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	"""
	Computational functions for interval arithmetic.

	"""

	from .backend import xrange

	from .libmpf import (
	ComplexResult,
	round_down, round_up, round_floor, round_ceiling, round_nearest,
	prec_to_dps, repr_dps, dps_to_prec,
	bitcount,
	from_float,
	fnan, finf, fninf, fzero, fhalf, fone, fnone,
	mpf_sign, mpf_lt, mpf_le, mpf_gt, mpf_ge, mpf_eq, mpf_cmp,
	mpf_min_max,
	mpf_floor, from_int, to_int, to_str, from_str,
	mpf_abs, mpf_neg, mpf_pos, mpf_add, mpf_sub, mpf_mul, mpf_mul_int,
	mpf_div, mpf_shift, mpf_pow_int,
	from_man_exp, MPZ_ONE)

	from .libelefun import (
	mpf_log, mpf_exp, mpf_sqrt, mpf_atan, mpf_atan2,
	mpf_pi, mod_pi2, mpf_cos_sin
	)

	from .gammazeta import mpf_gamma, mpf_rgamma, mpf_loggamma, mpc_loggamma

	def mpi_str(s, prec):
	sa, sb = s
	dps = prec_to_dps(prec) + 5
	return "[%s, %s]" % (to_str(sa, dps), to_str(sb, dps))
	#dps = prec_to_dps(prec)
	#m = mpi_mid(s, prec)
	#d = mpf_shift(mpi_delta(s, 20), -1)
	#return "%s +/- %s" % (to_str(m, dps), to_str(d, 3))

	mpi_zero = (fzero, fzero)
	mpi_one = (fone, fone)

	def mpi_eq(s, t):
	return s == t

	def mpi_ne(s, t):
	return s != t

	def mpi_lt(s, t):
	sa, sb = s
	ta, tb = t
	if mpf_lt(sb, ta): return True
	if mpf_ge(sa, tb): return False
	return None

	def mpi_le(s, t):
	sa, sb = s
	ta, tb = t
	if mpf_le(sb, ta): return True
	if mpf_gt(sa, tb): return False
	return None

	def mpi_gt(s, t): return mpi_lt(t, s)
	def mpi_ge(s, t): return mpi_le(t, s)

	def mpi_add(s, t, prec=0):
	sa, sb = s
	ta, tb = t
	a = mpf_add(sa, ta, prec, round_floor)
	b = mpf_add(sb, tb, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = finf
	return a, b

	def mpi_sub(s, t, prec=0):
	sa, sb = s
	ta, tb = t
	a = mpf_sub(sa, tb, prec, round_floor)
	b = mpf_sub(sb, ta, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = finf
	return a, b

	def mpi_delta(s, prec):
	sa, sb = s
	return mpf_sub(sb, sa, prec, round_up)

	def mpi_mid(s, prec):
	sa, sb = s
	return mpf_shift(mpf_add(sa, sb, prec, round_nearest), -1)

	def mpi_pos(s, prec):
	sa, sb = s
	a = mpf_pos(sa, prec, round_floor)
	b = mpf_pos(sb, prec, round_ceiling)
	return a, b

	def mpi_neg(s, prec=0):
	sa, sb = s
	a = mpf_neg(sb, prec, round_floor)
	b = mpf_neg(sa, prec, round_ceiling)
	return a, b

	def mpi_abs(s, prec=0):
	sa, sb = s
	sas = mpf_sign(sa)
	sbs = mpf_sign(sb)
	# Both points nonnegative?
	if sas >= 0:
	a = mpf_pos(sa, prec, round_floor)
	b = mpf_pos(sb, prec, round_ceiling)
	# Upper point nonnegative?
	elif sbs >= 0:
	a = fzero
	negsa = mpf_neg(sa)
	if mpf_lt(negsa, sb):
	b = mpf_pos(sb, prec, round_ceiling)
	else:
	b = mpf_pos(negsa, prec, round_ceiling)
	# Both negative?
	else:
	a = mpf_neg(sb, prec, round_floor)
	b = mpf_neg(sa, prec, round_ceiling)
	return a, b

