = t | |
return t | |
s = ctx.one | |
for k in xrange(1, ctx.prec): | |
t = term(k) | |
s += t | |
if abs(t) <= tol: | |
return s | |
finally: | |
ctx.prec = prec | |
if p <= q+3: | |
contour = kwargs.get('contour') | |
if not contour: | |
if ctx.arg(z) < 0.25: | |
u = z / max(1, abs(z)) | |
if ctx.arg(z) >= 0: | |
contour = [0, 2j, (2j+2)/u, 2/u, ctx.inf] | |
else: | |
contour = [0, -2j, (-2j+2)/u, 2/u, ctx.inf] | |
#contour = [0, 2j/z, 2/z, ctx.inf] | |
#contour = [0, 2j, 2/z, ctx.inf] | |
#contour = [0, 2j, ctx.inf] | |
else: | |
contour = [0, ctx.inf] | |
quad_kwargs = kwargs.get('quad_kwargs', {}) | |
def g(t): | |
return ctx.exp(-t)*ctx.hyper(a_s, b_s+[1], t*z) | |
I, err = ctx.quad(g, contour, error=True, **quad_kwargs) | |
if err <= abs(I)*ctx.eps*8: | |
return I | |
raise ctx.NoConvergence | |
def _hyp2f2(ctx, a_s, b_s, z, **kwargs): | |
(a1, a1type), (a2, a2type) = a_s | |
(b1, b1type), (b2, b2type) = b_s | |
absz = abs(z) | |
magz = ctx.mag(z) | |
orig = ctx.prec | |
# Asymptotic expansion is ~ exp(z) | |
asymp_extraprec = magz | |
# Asymptotic series is in terms of 3F1 | |
can_use_asymptotic = (not kwargs.get('force_series')) and \ | |
(ctx.mag(absz) > 3) | |
# TODO: much of the following could be shared with 2F3 instead of | |
# copypasted | |
if can_use_asymptotic: | |
#print "using asymp" | |
try: | |
try: | |
ctx.prec += asymp_extraprec | |
# http://functions.wolfram.com/HypergeometricFunctions/ | |
# Hypergeometric2F2/06/02/02/0002/ | |
def h(a1,a2,b1,b2): | |
X = a1+a2-b1-b2 | |
A2 = a1+a2 | |
B2 = b1+b2 | |
c = {} | |
c[0] = ctx.one | |
c[1] = (A2-1)*X+b1*b2-a1*a2 | |
s1 = 0 | |
k = 0 | |
tprev = 0 | |
while 1: | |
if k not in c: | |
uu1 = 1-B2+2*a1+a1**2+2*a2+a2**2-A2*B2+a1*a2+b1*b2+(2*B2-3*(A2+1))*k+2*k**2 | |
uu2 = (k-A2+b1-1)*(k-A2+b2-1)*(k-X-2) | |
c[k] = ctx.one/k * (uu1*c[k-1]-uu2*c[k-2]) | |
t1 = c[k] * z**(-k) | |
if abs(t1) < 0.1*ctx.eps: | |
#print "Convergence :)" | |
break | |
# Quit if the series doesn't converge quickly enough | |
if k > 5 and abs(tprev) / abs(t1) < 1.5: | |
#print "No convergence :(" | |
raise ctx.NoConvergence | |
s1 += t1 | |
tprev = t1 | |
k += 1 | |
S = ctx.exp(z)*s1 | |
T1 = [z,S], [X,1], [b1,b2],[a1,a2],[],[],0 | |
T2 = [-z],[-a1],[b1,b2,a2-a1],[a2,b1-a1,b2-a1],[a1,a1-b1+1,a1-b2+1],[a1-a2+1],-1/z | |
T3 = [-z],[-a2],[b1,b2,a1-a2],[a1,b1-a2,b2-a2],[a2,a2-b1+1,a2-b2+1],[-a1+a2+1],-1/z | |
return T1, T2, T3 | |
v = ctx.hypercomb(h, [a1,a2,b1,b2], force_series=True, maxterms=4*ctx.prec) | |
if sum(ctx._is_real_type(u) for u in [a1,a2,b1,b2,z]) == 5: | |
v = ctx.re(v) | |
return v | |
except ctx.NoConvergence: | |
pass | |
finally: | |
ctx.prec = orig | |
