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	"""
	This module implements computation of elementary transcendental
	functions (powers, logarithms, trigonometric and hyperbolic
	functions, inverse trigonometric and hyperbolic) for real
	floating-point numbers.

	For complex and interval implementations of the same functions,
	see libmpc and libmpi.

	"""

	import math
	from bisect import bisect

	from .backend import xrange
	from .backend import MPZ, MPZ_ZERO, MPZ_ONE, MPZ_TWO, MPZ_FIVE, BACKEND

	from .libmpf import (
	round_floor, round_ceiling, round_down, round_up,
	round_nearest, round_fast,
	ComplexResult,
	bitcount, bctable, lshift, rshift, giant_steps, sqrt_fixed,
	from_int, to_int, from_man_exp, to_fixed, to_float, from_float,
	from_rational, normalize,
	fzero, fone, fnone, fhalf, finf, fninf, fnan,
	mpf_cmp, mpf_sign, mpf_abs,
	mpf_pos, mpf_neg, mpf_add, mpf_sub, mpf_mul, mpf_div, mpf_shift,
	mpf_rdiv_int, mpf_pow_int, mpf_sqrt,
	reciprocal_rnd, negative_rnd, mpf_perturb,
	isqrt_fast
	)

	from .libintmath import ifib


	#-------------------------------------------------------------------------------
	# Tuning parameters
	#-------------------------------------------------------------------------------

	# Cutoff for computing exp from cosh+sinh. This reduces the
	# number of terms by half, but also requires a square root which
	# is expensive with the pure-Python square root code.
	if BACKEND == 'python':
	EXP_COSH_CUTOFF = 600
	else:
	EXP_COSH_CUTOFF = 400
	# Cutoff for using more than 2 series
	EXP_SERIES_U_CUTOFF = 1500

	# Also basically determined by sqrt
	if BACKEND == 'python':
	COS_SIN_CACHE_PREC = 400
	else:
	COS_SIN_CACHE_PREC = 200
	COS_SIN_CACHE_STEP = 8
	cos_sin_cache = {}

	# Number of integer logarithms to cache (for zeta sums)
	MAX_LOG_INT_CACHE = 2000
	log_int_cache = {}

	LOG_TAYLOR_PREC = 2500 # Use Taylor series with caching up to this prec
	LOG_TAYLOR_SHIFT = 9 # Cache log values in steps of size 2^-N
	log_taylor_cache = {}
	# prec/size ratio of x for fastest convergence in AGM formula
	LOG_AGM_MAG_PREC_RATIO = 20

	ATAN_TAYLOR_PREC = 3000 # Same as for log
	ATAN_TAYLOR_SHIFT = 7 # steps of size 2^-N
	atan_taylor_cache = {}


	# ~= next power of two + 20
	cache_prec_steps = [22,22]
	for k in xrange(1, bitcount(LOG_TAYLOR_PREC)+1):
	cache_prec_steps += [min(2*k,LOG_TAYLOR_PREC)+20] 2**(k-1)


	#----------------------------------------------------------------------------#
	# #
	# Elementary mathematical constants #
	# #
	#----------------------------------------------------------------------------#

	def constant_memo(f):
	"""
	Decorator for caching computed values of mathematical
	constants. This decorator should be applied to a
	function taking a single argument prec as input and
	returning a fixed-point value with the given precision.
	"""
	f.memo_prec = -1
	f.memo_val = None
	def g(prec, **kwargs):
	memo_prec = f.memo_prec
	if prec <= memo_prec:
	return f.memo_val >> (memo_prec-prec)
	newprec = int(prec*1.05+10)
	f.memo_val = f(newprec, **kwargs)
	f.memo_prec = newprec
	return f.memo_val >> (newprec-prec)
	g.__name__ = f.__name__
	g.__doc__ = f.__doc__
	return g

	def def_mpf_constant(fixed):
	"""
	Create a function that computes the mpf value for a mathematical
	constant, given a function that computes the fixed-point value.

	Assumptions: the constant is positive and has magnitude ~= 1;
	the fixed-point function rounds to floor.
	"""
	def f(prec, rnd=round_fast):
	wp = prec + 20
	v = fixed(wp)
	if rnd in (round_up, round_ceiling):
	v += 1
	return normalize(0, v, -wp, bitcount(v), prec, rnd)
	f.__doc__ = fixed.__doc__
	return f

	def bsp_acot(q, a, b, hyperbolic):
	if b - a == 1:
	a1 = MPZ(2*a + 3)
	if hyperbolic or a&1:
	return MPZ_ONE, a1 * q**2, a1
	else:
	return -MPZ_ONE, a1 * q**2, a1
	m = (a+b)//2
	p1, q1, r1 = bsp_acot(q, a, m, hyperbolic)
	p2, q2, r2 = bsp_acot(q, m, b, hyperbolic)
	return q2p1 + r1p2, q1q2, r1r2

	# the acoth(x) series converges like the geometric series for x^2
	# N = ceil(plog(2)/(2log(x)))
	def acot_fixed(a, prec, hyperbolic):
	"""
	Compute acot(a) or acoth(a) for an integer a with binary splitting; see
	http://numbers.computation.free.fr/Constants/Algorithms/splitting.html
	"""
	N = int(0.35 * prec/math.log(a) + 20)
	p, q, r = bsp_acot(a, 0,N, hyperbolic)
	return ((p+q)<<prec)//(q*a)

	def machin(coefs, prec, hyperbolic=False):
	"""
	Evaluate a Machin-like formula, i.e., a linear combination of
	acot(n) or acoth(n) for specific integer values of n, using fixed-
	point arithmetic. The input should be a list [(c, n), ...], giving
	c*acot[h](n) + ...
	"""
	extraprec = 10
	s = MPZ_ZERO
	for a, b in coefs:
	s += MPZ(a) * acot_fixed(MPZ(b), prec+extraprec, hyperbolic)
	return (s >> extraprec)

	# Logarithms of integers are needed for various computations involving
	# logarithms, powers, radix conversion, etc

	@constant_memo
	def ln2_fixed(prec):
	"""
	Computes ln(2). This is done with a hyperbolic Machin-type formula,
	with binary splitting at high precision.
	"""
	return machin([(18, 26), (-2, 4801), (8, 8749)], prec, True)

	@constant_memo
	def ln10_fixed(prec):
	"""
	Computes ln(10). This is done with a hyperbolic Machin-type formula.
	"""
	return machin([(46, 31), (34, 49), (20, 161)], prec, True)


	r"""
	For computation of pi, we use the Chudnovsky series:

	oo
	___ k
	1 \ (-1) (6 k)! (A + B k)
	----- = ) -----------------------
	12 pi /___ 3 3k+3/2
	(3 k)! (k!) C
	k = 0

	where A, B, and C are certain integer constants. This series adds roughly
	14 digits per term. Note that C^(3/2) can be extracted so that the
	series contains only rational terms. This makes binary splitting very
	efficient.