	# TODO: optimize
	def mpi_mul_mpf(s, t, prec):
	return mpi_mul(s, (t, t), prec)

	def mpi_div_mpf(s, t, prec):
	return mpi_div(s, (t, t), prec)

	def mpi_mul(s, t, prec=0):
	sa, sb = s
	ta, tb = t
	sas = mpf_sign(sa)
	sbs = mpf_sign(sb)
	tas = mpf_sign(ta)
	tbs = mpf_sign(tb)
	if sas == sbs == 0:
	# Should maybe be undefined
	if ta == fninf or tb == finf:
	return fninf, finf
	return fzero, fzero
	if tas == tbs == 0:
	# Should maybe be undefined
	if sa == fninf or sb == finf:
	return fninf, finf
	return fzero, fzero
	if sas >= 0:
	# positive * positive
	if tas >= 0:
	a = mpf_mul(sa, ta, prec, round_floor)
	b = mpf_mul(sb, tb, prec, round_ceiling)
	if a == fnan: a = fzero
	if b == fnan: b = finf
	# positive * negative
	elif tbs <= 0:
	a = mpf_mul(sb, ta, prec, round_floor)
	b = mpf_mul(sa, tb, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = fzero
	# positive * both signs
	else:
	a = mpf_mul(sb, ta, prec, round_floor)
	b = mpf_mul(sb, tb, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = finf
	elif sbs <= 0:
	# negative * positive
	if tas >= 0:
	a = mpf_mul(sa, tb, prec, round_floor)
	b = mpf_mul(sb, ta, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = fzero
	# negative * negative
	elif tbs <= 0:
	a = mpf_mul(sb, tb, prec, round_floor)
	b = mpf_mul(sa, ta, prec, round_ceiling)
	if a == fnan: a = fzero
	if b == fnan: b = finf
	# negative * both signs
	else:
	a = mpf_mul(sa, tb, prec, round_floor)
	b = mpf_mul(sa, ta, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = finf
	else:
	# General case: perform all cross-multiplications and compare
	# Since the multiplications can be done exactly, we need only
	# do 4 (instead of 8: two for each rounding mode)
	cases = [mpf_mul(sa, ta), mpf_mul(sa, tb), mpf_mul(sb, ta), mpf_mul(sb, tb)]
	if fnan in cases:
	a, b = (fninf, finf)
	else:
	a, b = mpf_min_max(cases)
	a = mpf_pos(a, prec, round_floor)
	b = mpf_pos(b, prec, round_ceiling)
	return a, b

	def mpi_square(s, prec=0):
	sa, sb = s
	if mpf_ge(sa, fzero):
	a = mpf_mul(sa, sa, prec, round_floor)
	b = mpf_mul(sb, sb, prec, round_ceiling)
	elif mpf_le(sb, fzero):
	a = mpf_mul(sb, sb, prec, round_floor)
	b = mpf_mul(sa, sa, prec, round_ceiling)
	else:
	sa = mpf_neg(sa)
	sa, sb = mpf_min_max([sa, sb])
	a = fzero
	b = mpf_mul(sb, sb, prec, round_ceiling)
	return a, b

	def mpi_div(s, t, prec):
	sa, sb = s
	ta, tb = t
	sas = mpf_sign(sa)
	sbs = mpf_sign(sb)
	tas = mpf_sign(ta)
	tbs = mpf_sign(tb)
	# 0 / X
	if sas == sbs == 0:
	# 0 / <interval containing 0>
	if (tas < 0 and tbs > 0) or (tas == 0 or tbs == 0):
	return fninf, finf
	return fzero, fzero
	# Denominator contains both negative and positive numbers;
	# this should properly be a multi-interval, but the closest
	# match is the entire (extended) real line
	if tas < 0 and tbs > 0:
	return fninf, finf
	# Assume denominator to be nonnegative
	if tas < 0:
	return mpi_div(mpi_neg(s), mpi_neg(t), prec)
	# Division by zero
	# XXX: make sure all results make sense
	if tas == 0:
	# Numerator contains both signs?
	if sas < 0 and sbs > 0:
	return fninf, finf
	if tas == tbs:
	return fninf, finf
	# Numerator positive?
	if sas >= 0:
	a = mpf_div(sa, tb, prec, round_floor)
	b = finf
	if sbs <= 0:
	a = fninf
	b = mpf_div(sb, tb, prec, round_ceiling)
	# Division with positive denominator
	# We still have to handle nans resulting from inf/0 or inf/inf
	else:
	# Nonnegative numerator
	if sas >= 0:
	a = mpf_div(sa, tb, prec, round_floor)
	b = mpf_div(sb, ta, prec, round_ceiling)
	if a == fnan: a = fzero
	if b == fnan: b = finf
	# Nonpositive numerator
	elif sbs <= 0:
	a = mpf_div(sa, ta, prec, round_floor)
	b = mpf_div(sb, tb, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = fzero
	# Numerator contains both signs?
	else:
	a = mpf_div(sa, ta, prec, round_floor)
	b = mpf_div(sb, ta, prec, round_ceiling)
	if a == fnan: a = fninf
	if b == fnan: b = finf
	return a, b

