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	from ..libmp.backend import xrange

	class SpecialFunctions(object):
	"""
	This class implements special functions using high-level code.

	Elementary and some other functions (e.g. gamma function, basecase
	hypergeometric series) are assumed to be predefined by the context as
	"builtins" or "low-level" functions.
	"""
	defined_functions = {}

	# The series for the Jacobi theta functions converge for \|q\| < 1;
	# in the current implementation they throw a ValueError for
	# abs(q) > THETA_Q_LIM
	THETA_Q_LIM = 1 - 10**-7

	def __init__(self):
	cls = self.__class__
	for name in cls.defined_functions:
	f, wrap = cls.defined_functions[name]
	cls._wrap_specfun(name, f, wrap)

	self.mpq_1 = self._mpq((1,1))
	self.mpq_0 = self._mpq((0,1))
	self.mpq_1_2 = self._mpq((1,2))
	self.mpq_3_2 = self._mpq((3,2))
	self.mpq_1_4 = self._mpq((1,4))
	self.mpq_1_16 = self._mpq((1,16))
	self.mpq_3_16 = self._mpq((3,16))
	self.mpq_5_2 = self._mpq((5,2))
	self.mpq_3_4 = self._mpq((3,4))
	self.mpq_7_4 = self._mpq((7,4))
	self.mpq_5_4 = self._mpq((5,4))
	self.mpq_1_3 = self._mpq((1,3))
	self.mpq_2_3 = self._mpq((2,3))
	self.mpq_4_3 = self._mpq((4,3))
	self.mpq_1_6 = self._mpq((1,6))
	self.mpq_5_6 = self._mpq((5,6))
	self.mpq_5_3 = self._mpq((5,3))

	self._misc_const_cache = {}

	self._aliases.update({
	'phase' : 'arg',
	'conjugate' : 'conj',
	'nthroot' : 'root',
	'polygamma' : 'psi',
	'hurwitz' : 'zeta',
	#'digamma' : 'psi0',
	#'trigamma' : 'psi1',
	#'tetragamma' : 'psi2',
	#'pentagamma' : 'psi3',
	'fibonacci' : 'fib',
	'factorial' : 'fac',
	})

	self.zetazero_memoized = self.memoize(self.zetazero)

	# Default -- do nothing
	@classmethod
	def _wrap_specfun(cls, name, f, wrap):
	setattr(cls, name, f)

	# Optional fast versions of common functions in common cases.
	# If not overridden, default (generic hypergeometric series)
	# implementations will be used
	def _besselj(ctx, n, z): raise NotImplementedError
	def _erf(ctx, z): raise NotImplementedError
	def _erfc(ctx, z): raise NotImplementedError
	def _gamma_upper_int(ctx, z, a): raise NotImplementedError
	def _expint_int(ctx, n, z): raise NotImplementedError
	def _zeta(ctx, s): raise NotImplementedError
	def _zetasum_fast(ctx, s, a, n, derivatives, reflect): raise NotImplementedError
	def _ei(ctx, z): raise NotImplementedError
	def _e1(ctx, z): raise NotImplementedError
	def _ci(ctx, z): raise NotImplementedError
	def _si(ctx, z): raise NotImplementedError
	def _altzeta(ctx, s): raise NotImplementedError

	def defun_wrapped(f):
	SpecialFunctions.defined_functions[f.__name__] = f, True
	return f

	def defun(f):
	SpecialFunctions.defined_functions[f.__name__] = f, False
	return f

	def defun_static(f):
	setattr(SpecialFunctions, f.__name__, f)
	return f

	@defun_wrapped
	def cot(ctx, z): return ctx.one / ctx.tan(z)

	@defun_wrapped
	def sec(ctx, z): return ctx.one / ctx.cos(z)

	@defun_wrapped
	def csc(ctx, z): return ctx.one / ctx.sin(z)

	@defun_wrapped
	def coth(ctx, z): return ctx.one / ctx.tanh(z)

	@defun_wrapped
	def sech(ctx, z): return ctx.one / ctx.cosh(z)

	@defun_wrapped
	def csch(ctx, z): return ctx.one / ctx.sinh(z)

	@defun_wrapped
	def acot(ctx, z):
	if not z:
	return ctx.pi * 0.5
	else:
	return ctx.atan(ctx.one / z)