	The recurrence formulas for the binary splitting were taken from
	ftp://ftp.gmplib.org/pub/src/gmp-chudnovsky.c

	Previously, Machin's formula was used at low precision and the AGM iteration
	was used at high precision. However, the Chudnovsky series is essentially as
	fast as the Machin formula at low precision and in practice about 3x faster
	than the AGM at high precision (despite theoretically having a worse
	asymptotic complexity), so there is no reason not to use it in all cases.

	"""

	# Constants in Chudnovsky's series
	CHUD_A = MPZ(13591409)
	CHUD_B = MPZ(545140134)
	CHUD_C = MPZ(640320)
	CHUD_D = MPZ(12)

	def bs_chudnovsky(a, b, level, verbose):
	"""
	Computes the sum from a to b of the series in the Chudnovsky
	formula. Returns g, p, q where p/q is the sum as an exact
	fraction and g is a temporary value used to save work
	for recursive calls.
	"""
	if b-a == 1:
	g = MPZ((6b-5)(2b-1)(6*b-1))
	p = b*3 CHUD_C**3 // 24
	q = (-1)*b g * (CHUD_A+CHUD_B*b)
	else:
	if verbose and level < 4:
	print(" binary splitting", a, b)
	mid = (a+b)//2
	g1, p1, q1 = bs_chudnovsky(a, mid, level+1, verbose)
	g2, p2, q2 = bs_chudnovsky(mid, b, level+1, verbose)
	p = p1*p2
	g = g1*g2
	q = q1p2 + q2g1
	return g, p, q

	@constant_memo
	def pi_fixed(prec, verbose=False, verbose_base=None):
	"""
	Compute floor(pi * 2**prec) as a big integer.

	This is done using Chudnovsky's series (see comments in
	libelefun.py for details).
	"""
	# The Chudnovsky series gives 14.18 digits per term
	N = int(prec/3.3219280948/14.181647462 + 2)
	if verbose:
	print("binary splitting with N =", N)
	g, p, q = bs_chudnovsky(0, N, 0, verbose)
	sqrtC = isqrt_fast(CHUD_C<<(2*prec))
	v = pCHUD_CsqrtC//((q+CHUD_Ap)CHUD_D)
	return v

	def degree_fixed(prec):
	return pi_fixed(prec)//180

	def bspe(a, b):
	"""
	Sum series for exp(1)-1 between a, b, returning the result
	as an exact fraction (p, q).
	"""
	if b-a == 1:
	return MPZ_ONE, MPZ(b)
	m = (a+b)//2
	p1, q1 = bspe(a, m)
	p2, q2 = bspe(m, b)
	return p1q2+p2, q1q2

	@constant_memo
	def e_fixed(prec):
	"""
	Computes exp(1). This is done using the ordinary Taylor series for
	exp, with binary splitting. For a description of the algorithm,
	see:

	http://numbers.computation.free.fr/Constants/
	Algorithms/splitting.html
	"""
	# Slight overestimate of N needed for 1/N! < 2**(-prec)
	# This could be tightened for large N.
	N = int(1.1*prec/math.log(prec) + 20)
	p, q = bspe(0,N)
	return ((p+q)<<prec)//q

	@constant_memo
	def phi_fixed(prec):
	"""
	Computes the golden ratio, (1+sqrt(5))/2
	"""
	prec += 10
	a = isqrt_fast(MPZ_FIVE<<(2*prec)) + (MPZ_ONE << prec)
	return a >> 11

	mpf_phi = def_mpf_constant(phi_fixed)
	mpf_pi = def_mpf_constant(pi_fixed)
	mpf_e = def_mpf_constant(e_fixed)
	mpf_degree = def_mpf_constant(degree_fixed)
	mpf_ln2 = def_mpf_constant(ln2_fixed)
	mpf_ln10 = def_mpf_constant(ln10_fixed)


	@constant_memo
	def ln_sqrt2pi_fixed(prec):
	wp = prec + 10
	# ln(sqrt(2pi)) = ln(2pi)/2
	return to_fixed(mpf_log(mpf_shift(mpf_pi(wp), 1), wp), prec-1)

	@constant_memo
	def sqrtpi_fixed(prec):
	return sqrt_fixed(pi_fixed(prec), prec)

	mpf_sqrtpi = def_mpf_constant(sqrtpi_fixed)
	mpf_ln_sqrt2pi = def_mpf_constant(ln_sqrt2pi_fixed)


	#----------------------------------------------------------------------------#
	# #
	# Powers #
	# #
	#----------------------------------------------------------------------------#

	def mpf_pow(s, t, prec, rnd=round_fast):
	"""
	Compute s**t. Raises ComplexResult if s is negative and t is
	fractional.
	"""
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t
	if ssign and texp < 0:
	raise ComplexResult("negative number raised to a fractional power")
	if texp >= 0:
	return mpf_pow_int(s, (-1)*tsign (tman<<texp), prec, rnd)
	# s(n/2) = sqrt(s)n
	if texp == -1:
	if tman == 1:
	if tsign:
	return mpf_div(fone, mpf_sqrt(s, prec+10,
	reciprocal_rnd[rnd]), prec, rnd)
	return mpf_sqrt(s, prec, rnd)
	else:
	if tsign:
	return mpf_pow_int(mpf_sqrt(s, prec+10,
	reciprocal_rnd[rnd]), -tman, prec, rnd)
	return mpf_pow_int(mpf_sqrt(s, prec+10, rnd), tman, prec, rnd)
	# General formula: s*t = exp(tlog(s))
	# TODO: handle rnd direction of the logarithm carefully
	c = mpf_log(s, prec+10, rnd)
	return mpf_exp(mpf_mul(t, c), prec, rnd)

	def int_pow_fixed(y, n, prec):
	"""n-th power of a fixed point number with precision prec