	def mpi_pi(prec):
	a = mpf_pi(prec, round_floor)
	b = mpf_pi(prec, round_ceiling)
	return a, b

	def mpi_exp(s, prec):
	sa, sb = s
	# exp is monotonic
	a = mpf_exp(sa, prec, round_floor)
	b = mpf_exp(sb, prec, round_ceiling)
	return a, b

	def mpi_log(s, prec):
	sa, sb = s
	# log is monotonic
	a = mpf_log(sa, prec, round_floor)
	b = mpf_log(sb, prec, round_ceiling)
	return a, b

	def mpi_sqrt(s, prec):
	sa, sb = s
	# sqrt is monotonic
	a = mpf_sqrt(sa, prec, round_floor)
	b = mpf_sqrt(sb, prec, round_ceiling)
	return a, b

	def mpi_atan(s, prec):
	sa, sb = s
	a = mpf_atan(sa, prec, round_floor)
	b = mpf_atan(sb, prec, round_ceiling)
	return a, b

	def mpi_pow_int(s, n, prec):
	sa, sb = s
	if n < 0:
	return mpi_div((fone, fone), mpi_pow_int(s, -n, prec+20), prec)
	if n == 0:
	return (fone, fone)
	if n == 1:
	return s
	if n == 2:
	return mpi_square(s, prec)
	# Odd -- signs are preserved
	if n & 1:
	a = mpf_pow_int(sa, n, prec, round_floor)
	b = mpf_pow_int(sb, n, prec, round_ceiling)
	# Even -- important to ensure positivity
	else:
	sas = mpf_sign(sa)
	sbs = mpf_sign(sb)
	# Nonnegative?
	if sas >= 0:
	a = mpf_pow_int(sa, n, prec, round_floor)
	b = mpf_pow_int(sb, n, prec, round_ceiling)
	# Nonpositive?
	elif sbs <= 0:
	a = mpf_pow_int(sb, n, prec, round_floor)
	b = mpf_pow_int(sa, n, prec, round_ceiling)
	# Mixed signs?
	else:
	a = fzero
	# max(-a,b)**n
	sa = mpf_neg(sa)
	if mpf_ge(sa, sb):
	b = mpf_pow_int(sa, n, prec, round_ceiling)
	else:
	b = mpf_pow_int(sb, n, prec, round_ceiling)
	return a, b

	def mpi_pow(s, t, prec):
	ta, tb = t
	if ta == tb and ta not in (finf, fninf):
	if ta == from_int(to_int(ta)):
	return mpi_pow_int(s, to_int(ta), prec)
	if ta == fhalf:
	return mpi_sqrt(s, prec)
	u = mpi_log(s, prec + 20)
	v = mpi_mul(u, t, prec + 20)
	return mpi_exp(v, prec)

	def MIN(x, y):
	if mpf_le(x, y):
	return x
	return y

	def MAX(x, y):
	if mpf_ge(x, y):
	return x
	return y

	def cos_sin_quadrant(x, wp):
	sign, man, exp, bc = x
	if x == fzero:
	return fone, fzero, 0
	# TODO: combine evaluation code to avoid duplicate modulo
	c, s = mpf_cos_sin(x, wp)
	t, n, wp_ = mod_pi2(man, exp, exp+bc, 15)
	if sign:
	n = -1-n
	return c, s, n