return ctx.hypsum(2, 2, (a1type, a2type, b1type, b2type), [a1, a2, b1, b2], z, **kwargs) | |
def _hyp1f2(ctx, a_s, b_s, z, **kwargs): | |
(a1, a1type), = a_s | |
(b1, b1type), (b2, b2type) = b_s | |
absz = abs(z) | |
magz = ctx.mag(z) | |
orig = ctx.prec | |
# Asymptotic expansion is ~ exp(sqrt(z)) | |
asymp_extraprec = z and magz//2 | |
# Asymptotic series is in terms of 3F0 | |
can_use_asymptotic = (not kwargs.get('force_series')) and \ | |
(ctx.mag(absz) > 19) and \ | |
(ctx.sqrt(absz) > 1.5*orig) # and \ | |
# ctx._hyp_check_convergence([a1, a1-b1+1, a1-b2+1], [], | |
# 1/absz, orig+40+asymp_extraprec) | |
# TODO: much of the following could be shared with 2F3 instead of | |
# copypasted | |
if can_use_asymptotic: | |
#print "using asymp" | |
try: | |
try: | |
ctx.prec += asymp_extraprec | |
# http://functions.wolfram.com/HypergeometricFunctions/ | |
# Hypergeometric1F2/06/02/03/ | |
def h(a1,b1,b2): | |
X = ctx.mpq_1_2*(a1-b1-b2+ctx.mpq_1_2) | |
c = {} | |
c[0] = ctx.one | |
c[1] = 2*(ctx.mpq_1_4*(3*a1+b1+b2-2)*(a1-b1-b2)+b1*b2-ctx.mpq_3_16) | |
c[2] = 2*(b1*b2+ctx.mpq_1_4*(a1-b1-b2)*(3*a1+b1+b2-2)-ctx.mpq_3_16)**2+\ | |
ctx.mpq_1_16*(-16*(2*a1-3)*b1*b2 + \ | |
4*(a1-b1-b2)*(-8*a1**2+11*a1+b1+b2-2)-3) | |
s1 = 0 | |
s2 = 0 | |
k = 0 | |
tprev = 0 | |
while 1: | |
if k not in c: | |
uu1 = (3*k**2+(-6*a1+2*b1+2*b2-4)*k + 3*a1**2 - \ | |
(b1-b2)**2 - 2*a1*(b1+b2-2) + ctx.mpq_1_4) | |
uu2 = (k-a1+b1-b2-ctx.mpq_1_2)*(k-a1-b1+b2-ctx.mpq_1_2)*\ | |
(k-a1+b1+b2-ctx.mpq_5_2) | |
c[k] = ctx.one/(2*k)*(uu1*c[k-1]-uu2*c[k-2]) | |
w = c[k] * (-z)**(-0.5*k) | |
t1 = (-ctx.j)**k * ctx.mpf(2)**(-k) * w | |
t2 = ctx.j**k * ctx.mpf(2)**(-k) * w | |
if abs(t1) < 0.1*ctx.eps: | |
#print "Convergence :)" | |
break | |
# Quit if the series doesn't converge quickly enough | |
if k > 5 and abs(tprev) / abs(t1) < 1.5: | |
#print "No convergence :(" | |
raise ctx.NoConvergence | |
s1 += t1 | |
s2 += t2 | |
tprev = t1 | |
k += 1 | |
S = ctx.expj(ctx.pi*X+2*ctx.sqrt(-z))*s1 + \ | |
ctx.expj(-(ctx.pi*X+2*ctx.sqrt(-z)))*s2 | |
T1 = [0.5*S, ctx.pi, -z], [1, -0.5, X], [b1, b2], [a1],\ | |
[], [], 0 | |
T2 = [-z], [-a1], [b1,b2],[b1-a1,b2-a1], \ | |
[a1,a1-b1+1,a1-b2+1], [], 1/z | |
return T1, T2 | |
v = ctx.hypercomb(h, [a1,b1,b2], force_series=True, maxterms=4*ctx.prec) | |
if sum(ctx._is_real_type(u) for u in [a1,b1,b2,z]) == 4: | |
v = ctx.re(v) | |
return v | |
except ctx.NoConvergence: | |
pass | |
finally: | |
ctx.prec = orig | |
#print "not using asymp" | |
return ctx.hypsum(1, 2, (a1type, b1type, b2type), [a1, b1, b2], z, **kwargs) | |
def _hyp2f3(ctx, a_s, b_s, z, **kwargs): | |
(a1, a1type), (a2, a2type) = a_s | |
(b1, b1type), (b2, b2type), (b3, b3type) = b_s | |
absz = abs(z) | |