	Returns the power in the form man, exp,
	man * 2exp ~= yn
	"""
	if n == 2:
	return (y*y), 0
	bc = bitcount(y)
	exp = 0
	workprec = 2 * (prec + 4*bitcount(n) + 4)
	_, pm, pe, pbc = fone
	while 1:
	if n & 1:
	pm = pm*y
	pe = pe+exp
	pbc += bc - 2
	pbc = pbc + bctable[int(pm >> pbc)]
	if pbc > workprec:
	pm = pm >> (pbc-workprec)
	pe += pbc - workprec
	pbc = workprec
	n -= 1
	if not n:
	break
	y = y*y
	exp = exp+exp
	bc = bc + bc - 2
	bc = bc + bctable[int(y >> bc)]
	if bc > workprec:
	y = y >> (bc-workprec)
	exp += bc - workprec
	bc = workprec
	n = n // 2
	return pm, pe

	# froot(s, n, prec, rnd) computes the real n-th root of a
	# positive mpf tuple s.
	# To compute the root we start from a 50-bit estimate for r
	# generated with ordinary floating-point arithmetic, and then refine
	# the value to full accuracy using the iteration

	# 1 / y \
	# r = --- \| (n-1) * r + ---------- \|
	# n+1 n \ n r_n**(n-1) /

	# which is simply Newton's method applied to the equation r**n = y.
	# With giant_steps(start, prec+extra) = [p0,...,pm, prec+extra]
	# and y = man * 2**-shift one has
	# (man * 2exp)(1/n) =
	# y*(1/n) 2*(start-prec/n) 2*(p0-start) ... * 2*(prec+extra-pm)
	# 2*((exp+shift-(n-1)prec)/n -extra))
	# The last factor is accounted for in the last line of froot.

	def nthroot_fixed(y, n, prec, exp1):
	start = 50
	try:
	y1 = rshift(y, prec - n*start)
	r = MPZ(int(y1**(1.0/n)))
	except OverflowError:
	y1 = from_int(y1, start)
	fn = from_int(n)
	fn = mpf_rdiv_int(1, fn, start)
	r = mpf_pow(y1, fn, start)
	r = to_int(r)
	extra = 10
	extra1 = n
	prevp = start
	for p in giant_steps(start, prec+extra):
	pm, pe = int_pow_fixed(r, n-1, prevp)
	r2 = rshift(pm, (n-1)*prevp - p - pe - extra1)
	B = lshift(y, 2*p-prec+extra1)//r2
	r = (B + (n-1) * lshift(r, p-prevp))//n
	prevp = p
	return r

	def mpf_nthroot(s, n, prec, rnd=round_fast):
	"""nth-root of a positive number

	Use the Newton method when faster, otherwise use x**(1/n)
	"""
	sign, man, exp, bc = s
	if sign:
	raise ComplexResult("nth root of a negative number")
	if not man:
	if s == fnan:
	return fnan
	if s == fzero:
	if n > 0:
	return fzero
	if n == 0:
	return fone
	return finf
	# Infinity
	if not n:
	return fnan
	if n < 0:
	return fzero
	return finf
	flag_inverse = False
	if n < 2:
	if n == 0:
	return fone
	if n == 1:
	return mpf_pos(s, prec, rnd)
	if n == -1:
	return mpf_div(fone, s, prec, rnd)
	# n < 0
	rnd = reciprocal_rnd[rnd]
	flag_inverse = True
	extra_inverse = 5
	prec += extra_inverse
	n = -n
	if n > 20 and (n >= 20000 or prec < int(233 + 28.3 * n**0.62)):
	prec2 = prec + 10
	fn = from_int(n)
	nth = mpf_rdiv_int(1, fn, prec2)
	r = mpf_pow(s, nth, prec2, rnd)
	s = normalize(r[0], r[1], r[2], r[3], prec, rnd)
	if flag_inverse:
	return mpf_div(fone, s, prec-extra_inverse, rnd)
	else:
	return s
	# Convert to a fixed-point number with prec2 bits.
	prec2 = prec + 2*n - (prec%n)
	# a few tests indicate that
	# for 10 < n < 10**4 a bit more precision is needed
	if n > 10:
	prec2 += prec2//10
	prec2 = prec2 - prec2%n
	# Mantissa may have more bits than we need. Trim it down.
	shift = bc - prec2
	# Adjust exponents to make prec2 and exp+shift multiples of n.
	sign1 = 0
	es = exp+shift
	if es < 0:
	sign1 = 1
	es = -es
	if sign1:
	shift += es%n
	else:
	shift -= es%n
	man = rshift(man, shift)
	extra = 10
	exp1 = ((exp+shift-(n-1)*prec2)//n) - extra
	rnd_shift = 0
	if flag_inverse:
	if rnd == 'u' or rnd == 'c':
	rnd_shift = 1
	else:
	if rnd == 'd' or rnd == 'f':
	rnd_shift = 1
	man = nthroot_fixed(man+rnd_shift, n, prec2, exp1)
	s = from_man_exp(man, exp1, prec, rnd)
	if flag_inverse:
	return mpf_div(fone, s, prec-extra_inverse, rnd)
	else:
	return s

	def mpf_cbrt(s, prec, rnd=round_fast):
	"""cubic root of a positive number"""
	return mpf_nthroot(s, 3, prec, rnd)

	#----------------------------------------------------------------------------#
	# #
	# Logarithms #
	# #
	#----------------------------------------------------------------------------#


	def log_int_fixed(n, prec, ln2=None):
	"""
	Fast computation of log(n), caching the value for small n,
	intended for zeta sums.
	"""
	if n in log_int_cache:
	value, vprec = log_int_cache[n]
	if vprec >= prec:
	return value >> (vprec - prec)
	wp = prec + 10
	if wp <= LOG_TAYLOR_SHIFT:
	if ln2 is None:
	ln2 = ln2_fixed(wp)
	r = bitcount(n)
	x = n << (wp-r)
	v = log_taylor_cached(x, wp) + r*ln2
	else:
	v = to_fixed(mpf_log(from_int(n), wp+5), wp)
	if n < MAX_LOG_INT_CACHE:
	log_int_cache[n] = (v, wp)
	return v >> (wp-prec)

	def agm_fixed(a, b, prec):
	"""
	Fixed-point computation of agm(a,b), assuming
	a, b both close to unit magnitude.
	"""
	i = 0
	while 1:
	anew = (a+b)>>1
	if i > 4 and abs(a-anew) < 8:
	return a
	b = isqrt_fast(a*b)
	a = anew
	i += 1
	return a

	def log_agm(x, prec):
	"""
	Fixed-point computation of -log(x) = log(1/x), suitable
	for large precision. It is required that 0 < x < 1. The
	algorithm used is the Sasaki-Kanada formula

	-log(x) = pi/agm(theta2(x)^2,theta3(x)^2). [1]

	For faster convergence in the theta functions, x should
	be chosen closer to 0.