	def mpi_cos_sin(x, prec):
	a, b = x
	if a == b == fzero:
	return (fone, fone), (fzero, fzero)
	# Guaranteed to contain both -1 and 1
	if (finf in x) or (fninf in x):
	return (fnone, fone), (fnone, fone)
	wp = prec + 20
	ca, sa, na = cos_sin_quadrant(a, wp)
	cb, sb, nb = cos_sin_quadrant(b, wp)
	ca, cb = mpf_min_max([ca, cb])
	sa, sb = mpf_min_max([sa, sb])
	# Both functions are monotonic within one quadrant
	if na == nb:
	pass
	# Guaranteed to contain both -1 and 1
	elif nb - na >= 4:
	return (fnone, fone), (fnone, fone)
	else:
	# cos has maximum between a and b
	if na//4 != nb//4:
	cb = fone
	# cos has minimum
	if (na-2)//4 != (nb-2)//4:
	ca = fnone
	# sin has maximum
	if (na-1)//4 != (nb-1)//4:
	sb = fone
	# sin has minimum
	if (na-3)//4 != (nb-3)//4:
	sa = fnone
	# Perturb to force interval rounding
	more = from_man_exp((MPZ_ONE<<wp) + (MPZ_ONE<<10), -wp)
	less = from_man_exp((MPZ_ONE<<wp) - (MPZ_ONE<<10), -wp)
	def finalize(v, rounding):
	if bool(v[0]) == (rounding == round_floor):
	p = more
	else:
	p = less
	v = mpf_mul(v, p, prec, rounding)
	sign, man, exp, bc = v
	if exp+bc >= 1:
	if sign:
	return fnone
	return fone
	return v
	ca = finalize(ca, round_floor)
	cb = finalize(cb, round_ceiling)
	sa = finalize(sa, round_floor)
	sb = finalize(sb, round_ceiling)
	return (ca,cb), (sa,sb)

	def mpi_cos(x, prec):
	return mpi_cos_sin(x, prec)[0]

	def mpi_sin(x, prec):
	return mpi_cos_sin(x, prec)[1]

	def mpi_tan(x, prec):
	cos, sin = mpi_cos_sin(x, prec+20)
	return mpi_div(sin, cos, prec)

	def mpi_cot(x, prec):
	cos, sin = mpi_cos_sin(x, prec+20)
	return mpi_div(cos, sin, prec)

	def mpi_from_str_a_b(x, y, percent, prec):
	wp = prec + 20
	xa = from_str(x, wp, round_floor)
	xb = from_str(x, wp, round_ceiling)
	#ya = from_str(y, wp, round_floor)
	y = from_str(y, wp, round_ceiling)
	assert mpf_ge(y, fzero)
	if percent:
	y = mpf_mul(MAX(mpf_abs(xa), mpf_abs(xb)), y, wp, round_ceiling)
	y = mpf_div(y, from_int(100), wp, round_ceiling)
	a = mpf_sub(xa, y, prec, round_floor)
	b = mpf_add(xb, y, prec, round_ceiling)
	return a, b

	def mpi_from_str(s, prec):
	"""
	Parse an interval number given as a string.

	Allowed forms are

	"-1.23e-27"
	Any single decimal floating-point literal.
	"a +- b" or "a (b)"
	a is the midpoint of the interval and b is the half-width
	"a +- b%" or "a (b%)"
	a is the midpoint of the interval and the half-width
	is b percent of a (`a \times b / 100`).
	"[a, b]"
	The interval indicated directly.
	"x[y,z]e"
	x are shared digits, y and z are unequal digits, e is the exponent.