	@defun_wrapped
	def asec(ctx, z): return ctx.acos(ctx.one / z)

	@defun_wrapped
	def acsc(ctx, z): return ctx.asin(ctx.one / z)

	@defun_wrapped
	def acoth(ctx, z):
	if not z:
	return ctx.pi * 0.5j
	else:
	return ctx.atanh(ctx.one / z)


	@defun_wrapped
	def asech(ctx, z): return ctx.acosh(ctx.one / z)

	@defun_wrapped
	def acsch(ctx, z): return ctx.asinh(ctx.one / z)

	@defun
	def sign(ctx, x):
	x = ctx.convert(x)
	if not x or ctx.isnan(x):
	return x
	if ctx._is_real_type(x):
	if x > 0:
	return ctx.one
	else:
	return -ctx.one
	return x / abs(x)

	@defun
	def agm(ctx, a, b=1):
	if b == 1:
	return ctx.agm1(a)
	a = ctx.convert(a)
	b = ctx.convert(b)
	return ctx._agm(a, b)

	@defun_wrapped
	def sinc(ctx, x):
	if ctx.isinf(x):
	return 1/x
	if not x:
	return x+1
	return ctx.sin(x)/x

	@defun_wrapped
	def sincpi(ctx, x):
	if ctx.isinf(x):
	return 1/x
	if not x:
	return x+1
	return ctx.sinpi(x)/(ctx.pi*x)

	# TODO: tests; improve implementation
	@defun_wrapped
	def expm1(ctx, x):
	if not x:
	return ctx.zero
	# exp(x) - 1 ~ x
	if ctx.mag(x) < -ctx.prec:
	return x + 0.5x*2
	# TODO: accurately eval the smaller of the real/imag parts
	return ctx.sum_accurately(lambda: iter([ctx.exp(x),-1]),1)

	@defun_wrapped
	def log1p(ctx, x):
	if not x:
	return ctx.zero
	if ctx.mag(x) < -ctx.prec:
	return x - 0.5x*2
	return ctx.log(ctx.fadd(1, x, prec=2*ctx.prec))

	@defun_wrapped
	def powm1(ctx, x, y):
	mag = ctx.mag
	one = ctx.one
	w = x**y - one
	M = mag(w)
	# Only moderate cancellation
	if M > -8:
	return w
	# Check for the only possible exact cases
	if not w:
	if (not y) or (x in (1, -1, 1j, -1j) and ctx.isint(y)):
	return w
	x1 = x - one
	magy = mag(y)
	lnx = ctx.ln(x)
	# Small y: x^y - 1 ~ log(x)y + O(log(x)^2 y^2)
	if magy + mag(lnx) < -ctx.prec:
	return lnxy + (lnxy)**2/2
	# TODO: accurately eval the smaller of the real/imag part
	return ctx.sum_accurately(lambda: iter([x**y, -1]), 1)

	@defun
	def _rootof1(ctx, k, n):
	k = int(k)
	n = int(n)
	k %= n
	if not k:
	return ctx.one
	elif 2*k == n:
	return -ctx.one
	elif 4*k == n:
	return ctx.j
	elif 4k == 3n:
	return -ctx.j
	return ctx.expjpi(2*ctx.mpf(k)/n)

	@defun
	def root(ctx, x, n, k=0):
	n = int(n)
	x = ctx.convert(x)
	if k:
	# Special case: there is an exact real root
	if (n & 1 and 2*k == n-1) and (not ctx.im(x)) and (ctx.re(x) < 0):
	return -ctx.root(-x, n)
	# Multiply by root of unity
	prec = ctx.prec
	try:
	ctx.prec += 10
	v = ctx.root(x, n, 0) * ctx._rootof1(k, n)
	finally:
	ctx.prec = prec
	return +v
	return ctx._nthroot(x, n)

	@defun
	def unitroots(ctx, n, primitive=False):
	gcd = ctx._gcd
	prec = ctx.prec
	try:
	ctx.prec += 10
	if primitive:
	v = [ctx._rootof1(k,n) for k in range(n) if gcd(k,n) == 1]
	else:
	# TODO: this can be done much faster
	v = [ctx._rootof1(k,n) for k in range(n)]
	finally:
	ctx.prec = prec
	return [+x for x in v]