	Guard bits must be added by the caller.

	HYPOTHESIS: if x = 2^(-n), n bits need to be added to
	account for the truncation to a fixed-point number,
	and this is the only significant cancellation error.

	The number of bits lost to roundoff is small and can be
	considered constant.

	[1] Richard P. Brent, "Fast Algorithms for High-Precision
	Computation of Elementary Functions (extended abstract)",
	http://wwwmaths.anu.edu.au/~brent/pd/RNC7-Brent.pdf

	"""
	x2 = (x*x) >> prec
	# Compute jtheta2(x)**2
	s = a = b = x2
	while a:
	b = (b*x2) >> prec
	a = (a*b) >> prec
	s += a
	s += (MPZ_ONE<<prec)
	s = (s*s)>>(prec-2)
	s = (s*isqrt_fast(x<<prec))>>prec
	# Compute jtheta3(x)**2
	t = a = b = x
	while a:
	b = (b*x2) >> prec
	a = (a*b) >> prec
	t += a
	t = (MPZ_ONE<<prec) + (t<<1)
	t = (t*t)>>prec
	# Final formula
	p = agm_fixed(s, t, prec)
	return (pi_fixed(prec) << prec) // p

	def log_taylor(x, prec, r=0):
	"""
	Fixed-point calculation of log(x). It is assumed that x is close
	enough to 1 for the Taylor series to converge quickly. Convergence
	can be improved by specifying r > 0 to compute
	log(x^(1/2^r))*2^r, at the cost of performing r square roots.

	The caller must provide sufficient guard bits.
	"""
	for i in xrange(r):
	x = isqrt_fast(x<<prec)
	one = MPZ_ONE << prec
	v = ((x-one)<<prec)//(x+one)
	sign = v < 0
	if sign:
	v = -v
	v2 = (v*v) >> prec
	v4 = (v2*v2) >> prec
	s0 = v
	s1 = v//3
	v = (v*v4) >> prec
	k = 5
	while v:
	s0 += v // k
	k += 2
	s1 += v // k
	v = (v*v4) >> prec
	k += 2
	s1 = (s1*v2) >> prec
	s = (s0+s1) << (1+r)
	if sign:
	return -s
	return s

	def log_taylor_cached(x, prec):
	"""
	Fixed-point computation of log(x), assuming x in (0.5, 2)
	and prec <= LOG_TAYLOR_PREC.
	"""
	n = x >> (prec-LOG_TAYLOR_SHIFT)
	cached_prec = cache_prec_steps[prec]
	dprec = cached_prec - prec
	if (n, cached_prec) in log_taylor_cache:
	a, log_a = log_taylor_cache[n, cached_prec]
	else:
	a = n << (cached_prec - LOG_TAYLOR_SHIFT)
	log_a = log_taylor(a, cached_prec, 8)
	log_taylor_cache[n, cached_prec] = (a, log_a)
	a >>= dprec
	log_a >>= dprec
	u = ((x - a) << prec) // a
	v = (u << prec) // ((MPZ_TWO << prec) + u)
	v2 = (v*v) >> prec
	v4 = (v2*v2) >> prec
	s0 = v
	s1 = v//3
	v = (v*v4) >> prec
	k = 5
	while v:
	s0 += v//k
	k += 2
	s1 += v//k
	v = (v*v4) >> prec
	k += 2
	s1 = (s1*v2) >> prec
	s = (s0+s1) << 1
	return log_a + s

	def mpf_log(x, prec, rnd=round_fast):
	"""
	Compute the natural logarithm of the mpf value x. If x is negative,
	ComplexResult is raised.
	"""
	sign, man, exp, bc = x
	#------------------------------------------------------------------
	# Handle special values
	if not man:
	if x == fzero: return fninf
	if x == finf: return finf
	if x == fnan: return fnan
	if sign:
	raise ComplexResult("logarithm of a negative number")
	wp = prec + 20
	#------------------------------------------------------------------
	# Handle log(2^n) = log(n)*2.
	# Here we catch the only possible exact value, log(1) = 0
	if man == 1:
	if not exp:
	return fzero
	return from_man_exp(exp*ln2_fixed(wp), -wp, prec, rnd)
	mag = exp+bc
	abs_mag = abs(mag)
	#------------------------------------------------------------------
	# Handle x = 1+eps, where log(x) ~ x. We need to check for
	# cancellation when moving to fixed-point math and compensate
	# by increasing the precision. Note that abs_mag in (0, 1) <=>
	# 0.5 < x < 2 and x != 1
	if abs_mag <= 1:
	# Calculate t = x-1 to measure distance from 1 in bits
	tsign = 1-abs_mag
	if tsign:
	tman = (MPZ_ONE<<bc) - man
	else:
	tman = man - (MPZ_ONE<<(bc-1))
	tbc = bitcount(tman)
	cancellation = bc - tbc
	if cancellation > wp:
	t = normalize(tsign, tman, abs_mag-bc, tbc, tbc, 'n')
	return mpf_perturb(t, tsign, prec, rnd)
	else:
	wp += cancellation
	# TODO: if close enough to 1, we could use Taylor series
	# even in the AGM precision range, since the Taylor series
	# converges rapidly
	#------------------------------------------------------------------
	# Another special case:
	# n*log(2) is a good enough approximation
	if abs_mag > 10000:
	if bitcount(abs_mag) > wp:
	return from_man_exp(exp*ln2_fixed(wp), -wp, prec, rnd)
	#------------------------------------------------------------------
	# General case.
	# Perform argument reduction using log(x) = log(x2^n) - nlog(2):
	# If we are in the Taylor precision range, choose magnitude 0 or 1.
	# If we are in the AGM precision range, choose magnitude -m for
	# some large m; benchmarking on one machine showed m = prec/20 to be
	# optimal between 1000 and 100,000 digits.
	if wp <= LOG_TAYLOR_PREC:
	m = log_taylor_cached(lshift(man, wp-bc), wp)
	if mag:
	m += mag*ln2_fixed(wp)
	else:
	optimal_mag = -wp//LOG_AGM_MAG_PREC_RATIO
	n = optimal_mag - mag
	x = mpf_shift(x, n)
	wp += (-optimal_mag)
	m = -log_agm(to_fixed(x, wp), wp)
	m -= n*ln2_fixed(wp)
	return from_man_exp(m, -wp, prec, rnd)