	"""
	e = ValueError("Improperly formed interval number '%s'" % s)
	s = s.replace(" ", "")
	wp = prec + 20
	if "+-" in s:
	x, y = s.split("+-")
	return mpi_from_str_a_b(x, y, False, prec)
	# case 2
	elif "(" in s:
	# Don't confuse with a complex number (x,y)
	if s[0] == "(" or ")" not in s:
	raise e
	s = s.replace(")", "")
	percent = False
	if "%" in s:
	if s[-1] != "%":
	raise e
	percent = True
	s = s.replace("%", "")
	x, y = s.split("(")
	return mpi_from_str_a_b(x, y, percent, prec)
	elif "," in s:
	if ('[' not in s) or (']' not in s):
	raise e
	if s[0] == '[':
	# case 3
	s = s.replace("[", "")
	s = s.replace("]", "")
	a, b = s.split(",")
	a = from_str(a, prec, round_floor)
	b = from_str(b, prec, round_ceiling)
	return a, b
	else:
	# case 4
	x, y = s.split('[')
	y, z = y.split(',')
	if 'e' in s:
	z, e = z.split(']')
	else:
	z, e = z.rstrip(']'), ''
	a = from_str(x+y+e, prec, round_floor)
	b = from_str(x+z+e, prec, round_ceiling)
	return a, b
	else:
	a = from_str(s, prec, round_floor)
	b = from_str(s, prec, round_ceiling)
	return a, b

	def mpi_to_str(x, dps, use_spaces=True, brackets='[]', mode='brackets', error_dps=4, **kwargs):
	"""
	Convert a mpi interval to a string.

	Arguments

	dps
	decimal places to use for printing
	use_spaces
	use spaces for more readable output, defaults to true
	brackets
	pair of strings (or two-character string) giving left and right brackets
	mode
	mode of display: 'plusminus', 'percent', 'brackets' (default) or 'diff'
	error_dps
	limit the error to error_dps digits (mode 'plusminus and 'percent')

	Additional keyword arguments are forwarded to the mpf-to-string conversion
	for the components of the output.

	Examples

	>>> from mpmath import mpi, mp
	>>> mp.dps = 30
	>>> x = mpi(1, 2)._mpi_
	>>> mpi_to_str(x, 2, mode='plusminus')
	'1.5 +- 0.5'
	>>> mpi_to_str(x, 2, mode='percent')
	'1.5 (33.33%)'
	>>> mpi_to_str(x, 2, mode='brackets')
	'[1.0, 2.0]'
	>>> mpi_to_str(x, 2, mode='brackets' , brackets=('<', '>'))
	'<1.0, 2.0>'
	>>> x = mpi('5.2582327113062393041', '5.2582327113062749951')._mpi_
	>>> mpi_to_str(x, 15, mode='diff')
	'5.2582327113062[4, 7]'
	>>> mpi_to_str(mpi(0)._mpi_, 2, mode='percent')
	'0.0 (0.0%)'

	"""
	prec = dps_to_prec(dps)
	wp = prec + 20
	a, b = x
	mid = mpi_mid(x, prec)
	delta = mpi_delta(x, prec)
	a_str = to_str(a, dps, **kwargs)
	b_str = to_str(b, dps, **kwargs)
	mid_str = to_str(mid, dps, **kwargs)
	sp = ""
	if use_spaces:
	sp = " "
	br1, br2 = brackets
	if mode == 'plusminus':
	delta_str = to_str(mpf_shift(delta,-1), dps, **kwargs)
	s = mid_str + sp + "+-" + sp + delta_str
	elif mode == 'percent':
	if mid == fzero:
	p = fzero
	else:
	# p = 100 * delta(x) / (2*mid(x))
	p = mpf_mul(delta, from_int(100))
	p = mpf_div(p, mpf_mul(mid, from_int(2)), wp)
	s = mid_str + sp + "(" + to_str(p, error_dps) + "%)"
	elif mode == 'brackets':
	s = br1 + a_str + "," + sp + b_str + br2
	elif mode == 'diff':
	# use more digits if str(x.a) and str(x.b) are equal
	if a_str == b_str:
	a_str = to_str(a, dps+3, **kwargs)
	b_str = to_str(b, dps+3, **kwargs)
	# separate mantissa and exponent
	a = a_str.split('e')
	if len(a) == 1:
	a.append('')
	b = b_str.split('e')
	if len(b) == 1:
	b.append('')
	if a[1] == b[1]:
	if a[0] != b[0]:
	for i in xrange(len(a[0]) + 1):
	if a[0][i] != b[0][i]:
	break
	s = (a[0][:i] + br1 + a[0][i:] + ',' + sp + b[0][i:] + br2
	+ 'e'*min(len(a[1]), 1) + a[1])
	else: # no difference
	s = a[0] + br1 + br2 + 'e'*min(len(a[1]), 1) + a[1]
	else:
	s = br1 + 'e'.join(a) + ',' + sp + 'e'.join(b) + br2
	else:
	raise ValueError("'%s' is unknown mode for printing mpi" % mode)
	return s