magz = ctx.mag(z) | |
# Asymptotic expansion is ~ exp(sqrt(z)) | |
asymp_extraprec = z and magz//2 | |
orig = ctx.prec | |
# Asymptotic series is in terms of 4F1 | |
# The square root below empirically provides a plausible criterion | |
# for the leading series to converge | |
can_use_asymptotic = (not kwargs.get('force_series')) and \ | |
(ctx.mag(absz) > 19) and (ctx.sqrt(absz) > 1.5*orig) | |
if can_use_asymptotic: | |
#print "using asymp" | |
try: | |
try: | |
ctx.prec += asymp_extraprec | |
# http://functions.wolfram.com/HypergeometricFunctions/ | |
# Hypergeometric2F3/06/02/03/01/0002/ | |
def h(a1,a2,b1,b2,b3): | |
X = ctx.mpq_1_2*(a1+a2-b1-b2-b3+ctx.mpq_1_2) | |
A2 = a1+a2 | |
B3 = b1+b2+b3 | |
A = a1*a2 | |
B = b1*b2+b3*b2+b1*b3 | |
R = b1*b2*b3 | |
c = {} | |
c[0] = ctx.one | |
c[1] = 2*(B - A + ctx.mpq_1_4*(3*A2+B3-2)*(A2-B3) - ctx.mpq_3_16) | |
c[2] = ctx.mpq_1_2*c[1]**2 + ctx.mpq_1_16*(-16*(2*A2-3)*(B-A) + 32*R +\ | |
4*(-8*A2**2 + 11*A2 + 8*A + B3 - 2)*(A2-B3)-3) | |
s1 = 0 | |
s2 = 0 | |
k = 0 | |
tprev = 0 | |
while 1: | |
if k not in c: | |
uu1 = (k-2*X-3)*(k-2*X-2*b1-1)*(k-2*X-2*b2-1)*\ | |
(k-2*X-2*b3-1) | |
uu2 = (4*(k-1)**3 - 6*(4*X+B3)*(k-1)**2 + \ | |
2*(24*X**2+12*B3*X+4*B+B3-1)*(k-1) - 32*X**3 - \ | |
24*B3*X**2 - 4*B - 8*R - 4*(4*B+B3-1)*X + 2*B3-1) | |
uu3 = (5*(k-1)**2+2*(-10*X+A2-3*B3+3)*(k-1)+2*c[1]) | |
c[k] = ctx.one/(2*k)*(uu1*c[k-3]-uu2*c[k-2]+uu3*c[k-1]) | |
w = c[k] * ctx.power(-z, -0.5*k) | |
t1 = (-ctx.j)**k * ctx.mpf(2)**(-k) * w | |
t2 = ctx.j**k * ctx.mpf(2)**(-k) * w | |
if abs(t1) < 0.1*ctx.eps: | |
break | |
# Quit if the series doesn't converge quickly enough | |
if k > 5 and abs(tprev) / abs(t1) < 1.5: | |
raise ctx.NoConvergence | |
s1 += t1 | |
s2 += t2 | |
tprev = t1 | |
k += 1 | |
S = ctx.expj(ctx.pi*X+2*ctx.sqrt(-z))*s1 + \ | |
ctx.expj(-(ctx.pi*X+2*ctx.sqrt(-z)))*s2 | |
T1 = [0.5*S, ctx.pi, -z], [1, -0.5, X], [b1, b2, b3], [a1, a2],\ | |
[], [], 0 | |
T2 = [-z], [-a1], [b1,b2,b3,a2-a1],[a2,b1-a1,b2-a1,b3-a1], \ | |
[a1,a1-b1+1,a1-b2+1,a1-b3+1], [a1-a2+1], 1/z | |
T3 = [-z], [-a2], [b1,b2,b3,a1-a2],[a1,b1-a2,b2-a2,b3-a2], \ | |
[a2,a2-b1+1,a2-b2+1,a2-b3+1],[-a1+a2+1], 1/z | |
return T1, T2, T3 | |
v = ctx.hypercomb(h, [a1,a2,b1,b2,b3], force_series=True, maxterms=4*ctx.prec) | |
if sum(ctx._is_real_type(u) for u in [a1,a2,b1,b2,b3,z]) == 6: | |
v = ctx.re(v) | |
return v | |
except ctx.NoConvergence: | |
pass | |
finally: | |
ctx.prec = orig | |
return ctx.hypsum(2, 3, (a1type, a2type, b1type, b2type, b3type), [a1, a2, b1, b2, b3], z, **kwargs) | |
def _hyp2f0(ctx, a_s, b_s, z, **kwargs): | |
(a, atype), (b, btype) = a_s | |
# We want to try aggressively to use the asymptotic expansion, | |
# and fall back only when absolutely necessary | |
try: | |