	def mpf_log_hypot(a, b, prec, rnd):
	"""
	Computes log(sqrt(a^2+b^2)) accurately.
	"""
	# If either a or b is inf/nan/0, assume it to be a
	if not b[1]:
	a, b = b, a
	# a is inf/nan/0
	if not a[1]:
	# both are inf/nan/0
	if not b[1]:
	if a == b == fzero:
	return fninf
	if fnan in (a, b):
	return fnan
	# at least one term is (+/- inf)^2
	return finf
	# only a is inf/nan/0
	if a == fzero:
	# log(sqrt(0+b^2)) = log(\|b\|)
	return mpf_log(mpf_abs(b), prec, rnd)
	if a == fnan:
	return fnan
	return finf
	# Exact
	a2 = mpf_mul(a,a)
	b2 = mpf_mul(b,b)
	extra = 20
	# Not exact
	h2 = mpf_add(a2, b2, prec+extra)
	cancelled = mpf_add(h2, fnone, 10)
	mag_cancelled = cancelled[2]+cancelled[3]
	# Just redo the sum exactly if necessary (could be smarter
	# and avoid memory allocation when a or b is precisely 1
	# and the other is tiny...)
	if cancelled == fzero or mag_cancelled < -extra//2:
	h2 = mpf_add(a2, b2, prec+extra-min(a2[2],b2[2]))
	return mpf_shift(mpf_log(h2, prec, rnd), -1)


	#----------------------------------------------------------------------
	# Inverse tangent
	#

	def atan_newton(x, prec):
	if prec >= 100:
	r = math.atan(int((x>>(prec-53)))/2.0**53)
	else:
	r = math.atan(int(x)/2.0**prec)
	prevp = 50
	r = MPZ(int(r * 2.0**53) >> (53-prevp))
	extra_p = 50
	for wp in giant_steps(prevp, prec):
	wp += extra_p
	r = r << (wp-prevp)
	cos, sin = cos_sin_fixed(r, wp)
	tan = (sin << wp) // cos
	a = ((tan-rshift(x, prec-wp)) << wp) // ((MPZ_ONE<<wp) + ((tan**2)>>wp))
	r = r - a
	prevp = wp
	return rshift(r, prevp-prec)

	def atan_taylor_get_cached(n, prec):
	# Taylor series with caching wins up to huge precisions
	# To avoid unnecessary precomputation at low precision, we
	# do it in steps
	# Round to next power of 2
	prec2 = (1<<(bitcount(prec-1))) + 20
	dprec = prec2 - prec
	if (n, prec2) in atan_taylor_cache:
	a, atan_a = atan_taylor_cache[n, prec2]
	else:
	a = n << (prec2 - ATAN_TAYLOR_SHIFT)
	atan_a = atan_newton(a, prec2)
	atan_taylor_cache[n, prec2] = (a, atan_a)
	return (a >> dprec), (atan_a >> dprec)

	def atan_taylor(x, prec):
	n = (x >> (prec-ATAN_TAYLOR_SHIFT))
	a, atan_a = atan_taylor_get_cached(n, prec)
	d = x - a
	s0 = v = (d << prec) // ((a*2 >> prec) + (ad >> prec) + (MPZ_ONE << prec))
	v2 = (v**2 >> prec)
	v4 = (v2 * v2) >> prec
	s1 = v//3
	v = (v * v4) >> prec
	k = 5
	while v:
	s0 += v // k
	k += 2
	s1 += v // k
	v = (v * v4) >> prec
	k += 2
	s1 = (s1 * v2) >> prec
	s = s0 - s1
	return atan_a + s

	def atan_inf(sign, prec, rnd):
	if not sign:
	return mpf_shift(mpf_pi(prec, rnd), -1)
	return mpf_neg(mpf_shift(mpf_pi(prec, negative_rnd[rnd]), -1))

	def mpf_atan(x, prec, rnd=round_fast):
	sign, man, exp, bc = x
	if not man:
	if x == fzero: return fzero
	if x == finf: return atan_inf(0, prec, rnd)
	if x == fninf: return atan_inf(1, prec, rnd)
	return fnan
	mag = exp + bc
	# Essentially infinity
	if mag > prec+20:
	return atan_inf(sign, prec, rnd)
	# Essentially ~ x
	if -mag > prec+20:
	return mpf_perturb(x, 1-sign, prec, rnd)
	wp = prec + 30 + abs(mag)
	# For large x, use atan(x) = pi/2 - atan(1/x)
	if mag >= 2:
	x = mpf_rdiv_int(1, x, wp)
	reciprocal = True
	else:
	reciprocal = False
	t = to_fixed(x, wp)
	if sign:
	t = -t
	if wp < ATAN_TAYLOR_PREC:
	a = atan_taylor(t, wp)
	else:
	a = atan_newton(t, wp)
	if reciprocal:
	a = ((pi_fixed(wp)>>1)+1) - a
	if sign:
	a = -a
	return from_man_exp(a, -wp, prec, rnd)