	@defun
	def arg(ctx, x):
	x = ctx.convert(x)
	re = ctx._re(x)
	im = ctx._im(x)
	return ctx.atan2(im, re)

	@defun
	def fabs(ctx, x):
	return abs(ctx.convert(x))

	@defun
	def re(ctx, x):
	x = ctx.convert(x)
	if hasattr(x, "real"): # py2.5 doesn't have .real/.imag for all numbers
	return x.real
	return x

	@defun
	def im(ctx, x):
	x = ctx.convert(x)
	if hasattr(x, "imag"): # py2.5 doesn't have .real/.imag for all numbers
	return x.imag
	return ctx.zero

	@defun
	def conj(ctx, x):
	x = ctx.convert(x)
	try:
	return x.conjugate()
	except AttributeError:
	return x

	@defun
	def polar(ctx, z):
	return (ctx.fabs(z), ctx.arg(z))

	@defun_wrapped
	def rect(ctx, r, phi):
	return r * ctx.mpc(*ctx.cos_sin(phi))

	@defun
	def log(ctx, x, b=None):
	if b is None:
	return ctx.ln(x)
	wp = ctx.prec + 20
	return ctx.ln(x, prec=wp) / ctx.ln(b, prec=wp)

	@defun
	def log10(ctx, x):
	return ctx.log(x, 10)

	@defun
	def fmod(ctx, x, y):
	return ctx.convert(x) % ctx.convert(y)

	@defun
	def degrees(ctx, x):
	return x / ctx.degree

	@defun
	def radians(ctx, x):
	return x * ctx.degree

	def _lambertw_special(ctx, z, k):
	# W(0,0) = 0; all other branches are singular
	if not z:
	if not k:
	return z
	return ctx.ninf + z
	if z == ctx.inf:
	if k == 0:
	return z
	else:
	return z + 2kctx.pi*ctx.j
	if z == ctx.ninf:
	return (-z) + (2k+1)ctx.pi*ctx.j
	# Some kind of nan or complex inf/nan?
	return ctx.ln(z)

	import math
	import cmath

	def _lambertw_approx_hybrid(z, k):
	imag_sign = 0
	if hasattr(z, "imag"):
	x = float(z.real)
	y = z.imag
	if y:
	imag_sign = (-1) ** (y < 0)
	y = float(y)
	else:
	x = float(z)
	y = 0.0
	imag_sign = 0
	# hack to work regardless of whether Python supports -0.0
	if not y:
	y = 0.0
	z = complex(x,y)
	if k == 0:
	if -4.0 < y < 4.0 and -1.0 < x < 2.5:
	if imag_sign:
	# Taylor series in upper/lower half-plane
	if y > 1.00: return (0.876+0.645j) + (0.118-0.174j)*(z-(0.75+2.5j))
	if y > 0.25: return (0.505+0.204j) + (0.375-0.132j)*(z-(0.75+0.5j))
	if y < -1.00: return (0.876-0.645j) + (0.118+0.174j)*(z-(0.75-2.5j))
	if y < -0.25: return (0.505-0.204j) + (0.375+0.132j)*(z-(0.75-0.5j))
	# Taylor series near -1
	if x < -0.5:
	if imag_sign >= 0:
	return (-0.318+1.34j) + (-0.697-0.593j)*(z+1)
	else:
	return (-0.318-1.34j) + (-0.697+0.593j)*(z+1)
	# return real type
	r = -0.367879441171442
	if (not imag_sign) and x > r:
	z = x
	# Singularity near -1/e
	if x < -0.2:
	return -1 + 2.33164398159712(z-r)0.5 - 1.81218788563936(z-r)
	# Taylor series near 0
	if x < 0.5: return z
	# Simple linear approximation
	return 0.2 + 0.3*z
	if (not imag_sign) and x > 0.0:
	L1 = math.log(x); L2 = math.log(L1)
	else:
	L1 = cmath.log(z); L2 = cmath.log(L1)
	elif k == -1:
	# return real type
	r = -0.367879441171442
	if (not imag_sign) and r < x < 0.0:
	z = x
	if (imag_sign >= 0) and y < 0.1 and -0.6 < x < -0.2:
	return -1 - 2.33164398159712(z-r)0.5 - 1.81218788563936(z-r)
	if (not imag_sign) and -0.2 <= x < 0.0:
	L1 = math.log(-x)
	return L1 - math.log(-L1)
	else:
	if imag_sign == -1 and (not y) and x < 0.0:
	L1 = cmath.log(z) - 3.1415926535897932j
	else:
	L1 = cmath.log(z) - 6.2831853071795865j
	L2 = cmath.log(L1)
	return L1 - L2 + L2/L1 + L2(L2-2)/(2L1**2)