kwargsb = kwargs.copy() | |
kwargsb['maxterms'] = kwargsb.get('maxterms', ctx.prec) | |
return ctx.hypsum(2, 0, (atype,btype), [a,b], z, **kwargsb) | |
except ctx.NoConvergence: | |
if kwargs.get('force_series'): | |
raise | |
pass | |
def h(a, b): | |
w = ctx.sinpi(b) | |
rz = -1/z | |
T1 = ([ctx.pi,w,rz],[1,-1,a],[],[a-b+1,b],[a],[b],rz) | |
T2 = ([-ctx.pi,w,rz],[1,-1,1+a-b],[],[a,2-b],[a-b+1],[2-b],rz) | |
return T1, T2 | |
return ctx.hypercomb(h, [a, 1+a-b], **kwargs) | |
def meijerg(ctx, a_s, b_s, z, r=1, series=None, **kwargs): | |
an, ap = a_s | |
bm, bq = b_s | |
n = len(an) | |
p = n + len(ap) | |
m = len(bm) | |
q = m + len(bq) | |
a = an+ap | |
b = bm+bq | |
a = [ctx.convert(_) for _ in a] | |
b = [ctx.convert(_) for _ in b] | |
z = ctx.convert(z) | |
if series is None: | |
if p < q: series = 1 | |
if p > q: series = 2 | |
if p == q: | |
if m+n == p and abs(z) > 1: | |
series = 2 | |
else: | |
series = 1 | |
if kwargs.get('verbose'): | |
print("Meijer G m,n,p,q,series =", m,n,p,q,series) | |
if series == 1: | |
def h(*args): | |
a = args[:p] | |
b = args[p:] | |
terms = [] | |
for k in range(m): | |
bases = [z] | |
expts = [b[k]/r] | |
gn = [b[j]-b[k] for j in range(m) if j != k] | |
gn += [1-a[j]+b[k] for j in range(n)] | |
gd = [a[j]-b[k] for j in range(n,p)] | |
gd += [1-b[j]+b[k] for j in range(m,q)] | |
hn = [1-a[j]+b[k] for j in range(p)] | |
hd = [1-b[j]+b[k] for j in range(q) if j != k] | |
hz = (-ctx.one)**(p-m-n) * z**(ctx.one/r) | |
terms.append((bases, expts, gn, gd, hn, hd, hz)) | |
return terms | |
else: | |
def h(*args): | |
a = args[:p] | |
b = args[p:] | |
terms = [] | |
for k in range(n): | |
bases = [z] | |
if r == 1: | |
expts = [a[k]-1] | |
else: | |
expts = [(a[k]-1)/ctx.convert(r)] | |
gn = [a[k]-a[j] for j in range(n) if j != k] | |
gn += [1-a[k]+b[j] for j in range(m)] | |
gd = [a[k]-b[j] for j in range(m,q)] | |
gd += [1-a[k]+a[j] for j in range(n,p)] | |
hn = [1-a[k]+b[j] for j in range(q)] | |
hd = [1+a[j]-a[k] for j in range(p) if j != k] | |
hz = (-ctx.one)**(q-m-n) / z**(ctx.one/r) | |
terms.append((bases, expts, gn, gd, hn, hd, hz)) | |
return terms | |
return ctx.hypercomb(h, a+b, **kwargs) | |
def appellf1(ctx,a,b1,b2,c,x,y,**kwargs): | |
# Assume x smaller | |
# We will use x for the outer loop | |
if abs(x) > abs(y): | |
x, y = y, x | |
b1, b2 = b2, b1 | |
def ok(x): | |
return abs(x) < 0.99 | |
# Finite cases | |
if ctx.isnpint(a): | |
pass | |
elif ctx.isnpint(b1): | |
pass | |
elif ctx.isnpint(b2): | |
x, y, b1, b2 = y, x, b2, b1 | |
else: | |
#print x, y | |
# Note: ok if |y| > 1, because | |
# 2F1 implements analytic continuation | |
if not ok(x): | |