	def mpci_add(x, y, prec):
	a, b = x
	c, d = y
	return mpi_add(a, c, prec), mpi_add(b, d, prec)

	def mpci_sub(x, y, prec):
	a, b = x
	c, d = y
	return mpi_sub(a, c, prec), mpi_sub(b, d, prec)

	def mpci_neg(x, prec=0):
	a, b = x
	return mpi_neg(a, prec), mpi_neg(b, prec)

	def mpci_pos(x, prec):
	a, b = x
	return mpi_pos(a, prec), mpi_pos(b, prec)

	def mpci_mul(x, y, prec):
	# TODO: optimize for real/imag cases
	a, b = x
	c, d = y
	r1 = mpi_mul(a,c)
	r2 = mpi_mul(b,d)
	re = mpi_sub(r1,r2,prec)
	i1 = mpi_mul(a,d)
	i2 = mpi_mul(b,c)
	im = mpi_add(i1,i2,prec)
	return re, im

	def mpci_div(x, y, prec):
	# TODO: optimize for real/imag cases
	a, b = x
	c, d = y
	wp = prec+20
	m1 = mpi_square(c)
	m2 = mpi_square(d)
	m = mpi_add(m1,m2,wp)
	re = mpi_add(mpi_mul(a,c), mpi_mul(b,d), wp)
	im = mpi_sub(mpi_mul(b,c), mpi_mul(a,d), wp)
	re = mpi_div(re, m, prec)
	im = mpi_div(im, m, prec)
	return re, im

	def mpci_exp(x, prec):
	a, b = x
	wp = prec+20
	r = mpi_exp(a, wp)
	c, s = mpi_cos_sin(b, wp)
	a = mpi_mul(r, c, prec)
	b = mpi_mul(r, s, prec)
	return a, b

	def mpi_shift(x, n):
	a, b = x
	return mpf_shift(a,n), mpf_shift(b,n)

	def mpi_cosh_sinh(x, prec):
	# TODO: accuracy for small x
	wp = prec+20
	e1 = mpi_exp(x, wp)
	e2 = mpi_div(mpi_one, e1, wp)
	c = mpi_add(e1, e2, prec)
	s = mpi_sub(e1, e2, prec)
	c = mpi_shift(c, -1)
	s = mpi_shift(s, -1)
	return c, s

	def mpci_cos(x, prec):
	a, b = x
	wp = prec+10
	c, s = mpi_cos_sin(a, wp)
	ch, sh = mpi_cosh_sinh(b, wp)
	re = mpi_mul(c, ch, prec)
	im = mpi_mul(s, sh, prec)
	return re, mpi_neg(im)

	def mpci_sin(x, prec):
	a, b = x
	wp = prec+10
	c, s = mpi_cos_sin(a, wp)
	ch, sh = mpi_cosh_sinh(b, wp)
	re = mpi_mul(s, ch, prec)
	im = mpi_mul(c, sh, prec)
	return re, im

	def mpci_abs(x, prec):
	a, b = x
	if a == mpi_zero:
	return mpi_abs(b)
	if b == mpi_zero:
	return mpi_abs(a)
	# Important: nonnegative
	a = mpi_square(a)
	b = mpi_square(b)
	t = mpi_add(a, b, prec+20)
	return mpi_sqrt(t, prec)