	def _lambertw_series(ctx, z, k, tol):
	"""
	Return rough approximation for W_k(z) from an asymptotic series,
	sufficiently accurate for the Halley iteration to converge to
	the correct value.
	"""
	magz = ctx.mag(z)
	if (-10 < magz < 900) and (-1000 < k < 1000):
	# Near the branch point at -1/e
	if magz < 1 and abs(z+0.36787944117144) < 0.05:
	if k == 0 or (k == -1 and ctx._im(z) >= 0) or \
	(k == 1 and ctx._im(z) < 0):
	delta = ctx.sum_accurately(lambda: [z, ctx.exp(-1)])
	cancellation = -ctx.mag(delta)
	ctx.prec += cancellation
	# Use series given in Corless et al.
	p = ctx.sqrt(2(ctx.ez+1))
	ctx.prec -= cancellation
	u = {0:ctx.mpf(-1), 1:ctx.mpf(1)}
	a = {0:ctx.mpf(2), 1:ctx.mpf(-1)}
	if k != 0:
	p = -p
	s = ctx.zero
	# The series converges, so we could use it directly, but unless
	# extremely close, it is better to just use the first few
	# terms to get a good approximation for the iteration
	for l in xrange(max(2,cancellation)):
	if l not in u:
	a[l] = ctx.fsum(u[j]*u[l+1-j] for j in xrange(2,l))
	u[l] = (l-1)*(u[l-2]/2+a[l-2]/4)/(l+1)-a[l]/2-u[l-1]/(l+1)
	term = u[l] * p**l
	s += term
	if ctx.mag(term) < -tol:
	return s, True
	l += 1
	ctx.prec += cancellation//2
	return s, False
	if k == 0 or k == -1:
	return _lambertw_approx_hybrid(z, k), False
	if k == 0:
	if magz < -1:
	return z*(1-z), False
	L1 = ctx.ln(z)
	L2 = ctx.ln(L1)
	elif k == -1 and (not ctx._im(z)) and (-0.36787944117144 < ctx._re(z) < 0):
	L1 = ctx.ln(-z)
	return L1 - ctx.ln(-L1), False
	else:
	# This holds both as z -> 0 and z -> inf.
	# Relative error is O(1/log(z)).
	L1 = ctx.ln(z) + 2jctx.pik
	L2 = ctx.ln(L1)
	return L1 - L2 + L2/L1 + L2(L2-2)/(2L1**2), False

	@defun
	def lambertw(ctx, z, k=0):
	z = ctx.convert(z)
	k = int(k)
	if not ctx.isnormal(z):
	return _lambertw_special(ctx, z, k)
	prec = ctx.prec
	ctx.prec += 20 + ctx.mag(k or 1)
	wp = ctx.prec
	tol = wp - 5
	w, done = _lambertw_series(ctx, z, k, tol)
	if not done:
	# Use Halley iteration to solve w*exp(w) = z
	two = ctx.mpf(2)
	for i in xrange(100):
	ew = ctx.exp(w)
	wew = w*ew
	wewz = wew-z
	wn = w - wewz/(wew+ew-(w+two)wewz/(twow+two))
	if ctx.mag(wn-w) <= ctx.mag(wn) - tol:
	w = wn
	break
	else:
	w = wn
	if i == 100:
	ctx.warn("Lambert W iteration failed to converge for z = %s" % z)
	ctx.prec = prec
	return +w