u1 = (x-y)/(x-1) | |
if not ok(u1): | |
raise ValueError("Analytic continuation not implemented") | |
#print "Using analytic continuation" | |
return (1-x)**(-b1)*(1-y)**(c-a-b2)*\ | |
ctx.appellf1(c-a,b1,c-b1-b2,c,u1,y,**kwargs) | |
return ctx.hyper2d({'m+n':[a],'m':[b1],'n':[b2]}, {'m+n':[c]}, x,y, **kwargs) | |
def appellf2(ctx,a,b1,b2,c1,c2,x,y,**kwargs): | |
# TODO: continuation | |
return ctx.hyper2d({'m+n':[a],'m':[b1],'n':[b2]}, | |
{'m':[c1],'n':[c2]}, x,y, **kwargs) | |
def appellf3(ctx,a1,a2,b1,b2,c,x,y,**kwargs): | |
outer_polynomial = ctx.isnpint(a1) or ctx.isnpint(b1) | |
inner_polynomial = ctx.isnpint(a2) or ctx.isnpint(b2) | |
if not outer_polynomial: | |
if inner_polynomial or abs(x) > abs(y): | |
x, y = y, x | |
a1,a2,b1,b2 = a2,a1,b2,b1 | |
return ctx.hyper2d({'m':[a1,b1],'n':[a2,b2]}, {'m+n':[c]},x,y,**kwargs) | |
def appellf4(ctx,a,b,c1,c2,x,y,**kwargs): | |
# TODO: continuation | |
return ctx.hyper2d({'m+n':[a,b]}, {'m':[c1],'n':[c2]},x,y,**kwargs) | |
def hyper2d(ctx, a, b, x, y, **kwargs): | |
r""" | |
Sums the generalized 2D hypergeometric series | |
.. math :: | |
\sum_{m=0}^{\infty} \sum_{n=0}^{\infty} | |
\frac{P((a),m,n)}{Q((b),m,n)} | |
\frac{x^m y^n} {m! n!} | |
where `(a) = (a_1,\ldots,a_r)`, `(b) = (b_1,\ldots,b_s)` and where | |
`P` and `Q` are products of rising factorials such as `(a_j)_n` or | |
`(a_j)_{m+n}`. `P` and `Q` are specified in the form of dicts, with | |
the `m` and `n` dependence as keys and parameter lists as values. | |
The supported rising factorials are given in the following table | |
(note that only a few are supported in `Q`): | |
+------------+-------------------+--------+ | |
| Key | Rising factorial | `Q` | | |
+============+===================+========+ | |
| ``'m'`` | `(a_j)_m` | Yes | | |
+------------+-------------------+--------+ | |
| ``'n'`` | `(a_j)_n` | Yes | | |
+------------+-------------------+--------+ | |
| ``'m+n'`` | `(a_j)_{m+n}` | Yes | | |
+------------+-------------------+--------+ | |
| ``'m-n'`` | `(a_j)_{m-n}` | No | | |
+------------+-------------------+--------+ | |
| ``'n-m'`` | `(a_j)_{n-m}` | No | | |
+------------+-------------------+--------+ | |
| ``'2m+n'`` | `(a_j)_{2m+n}` | No | | |
+------------+-------------------+--------+ | |
| ``'2m-n'`` | `(a_j)_{2m-n}` | No | | |
+------------+-------------------+--------+ | |
| ``'2n-m'`` | `(a_j)_{2n-m}` | No | | |
+------------+-------------------+--------+ | |
For example, the Appell F1 and F4 functions | |
.. math :: | |
F_1 = \sum_{m=0}^{\infty} \sum_{n=0}^{\infty} | |
\frac{(a)_{m+n} (b)_m (c)_n}{(d)_{m+n}} | |
\frac{x^m y^n}{m! n!} | |
F_4 = \sum_{m=0}^{\infty} \sum_{n=0}^{\infty} | |