	def mpi_atan2(y, x, prec):
	ya, yb = y
	xa, xb = x
	# Constrained to the real line
	if ya == yb == fzero:
	if mpf_ge(xa, fzero):
	return mpi_zero
	return mpi_pi(prec)
	# Right half-plane
	if mpf_ge(xa, fzero):
	if mpf_ge(ya, fzero):
	a = mpf_atan2(ya, xb, prec, round_floor)
	else:
	a = mpf_atan2(ya, xa, prec, round_floor)
	if mpf_ge(yb, fzero):
	b = mpf_atan2(yb, xa, prec, round_ceiling)
	else:
	b = mpf_atan2(yb, xb, prec, round_ceiling)
	# Upper half-plane
	elif mpf_ge(ya, fzero):
	b = mpf_atan2(ya, xa, prec, round_ceiling)
	if mpf_le(xb, fzero):
	a = mpf_atan2(yb, xb, prec, round_floor)
	else:
	a = mpf_atan2(ya, xb, prec, round_floor)
	# Lower half-plane
	elif mpf_le(yb, fzero):
	a = mpf_atan2(yb, xa, prec, round_floor)
	if mpf_le(xb, fzero):
	b = mpf_atan2(ya, xb, prec, round_ceiling)
	else:
	b = mpf_atan2(yb, xb, prec, round_ceiling)
	# Covering the origin
	else:
	b = mpf_pi(prec, round_ceiling)
	a = mpf_neg(b)
	return a, b

	def mpci_arg(z, prec):
	x, y = z
	return mpi_atan2(y, x, prec)

	def mpci_log(z, prec):
	x, y = z
	re = mpi_log(mpci_abs(z, prec+20), prec)
	im = mpci_arg(z, prec)
	return re, im

	def mpci_pow(x, y, prec):
	# TODO: recognize/speed up real cases, integer y
	yre, yim = y
	if yim == mpi_zero:
	ya, yb = yre
	if ya == yb:
	sign, man, exp, bc = yb
	if man and exp >= 0:
	return mpci_pow_int(x, (-1)*sign int(man<<exp), prec)
	# x^0
	if yb == fzero:
	return mpci_pow_int(x, 0, prec)
	wp = prec+20
	return mpci_exp(mpci_mul(y, mpci_log(x, wp), wp), prec)

	def mpci_square(x, prec):
	a, b = x
	# (a+bi)^2 = (a^2-b^2) + 2abi
	re = mpi_sub(mpi_square(a), mpi_square(b), prec)
	im = mpi_mul(a, b, prec)
	im = mpi_shift(im, 1)
	return re, im

	def mpci_pow_int(x, n, prec):
	if n < 0:
	return mpci_div((mpi_one,mpi_zero), mpci_pow_int(x, -n, prec+20), prec)
	if n == 0:
	return mpi_one, mpi_zero
	if n == 1:
	return mpci_pos(x, prec)
	if n == 2:
	return mpci_square(x, prec)
	wp = prec + 20
	result = (mpi_one, mpi_zero)
	while n:
	if n & 1:
	result = mpci_mul(result, x, wp)
	n -= 1
	x = mpci_square(x, wp)
	n >>= 1
	return mpci_pos(result, prec)

	gamma_min_a = from_float(1.46163214496)
	gamma_min_b = from_float(1.46163214497)
	gamma_min = (gamma_min_a, gamma_min_b)
	gamma_mono_imag_a = from_float(-1.1)
	gamma_mono_imag_b = from_float(1.1)

	def mpi_overlap(x, y):
	a, b = x
	c, d = y
	if mpf_lt(d, a): return False
	if mpf_gt(c, b): return False
	return True

	# type = 0 -- gamma
	# type = 1 -- factorial
	# type = 2 -- 1/gamma
	# type = 3 -- log-gamma

	def mpi_gamma(z, prec, type=0):
	a, b = z
	wp = prec+20

	if type == 1:
	return mpi_gamma(mpi_add(z, mpi_one, wp), prec, 0)

	# increasing
	if mpf_gt(a, gamma_min_b):
	if type == 0:
	c = mpf_gamma(a, prec, round_floor)
	d = mpf_gamma(b, prec, round_ceiling)
	elif type == 2:
	c = mpf_rgamma(b, prec, round_floor)
	d = mpf_rgamma(a, prec, round_ceiling)
	elif type == 3:
	c = mpf_loggamma(a, prec, round_floor)
	d = mpf_loggamma(b, prec, round_ceiling)
	# decreasing
	elif mpf_gt(a, fzero) and mpf_lt(b, gamma_min_a):
	if type == 0:
	c = mpf_gamma(b, prec, round_floor)
	d = mpf_gamma(a, prec, round_ceiling)
	elif type == 2:
	c = mpf_rgamma(a, prec, round_floor)
	d = mpf_rgamma(b, prec, round_ceiling)
	elif type == 3:
	c = mpf_loggamma(b, prec, round_floor)
	d = mpf_loggamma(a, prec, round_ceiling)
	else:
	# TODO: reflection formula
	znew = mpi_add(z, mpi_one, wp)
	if type == 0: return mpi_div(mpi_gamma(znew, prec+2, 0), z, prec)
	if type == 2: return mpi_mul(mpi_gamma(znew, prec+2, 2), z, prec)
	if type == 3: return mpi_sub(mpi_gamma(znew, prec+2, 3), mpi_log(z, prec+2), prec)
	return c, d