	@defun_wrapped
	def bell(ctx, n, x=1):
	x = ctx.convert(x)
	if not n:
	if ctx.isnan(x):
	return x
	return type(x)(1)
	if ctx.isinf(x) or ctx.isinf(n) or ctx.isnan(x) or ctx.isnan(n):
	return x**n
	if n == 1: return x
	if n == 2: return x*(x+1)
	if x == 0: return ctx.sincpi(n)
	return _polyexp(ctx, n, x, True) / ctx.exp(x)

	def _polyexp(ctx, n, x, extra=False):
	def _terms():
	if extra:
	yield ctx.sincpi(n)
	t = x
	k = 1
	while 1:
	yield k*n t
	k += 1
	t = t*x/k
	return ctx.sum_accurately(_terms, check_step=4)

	@defun_wrapped
	def polyexp(ctx, s, z):
	if ctx.isinf(z) or ctx.isinf(s) or ctx.isnan(z) or ctx.isnan(s):
	return z**s
	if z == 0: return z*s
	if s == 0: return ctx.expm1(z)
	if s == 1: return ctx.exp(z)*z
	if s == 2: return ctx.exp(z)z(z+1)
	return _polyexp(ctx, s, z)

	@defun_wrapped
	def cyclotomic(ctx, n, z):
	n = int(n)
	if n < 0:
	raise ValueError("n cannot be negative")
	p = ctx.one
	if n == 0:
	return p
	if n == 1:
	return z - p
	if n == 2:
	return z + p
	# Use divisor product representation. Unfortunately, this sometimes
	# includes singularities for roots of unity, which we have to cancel out.
	# Matching zeros/poles pairwise, we have (1-z^a)/(1-z^b) ~ a/b + O(z-1).
	a_prod = 1
	b_prod = 1
	num_zeros = 0
	num_poles = 0
	for d in range(1,n+1):
	if not n % d:
	w = ctx.moebius(n//d)
	# Use powm1 because it is important that we get 0 only
	# if it really is exactly 0
	b = -ctx.powm1(z, d)
	if b:
	p = b*w
	else:
	if w == 1:
	a_prod *= d
	num_zeros += 1
	elif w == -1:
	b_prod *= d
	num_poles += 1
	#print n, num_zeros, num_poles
	if num_zeros:
	if num_zeros > num_poles:
	p *= 0
	else:
	p *= a_prod
	p /= b_prod
	return p

	@defun
	def mangoldt(ctx, n):
	r"""
	Evaluates the von Mangoldt function `\Lambda(n) = \log p`
	if `n = p^k` a power of a prime, and `\Lambda(n) = 0` otherwise.

	Examples

	>>> from mpmath import *
	>>> mp.dps = 25; mp.pretty = True
	>>> [mangoldt(n) for n in range(-2,3)]
	[0.0, 0.0, 0.0, 0.0, 0.6931471805599453094172321]
	>>> mangoldt(6)
	0.0
	>>> mangoldt(7)
	1.945910149055313305105353
	>>> mangoldt(8)
	0.6931471805599453094172321
	>>> fsum(mangoldt(n) for n in range(101))
	94.04531122935739224600493
	>>> fsum(mangoldt(n) for n in range(10001))
	10013.39669326311478372032

	"""
	n = int(n)
	if n < 2:
	return ctx.zero
	if n % 2 == 0:
	# Must be a power of two
	if n & (n-1) == 0:
	return +ctx.ln2
	else:
	return ctx.zero
	# TODO: the following could be generalized into a perfect
	# power testing function
	# ---
	# Look for a small factor
	for p in (3,5,7,11,13,17,19,23,29,31):
	if not n % p:
	q, r = n // p, 0
	while q > 1:
	q, r = divmod(q, p)
	if r:
	return ctx.zero
	return ctx.ln(p)
	if ctx.isprime(n):
	return ctx.ln(n)
	# Obviously, we could use arbitrary-precision arithmetic for this...
	if n > 10**30:
	raise NotImplementedError
	k = 2
	while 1:
	p = int(n**(1./k) + 0.5)
	if p < 2:
	return ctx.zero
	if p ** k == n:
	if ctx.isprime(p):
	return ctx.ln(p)
	k += 1

	@defun
	def stirling1(ctx, n, k, exact=False):
	v = ctx._stirling1(int(n), int(k))
	if exact:
	return int(v)
	else:
	return ctx.mpf(v)

	@defun
	def stirling2(ctx, n, k, exact=False):
	v = ctx._stirling2(int(n), int(k))
	if exact:
	return int(v)
	else:
	return ctx.mpf(v)