\frac{(a)_{m+n} (b)_{m+n}}{(c)_m (d)_{n}} | |
\frac{x^m y^n}{m! n!} | |
can be represented respectively as | |
``hyper2d({'m+n':[a], 'm':[b], 'n':[c]}, {'m+n':[d]}, x, y)`` | |
``hyper2d({'m+n':[a,b]}, {'m':[c], 'n':[d]}, x, y)`` | |
More generally, :func:`~mpmath.hyper2d` can evaluate any of the 34 distinct | |
convergent second-order (generalized Gaussian) hypergeometric | |
series enumerated by Horn, as well as the Kampe de Feriet | |
function. | |
The series is computed by rewriting it so that the inner | |
series (i.e. the series containing `n` and `y`) has the form of an | |
ordinary generalized hypergeometric series and thereby can be | |
evaluated efficiently using :func:`~mpmath.hyper`. If possible, | |
manually swapping `x` and `y` and the corresponding parameters | |
can sometimes give better results. | |
**Examples** | |
Two separable cases: a product of two geometric series, and a | |
product of two Gaussian hypergeometric functions:: | |
>>> from mpmath import * | |
>>> mp.dps = 25; mp.pretty = True | |
>>> x, y = mpf(0.25), mpf(0.5) | |
>>> hyper2d({'m':1,'n':1}, {}, x,y) | |
2.666666666666666666666667 | |
>>> 1/(1-x)/(1-y) | |
2.666666666666666666666667 | |
>>> hyper2d({'m':[1,2],'n':[3,4]}, {'m':[5],'n':[6]}, x,y) | |
4.164358531238938319669856 | |
>>> hyp2f1(1,2,5,x)*hyp2f1(3,4,6,y) | |
4.164358531238938319669856 | |
Some more series that can be done in closed form:: | |
>>> hyper2d({'m':1,'n':1},{'m+n':1},x,y) | |
2.013417124712514809623881 | |
>>> (exp(x)*x-exp(y)*y)/(x-y) | |
2.013417124712514809623881 | |
Six of the 34 Horn functions, G1-G3 and H1-H3:: | |
>>> from mpmath import * | |
>>> mp.dps = 10; mp.pretty = True | |
>>> x, y = 0.0625, 0.125 | |
>>> a1,a2,b1,b2,c1,c2,d = 1.1,-1.2,-1.3,-1.4,1.5,-1.6,1.7 | |
>>> hyper2d({'m+n':a1,'n-m':b1,'m-n':b2},{},x,y) # G1 | |
1.139090746 | |
>>> nsum(lambda m,n: rf(a1,m+n)*rf(b1,n-m)*rf(b2,m-n)*\ | |
... x**m*y**n/fac(m)/fac(n), [0,inf], [0,inf]) | |
1.139090746 | |
>>> hyper2d({'m':a1,'n':a2,'n-m':b1,'m-n':b2},{},x,y) # G2 | |
0.9503682696 | |
>>> nsum(lambda m,n: rf(a1,m)*rf(a2,n)*rf(b1,n-m)*rf(b2,m-n)*\ | |
... x**m*y**n/fac(m)/fac(n), [0,inf], [0,inf]) | |
0.9503682696 | |
>>> hyper2d({'2n-m':a1,'2m-n':a2},{},x,y) # G3 | |
1.029372029 | |
>>> nsum(lambda m,n: rf(a1,2*n-m)*rf(a2,2*m-n)*\ | |
... x**m*y**n/fac(m)/fac(n), [0,inf], [0,inf]) | |
1.029372029 | |
>>> hyper2d({'m-n':a1,'m+n':b1,'n':c1},{'m':d},x,y) # H1 | |
-1.605331256 | |
>>> nsum(lambda m,n: rf(a1,m-n)*rf(b1,m+n)*rf(c1,n)/rf(d,m)*\ | |
... x**m*y**n/fac(m)/fac(n), [0,inf], [0,inf]) | |
-1.605331256 | |
>>> hyper2d({'m-n':a1,'m':b1,'n':[c1,c2]},{'m':d},x,y) # H2 | |
-2.35405404 | |