	# TODO: cleanup the special cases
	def mpf_atan2(y, x, prec, rnd=round_fast):
	xsign, xman, xexp, xbc = x
	ysign, yman, yexp, ybc = y
	if not yman:
	if y == fzero and x != fnan:
	if mpf_sign(x) >= 0:
	return fzero
	return mpf_pi(prec, rnd)
	if y in (finf, fninf):
	if x in (finf, fninf):
	return fnan
	# pi/2
	if y == finf:
	return mpf_shift(mpf_pi(prec, rnd), -1)
	# -pi/2
	return mpf_neg(mpf_shift(mpf_pi(prec, negative_rnd[rnd]), -1))
	return fnan
	if ysign:
	return mpf_neg(mpf_atan2(mpf_neg(y), x, prec, negative_rnd[rnd]))
	if not xman:
	if x == fnan:
	return fnan
	if x == finf:
	return fzero
	if x == fninf:
	return mpf_pi(prec, rnd)
	if y == fzero:
	return fzero
	return mpf_shift(mpf_pi(prec, rnd), -1)
	tquo = mpf_atan(mpf_div(y, x, prec+4), prec+4)
	if xsign:
	return mpf_add(mpf_pi(prec+4), tquo, prec, rnd)
	else:
	return mpf_pos(tquo, prec, rnd)

	def mpf_asin(x, prec, rnd=round_fast):
	sign, man, exp, bc = x
	if bc+exp > 0 and x not in (fone, fnone):
	raise ComplexResult("asin(x) is real only for -1 <= x <= 1")
	# asin(x) = 2atan(x/(1+sqrt(1-x*2)))
	wp = prec + 15
	a = mpf_mul(x, x)
	b = mpf_add(fone, mpf_sqrt(mpf_sub(fone, a, wp), wp), wp)
	c = mpf_div(x, b, wp)
	return mpf_shift(mpf_atan(c, prec, rnd), 1)

	def mpf_acos(x, prec, rnd=round_fast):
	# acos(x) = 2atan(sqrt(1-x*2)/(1+x))
	sign, man, exp, bc = x
	if bc + exp > 0:
	if x not in (fone, fnone):
	raise ComplexResult("acos(x) is real only for -1 <= x <= 1")
	if x == fnone:
	return mpf_pi(prec, rnd)
	wp = prec + 15
	a = mpf_mul(x, x)
	b = mpf_sqrt(mpf_sub(fone, a, wp), wp)
	c = mpf_div(b, mpf_add(fone, x, wp), wp)
	return mpf_shift(mpf_atan(c, prec, rnd), 1)

	def mpf_asinh(x, prec, rnd=round_fast):
	wp = prec + 20
	sign, man, exp, bc = x
	mag = exp+bc
	if mag < -8:
	if mag < -wp:
	return mpf_perturb(x, 1-sign, prec, rnd)
	wp += (-mag)
	# asinh(x) = log(x+sqrt(x**2+1))
	# use reflection symmetry to avoid cancellation
	q = mpf_sqrt(mpf_add(mpf_mul(x, x), fone, wp), wp)
	q = mpf_add(mpf_abs(x), q, wp)
	if sign:
	return mpf_neg(mpf_log(q, prec, negative_rnd[rnd]))
	else:
	return mpf_log(q, prec, rnd)

	def mpf_acosh(x, prec, rnd=round_fast):
	# acosh(x) = log(x+sqrt(x**2-1))
	wp = prec + 15
	if mpf_cmp(x, fone) == -1:
	raise ComplexResult("acosh(x) is real only for x >= 1")
	q = mpf_sqrt(mpf_add(mpf_mul(x,x), fnone, wp), wp)
	return mpf_log(mpf_add(x, q, wp), prec, rnd)

	def mpf_atanh(x, prec, rnd=round_fast):
	# atanh(x) = log((1+x)/(1-x))/2
	sign, man, exp, bc = x
	if (not man) and exp:
	if x in (fzero, fnan):
	return x
	raise ComplexResult("atanh(x) is real only for -1 <= x <= 1")
	mag = bc + exp
	if mag > 0:
	if mag == 1 and man == 1:
	return [finf, fninf][sign]
	raise ComplexResult("atanh(x) is real only for -1 <= x <= 1")
	wp = prec + 15
	if mag < -8:
	if mag < -wp:
	return mpf_perturb(x, sign, prec, rnd)
	wp += (-mag)
	a = mpf_add(x, fone, wp)
	b = mpf_sub(fone, x, wp)
	return mpf_shift(mpf_log(mpf_div(a, b, wp), prec, rnd), -1)

	def mpf_fibonacci(x, prec, rnd=round_fast):
	sign, man, exp, bc = x
	if not man:
	if x == fninf:
	return fnan
	return x
	# F(2^n) ~= 2^(2^n)
	size = abs(exp+bc)
	if exp >= 0:
	# Exact
	if size < 10 or size <= bitcount(prec):
	return from_int(ifib(to_int(x)), prec, rnd)
	# Use the modified Binet formula
	wp = prec + size + 20
	a = mpf_phi(wp)
	b = mpf_add(mpf_shift(a, 1), fnone, wp)
	u = mpf_pow(a, x, wp)
	v = mpf_cos_pi(x, wp)
	v = mpf_div(v, u, wp)
	u = mpf_sub(u, v, wp)
	u = mpf_div(u, b, prec, rnd)
	return u


	#-------------------------------------------------------------------------------
	# Exponential-type functions
	#-------------------------------------------------------------------------------

	def exponential_series(x, prec, type=0):
	"""
	Taylor series for cosh/sinh or cos/sin.

	type = 0 -- returns exp(x) (slightly faster than cosh+sinh)
	type = 1 -- returns (cosh(x), sinh(x))
	type = 2 -- returns (cos(x), sin(x))
	"""
	if x < 0:
	x = -x
	sign = 1
	else:
	sign = 0
	r = int(0.5prec*0.5)
	xmag = bitcount(x) - prec
	r = max(0, xmag + r)
	extra = 10 + 2*max(r,-xmag)
	wp = prec + extra
	x <<= (extra - r)
	one = MPZ_ONE << wp
	alt = (type == 2)
	if prec < EXP_SERIES_U_CUTOFF:
	x2 = a = (x*x) >> wp
	x4 = (x2*x2) >> wp
	s0 = s1 = MPZ_ZERO
	k = 2
	while a:
	a //= (k-1)*k; s0 += a; k += 2
	a //= (k-1)*k; s1 += a; k += 2
	a = (a*x4) >> wp
	s1 = (x2*s1) >> wp
	if alt:
	c = s1 - s0 + one
	else:
	c = s1 + s0 + one
	else:
	u = int(0.3prec*0.35)
	x2 = a = (x*x) >> wp
	xpowers = [one, x2]
	for i in xrange(1, u):
	xpowers.append((xpowers[-1]*x2)>>wp)
	sums = [MPZ_ZERO] * u
	k = 2
	while a:
	for i in xrange(u):
	a //= (k-1)*k
	if alt and k & 2: sums[i] -= a
	else: sums[i] += a
	k += 2
	a = (a*xpowers[-1]) >> wp
	for i in xrange(1, u):
	sums[i] = (sums[i]*xpowers[i]) >> wp
	c = sum(sums) + one
	if type == 0:
	s = isqrt_fast(c*c - (one<<wp))
	if sign:
	v = c - s
	else:
	v = c + s
	for i in xrange(r):
	v = (v*v) >> wp
	return v >> extra
	else:
	# Repeatedly apply the double-angle formula
	# cosh(2x) = 2cosh(x)^2 - 1
	# cos(2x) = 2cos(x)^2 - 1
	pshift = wp-1
	for i in xrange(r):
	c = ((c*c) >> pshift) - one
	# With the abs, this is the same for sinh and sin
	s = isqrt_fast(abs((one<<wp) - c*c))
	if sign:
	s = -s
	return (c>>extra), (s>>extra)