>>> nsum(lambda m,n: rf(a1,m-n)*rf(b1,m)*rf(c1,n)*rf(c2,n)/rf(d,m)*\ | |
... x**m*y**n/fac(m)/fac(n), [0,inf], [0,inf]) | |
-2.35405404 | |
>>> hyper2d({'2m+n':a1,'n':b1},{'m+n':c1},x,y) # H3 | |
0.974479074 | |
>>> nsum(lambda m,n: rf(a1,2*m+n)*rf(b1,n)/rf(c1,m+n)*\ | |
... x**m*y**n/fac(m)/fac(n), [0,inf], [0,inf]) | |
0.974479074 | |
**References** | |
1. [SrivastavaKarlsson]_ | |
2. [Weisstein]_ http://mathworld.wolfram.com/HornFunction.html | |
3. [Weisstein]_ http://mathworld.wolfram.com/AppellHypergeometricFunction.html | |
""" | |
x = ctx.convert(x) | |
y = ctx.convert(y) | |
def parse(dct, key): | |
args = dct.pop(key, []) | |
try: | |
args = list(args) | |
except TypeError: | |
args = [args] | |
return [ctx.convert(arg) for arg in args] | |
a_s = dict(a) | |
b_s = dict(b) | |
a_m = parse(a, 'm') | |
a_n = parse(a, 'n') | |
a_m_add_n = parse(a, 'm+n') | |
a_m_sub_n = parse(a, 'm-n') | |
a_n_sub_m = parse(a, 'n-m') | |
a_2m_add_n = parse(a, '2m+n') | |
a_2m_sub_n = parse(a, '2m-n') | |
a_2n_sub_m = parse(a, '2n-m') | |
b_m = parse(b, 'm') | |
b_n = parse(b, 'n') | |
b_m_add_n = parse(b, 'm+n') | |
if a: raise ValueError("unsupported key: %r" % a.keys()[0]) | |
if b: raise ValueError("unsupported key: %r" % b.keys()[0]) | |
s = 0 | |
outer = ctx.one | |
m = ctx.mpf(0) | |
ok_count = 0 | |
prec = ctx.prec | |
maxterms = kwargs.get('maxterms', 20*prec) | |
try: | |
ctx.prec += 10 | |
tol = +ctx.eps | |
while 1: | |
inner_sign = 1 | |
outer_sign = 1 | |
inner_a = list(a_n) | |
inner_b = list(b_n) | |
outer_a = [a+m for a in a_m] | |
outer_b = [b+m for b in b_m] | |
# (a)_{m+n} = (a)_m (a+m)_n | |
for a in a_m_add_n: | |
a = a+m | |
inner_a.append(a) | |
outer_a.append(a) | |
# (b)_{m+n} = (b)_m (b+m)_n | |
for b in b_m_add_n: | |
b = b+m | |
inner_b.append(b) | |
outer_b.append(b) | |
# (a)_{n-m} = (a-m)_n / (a-m)_m | |
for a in a_n_sub_m: | |
inner_a.append(a-m) | |
outer_b.append(a-m-1) | |
# (a)_{m-n} = (-1)^(m+n) (1-a-m)_m / (1-a-m)_n | |
for a in a_m_sub_n: | |
inner_sign *= (-1) | |
outer_sign *= (-1)**(m) | |
inner_b.append(1-a-m) | |
outer_a.append(-a-m) | |
# (a)_{2m+n} = (a)_{2m} (a+2m)_n | |
for a in a_2m_add_n: | |
inner_a.append(a+2*m) | |
outer_a.append((a+2*m)*(1+a+2*m)) | |
# (a)_{2m-n} = (-1)^(2m+n) (1-a-2m)_{2m} / (1-a-2m)_n | |
for a in a_2m_sub_n: | |
inner_sign *= (-1) | |
inner_b.append(1-a-2*m) | |
outer_a.append((a+2*m)*(1+a+2*m)) | |
# (a)_{2n-m} = 4^n ((a-m)/2)_n ((a-m+1)/2)_n / (a-m)_m | |
for a in a_2n_sub_m: | |
inner_sign *= 4 | |
inner_a.append(0.5*(a-m)) | |
inner_a.append(0.5*(a-m+1)) | |
outer_b.append(a-m-1) | |
inner = ctx.hyper(inner_a, inner_b, inner_sign*y, | |
zeroprec=ctx.prec, **kwargs) | |
term = outer * inner * outer_sign | |
if abs(term) < tol: | |
ok_count += 1 | |
else: | |
ok_count = 0 | |
if ok_count >= 3 or not outer: | |
break | |
s += term | |
for a in outer_a: outer *= a | |
for b in outer_b: outer /= b | |
m += 1 | |
outer = outer * x / m | |
if m > maxterms: | |
raise ctx.NoConvergence("maxterms exceeded in hyper2d") | |
finally: | |
ctx.prec = prec | |
return +s | |
""" | |
@defun | |
def kampe_de_feriet(ctx,a,b,c,d,e,f,x,y,**kwargs): | |
return ctx.hyper2d({'m+n':a,'m':b,'n':c}, | |
{'m+n':d,'m':e,'n':f}, x,y, **kwargs) | |
""" | |
def bihyper(ctx, a_s, b_s, z, **kwargs): | |
r""" | |
Evaluates the bilateral hypergeometric series | |
.. math :: | |
\,_AH_B(a_1, \ldots, a_k; b_1, \ldots, b_B; z) = | |
\sum_{n=-\infty}^{\infty} | |
\frac{(a_1)_n \ldots (a_A)_n} | |
{(b_1)_n \ldots (b_B)_n} \, z^n | |
where, for direct convergence, `A = B` and `|z| = 1`, although a | |
regularized sum exists more generally by considering the | |
bilateral series as a sum of two ordinary hypergeometric | |
functions. In order for the series to make sense, none of the | |
parameters may be integers. | |
**Examples** | |
The value of `\,_2H_2` at `z = 1` is given by Dougall's formula:: | |
>>> from mpmath import * | |
>>> mp.dps = 25; mp.pretty = True | |
>>> a,b,c,d = 0.5, 1.5, 2.25, 3.25 | |
>>> bihyper([a,b],[c,d],1) | |
-14.49118026212345786148847 | |
>>> gammaprod([c,d,1-a,1-b,c+d-a-b-1],[c-a,d-a,c-b,d-b]) | |
-14.49118026212345786148847 | |
The regularized function `\,_1H_0` can be expressed as the | |
sum of one `\,_2F_0` function and one `\,_1F_1` function:: | |
>>> a = mpf(0.25) | |
>>> z = mpf(0.75) | |
>>> bihyper([a], [], z) | |
(0.2454393389657273841385582 + 0.2454393389657273841385582j) | |
>>> hyper([a,1],[],z) + (hyper([1],[1-a],-1/z)-1) | |
(0.2454393389657273841385582 + 0.2454393389657273841385582j) | |
>>> hyper([a,1],[],z) + hyper([1],[2-a],-1/z)/z/(a-1) | |
(0.2454393389657273841385582 + 0.2454393389657273841385582j) | |
**References** | |
1. [Slater]_ (chapter 6: "Bilateral Series", pp. 180-189) | |
2. [Wikipedia]_ http://en.wikipedia.org/wiki/Bilateral_hypergeometric_series | |
""" | |
z = ctx.convert(z) | |
c_s = a_s + b_s | |
p = len(a_s) | |
q = len(b_s) | |
if (p, q) == (0,0) or (p, q) == (1,1): | |
return ctx.zero * z | |
neg = (p-q) % 2 | |
def h(*c_s): | |
a_s = list(c_s[:p]) | |
b_s = list(c_s[p:]) | |
aa_s = [2-b for b in b_s] | |
bb_s = [2-a for a in a_s] | |
rp = [(-1)**neg * z] + [1-b for b in b_s] + [1-a for a in a_s] | |
rc = [-1] + [1]*len(b_s) + [-1]*len(a_s) | |
T1 = [], [], [], [], a_s + [1], b_s, z | |
T2 = rp, rc, [], [], aa_s + [1], bb_s, (-1)**neg / z | |
return T1, T2 | |
return ctx.hypercomb(h, c_s, **kwargs) | |