	def exp_basecase(x, prec):
	"""
	Compute exp(x) as a fixed-point number. Works for any x,
	but for speed should have \|x\| < 1. For an arbitrary number,
	use exp(x) = exp(x-mlog(2)) 2^m where m = floor(x/log(2)).
	"""
	if prec > EXP_COSH_CUTOFF:
	return exponential_series(x, prec, 0)
	r = int(prec**0.5)
	prec += r
	s0 = s1 = (MPZ_ONE << prec)
	k = 2
	a = x2 = (x*x) >> prec
	while a:
	a //= k; s0 += a; k += 1
	a //= k; s1 += a; k += 1
	a = (a*x2) >> prec
	s1 = (s1*x) >> prec
	s = s0 + s1
	u = r
	while r:
	s = (s*s) >> prec
	r -= 1
	return s >> u

	def exp_expneg_basecase(x, prec):
	"""
	Computation of exp(x), exp(-x)
	"""
	if prec > EXP_COSH_CUTOFF:
	cosh, sinh = exponential_series(x, prec, 1)
	return cosh+sinh, cosh-sinh
	a = exp_basecase(x, prec)
	b = (MPZ_ONE << (prec+prec)) // a
	return a, b

	def cos_sin_basecase(x, prec):
	"""
	Compute cos(x), sin(x) as fixed-point numbers, assuming x
	in [0, pi/2). For an arbitrary number, use x' = x - m*(pi/2)
	where m = floor(x/(pi/2)) along with quarter-period symmetries.
	"""
	if prec > COS_SIN_CACHE_PREC:
	return exponential_series(x, prec, 2)
	precs = prec - COS_SIN_CACHE_STEP
	t = x >> precs
	n = int(t)
	if n not in cos_sin_cache:
	w = t<<(10+COS_SIN_CACHE_PREC-COS_SIN_CACHE_STEP)
	cos_t, sin_t = exponential_series(w, 10+COS_SIN_CACHE_PREC, 2)
	cos_sin_cache[n] = (cos_t>>10), (sin_t>>10)
	cos_t, sin_t = cos_sin_cache[n]
	offset = COS_SIN_CACHE_PREC - prec
	cos_t >>= offset
	sin_t >>= offset
	x -= t << precs
	cos = MPZ_ONE << prec
	sin = x
	k = 2
	a = -((x*x) >> prec)
	while a:
	a //= k; cos += a; k += 1; a = (a*x) >> prec
	a //= k; sin += a; k += 1; a = -((a*x) >> prec)
	return ((coscos_t-sinsin_t) >> prec), ((sincos_t+cossin_t) >> prec)

	def mpf_exp(x, prec, rnd=round_fast):
	sign, man, exp, bc = x
	if man:
	mag = bc + exp
	wp = prec + 14
	if sign:
	man = -man
	# TODO: the best cutoff depends on both x and the precision.
	if prec > 600 and exp >= 0:
	# Need about log2(exp(n)) ~= 1.45*mag extra precision
	e = mpf_e(wp+int(1.45*mag))
	return mpf_pow_int(e, man<<exp, prec, rnd)
	if mag < -wp:
	return mpf_perturb(fone, sign, prec, rnd)
	# \|x\| >= 2
	if mag > 1:
	# For large arguments: exp(2^mag*(1+eps)) =
	# exp(2^mag)exp(2^mageps) = exp(2^mag)(1 + 2^mageps + ...)
	# so about mag extra bits is required.
	wpmod = wp + mag
	offset = exp + wpmod
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	lg2 = ln2_fixed(wpmod)
	n, t = divmod(t, lg2)
	n = int(n)
	t >>= mag
	else:
	offset = exp + wp
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	n = 0
	man = exp_basecase(t, wp)
	return from_man_exp(man, n-wp, prec, rnd)
	if not exp:
	return fone
	if x == fninf:
	return fzero
	return x


	def mpf_cosh_sinh(x, prec, rnd=round_fast, tanh=0):
	"""Simultaneously compute (cosh(x), sinh(x)) for real x"""
	sign, man, exp, bc = x
	if (not man) and exp:
	if tanh:
	if x == finf: return fone
	if x == fninf: return fnone
	return fnan
	if x == finf: return (finf, finf)
	if x == fninf: return (finf, fninf)
	return fnan, fnan
	mag = exp+bc
	wp = prec+14
	if mag < -4:
	# Extremely close to 0, sinh(x) ~= x and cosh(x) ~= 1
	if mag < -wp:
	if tanh:
	return mpf_perturb(x, 1-sign, prec, rnd)
	cosh = mpf_perturb(fone, 0, prec, rnd)
	sinh = mpf_perturb(x, sign, prec, rnd)
	return cosh, sinh
	# Fix for cancellation when computing sinh
	wp += (-mag)
	# Does exp(-2*x) vanish?
	if mag > 10:
	if 3*(1<<(mag-1)) > wp:
	# XXX: rounding
	if tanh:
	return mpf_perturb([fone,fnone][sign], 1-sign, prec, rnd)
	c = s = mpf_shift(mpf_exp(mpf_abs(x), prec, rnd), -1)
	if sign:
	s = mpf_neg(s)
	return c, s
	# \|x\| > 1
	if mag > 1:
	wpmod = wp + mag
	offset = exp + wpmod
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	lg2 = ln2_fixed(wpmod)
	n, t = divmod(t, lg2)
	n = int(n)
	t >>= mag
	else:
	offset = exp + wp
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	n = 0
	a, b = exp_expneg_basecase(t, wp)
	# TODO: optimize division precision
	cosh = a + (b>>(2*n))
	sinh = a - (b>>(2*n))
	if sign:
	sinh = -sinh
	if tanh:
	man = (sinh << wp) // cosh
	return from_man_exp(man, -wp, prec, rnd)
	else:
	cosh = from_man_exp(cosh, n-wp-1, prec, rnd)
	sinh = from_man_exp(sinh, n-wp-1, prec, rnd)
	return cosh, sinh


	def mod_pi2(man, exp, mag, wp):
	# Reduce to standard interval
	if mag > 0:
	i = 0
	while 1:
	cancellation_prec = 20 << i
	wpmod = wp + mag + cancellation_prec
	pi2 = pi_fixed(wpmod-1)
	pi4 = pi2 >> 1
	offset = wpmod + exp
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	n, y = divmod(t, pi2)
	if y > pi4:
	small = pi2 - y
	else:
	small = y
	if small >> (wp+mag-10):
	n = int(n)
	t = y >> mag
	wp = wpmod - mag
	break
	i += 1
	else:
	wp += (-mag)
	offset = exp + wp
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	n = 0
	return t, n, wp


	def mpf_cos_sin(x, prec, rnd=round_fast, which=0, pi=False):
	"""
	which:
	0 -- return cos(x), sin(x)
	1 -- return cos(x)
	2 -- return sin(x)
	3 -- return tan(x)

	if pi=True, compute for pi*x
	"""
	sign, man, exp, bc = x
	if not man:
	if exp:
	c, s = fnan, fnan
	else:
	c, s = fone, fzero
	if which == 0: return c, s
	if which == 1: return c
	if which == 2: return s
	if which == 3: return s

	mag = bc + exp
	wp = prec + 10

	# Extremely small?
	if mag < 0:
	if mag < -wp:
	if pi:
	x = mpf_mul(x, mpf_pi(wp))
	c = mpf_perturb(fone, 1, prec, rnd)
	s = mpf_perturb(x, 1-sign, prec, rnd)
	if which == 0: return c, s
	if which == 1: return c
	if which == 2: return s
	if which == 3: return mpf_perturb(x, sign, prec, rnd)
	if pi:
	if exp >= -1:
	if exp == -1:
	c = fzero
	s = (fone, fnone)[bool(man & 2) ^ sign]
	elif exp == 0:
	c, s = (fnone, fzero)
	else:
	c, s = (fone, fzero)
	if which == 0: return c, s
	if which == 1: return c
	if which == 2: return s
	if which == 3: return mpf_div(s, c, prec, rnd)
	# Subtract nearest half-integer (= mod by pi/2)
	n = ((man >> (-exp-2)) + 1) >> 1
	man = man - (n << (-exp-1))
	mag2 = bitcount(man) + exp
	wp = prec + 10 - mag2
	offset = exp + wp
	if offset >= 0:
	t = man << offset
	else:
	t = man >> (-offset)
	t = (t*pi_fixed(wp)) >> wp
	else:
	t, n, wp = mod_pi2(man, exp, mag, wp)
	c, s = cos_sin_basecase(t, wp)
	m = n & 3
	if m == 1: c, s = -s, c
	elif m == 2: c, s = -c, -s
	elif m == 3: c, s = s, -c
	if sign:
	s = -s
	if which == 0:
	c = from_man_exp(c, -wp, prec, rnd)
	s = from_man_exp(s, -wp, prec, rnd)
	return c, s
	if which == 1:
	return from_man_exp(c, -wp, prec, rnd)
	if which == 2:
	return from_man_exp(s, -wp, prec, rnd)
	if which == 3:
	return from_rational(s, c, prec, rnd)

	def mpf_cos(x, prec, rnd=round_fast): return mpf_cos_sin(x, prec, rnd, 1)
	def mpf_sin(x, prec, rnd=round_fast): return mpf_cos_sin(x, prec, rnd, 2)
	def mpf_tan(x, prec, rnd=round_fast): return mpf_cos_sin(x, prec, rnd, 3)
	def mpf_cos_sin_pi(x, prec, rnd=round_fast): return mpf_cos_sin(x, prec, rnd, 0, 1)
	def mpf_cos_pi(x, prec, rnd=round_fast): return mpf_cos_sin(x, prec, rnd, 1, 1)
	def mpf_sin_pi(x, prec, rnd=round_fast): return mpf_cos_sin(x, prec, rnd, 2, 1)
	def mpf_cosh(x, prec, rnd=round_fast): return mpf_cosh_sinh(x, prec, rnd)[0]
	def mpf_sinh(x, prec, rnd=round_fast): return mpf_cosh_sinh(x, prec, rnd)[1]
	def mpf_tanh(x, prec, rnd=round_fast): return mpf_cosh_sinh(x, prec, rnd, tanh=1)


	# Low-overhead fixed-point versions

	def cos_sin_fixed(x, prec, pi2=None):
	if pi2 is None:
	pi2 = pi_fixed(prec-1)
	n, t = divmod(x, pi2)
	n = int(n)
	c, s = cos_sin_basecase(t, prec)
	m = n & 3
	if m == 0: return c, s
	if m == 1: return -s, c
	if m == 2: return -c, -s
	if m == 3: return s, -c

	def exp_fixed(x, prec, ln2=None):
	if ln2 is None:
	ln2 = ln2_fixed(prec)
	n, t = divmod(x, ln2)
	n = int(n)
	v = exp_basecase(t, prec)
	if n >= 0:
	return v << n
	else:
	return v >> (-n)


	if BACKEND == 'sage':
	try:
	import sage.libs.mpmath.ext_libmp as _lbmp
	mpf_sqrt = _lbmp.mpf_sqrt
	mpf_exp = _lbmp.mpf_exp
	mpf_log = _lbmp.mpf_log
	mpf_cos = _lbmp.mpf_cos
	mpf_sin = _lbmp.mpf_sin
	mpf_pow = _lbmp.mpf_pow
	exp_fixed = _lbmp.exp_fixed
	cos_sin_fixed = _lbmp.cos_sin_fixed
	log_int_fixed = _lbmp.log_int_fixed
	except (ImportError, AttributeError):
	print("Warning: Sage imports in libelefun failed")