	def mpci_gamma(z, prec, type=0):
	(a1,a2), (b1,b2) = z

	# Real case
	if b1 == b2 == fzero and (type != 3 or mpf_gt(a1,fzero)):
	return mpi_gamma(z, prec, type), mpi_zero

	# Estimate precision
	wp = prec+20
	if type != 3:
	amag = a2[2]+a2[3]
	bmag = b2[2]+b2[3]
	if a2 != fzero:
	mag = max(amag, bmag)
	else:
	mag = bmag
	an = abs(to_int(a2))
	bn = abs(to_int(b2))
	absn = max(an, bn)
	gamma_size = max(0,absn*mag)
	wp += bitcount(gamma_size)

	# Assume type != 1
	if type == 1:
	(a1,a2) = mpi_add((a1,a2), mpi_one, wp); z = (a1,a2), (b1,b2)
	type = 0

	# Avoid non-monotonic region near the negative real axis
	if mpf_lt(a1, gamma_min_b):
	if mpi_overlap((b1,b2), (gamma_mono_imag_a, gamma_mono_imag_b)):
	# TODO: reflection formula
	#if mpf_lt(a2, mpf_shift(fone,-1)):
	# znew = mpci_sub((mpi_one,mpi_zero),z,wp)
	# ...
	# Recurrence:
	# gamma(z) = gamma(z+1)/z
	znew = mpi_add((a1,a2), mpi_one, wp), (b1,b2)
	if type == 0: return mpci_div(mpci_gamma(znew, prec+2, 0), z, prec)
	if type == 2: return mpci_mul(mpci_gamma(znew, prec+2, 2), z, prec)
	if type == 3: return mpci_sub(mpci_gamma(znew, prec+2, 3), mpci_log(z,prec+2), prec)

	# Use monotonicity (except for a small region close to the
	# origin and near poles)
	# upper half-plane
	if mpf_ge(b1, fzero):
	minre = mpc_loggamma((a1,b2), wp, round_floor)
	maxre = mpc_loggamma((a2,b1), wp, round_ceiling)
	minim = mpc_loggamma((a1,b1), wp, round_floor)
	maxim = mpc_loggamma((a2,b2), wp, round_ceiling)
	# lower half-plane
	elif mpf_le(b2, fzero):
	minre = mpc_loggamma((a1,b1), wp, round_floor)
	maxre = mpc_loggamma((a2,b2), wp, round_ceiling)
	minim = mpc_loggamma((a2,b1), wp, round_floor)
	maxim = mpc_loggamma((a1,b2), wp, round_ceiling)
	# crosses real axis
	else:
	maxre = mpc_loggamma((a2,fzero), wp, round_ceiling)
	# stretches more into the lower half-plane
	if mpf_gt(mpf_neg(b1), b2):
	minre = mpc_loggamma((a1,b1), wp, round_ceiling)
	else:
	minre = mpc_loggamma((a1,b2), wp, round_ceiling)
	minim = mpc_loggamma((a2,b1), wp, round_floor)
	maxim = mpc_loggamma((a2,b2), wp, round_floor)

	w = (minre[0], maxre[0]), (minim[1], maxim[1])
	if type == 3:
	return mpi_pos(w[0], prec), mpi_pos(w[1], prec)
	if type == 2:
	w = mpci_neg(w)
	return mpci_exp(w, prec)

	def mpi_loggamma(z, prec): return mpi_gamma(z, prec, type=3)
	def mpci_loggamma(z, prec): return mpci_gamma(z, prec, type=3)

	def mpi_rgamma(z, prec): return mpi_gamma(z, prec, type=2)
	def mpci_rgamma(z, prec): return mpci_gamma(z, prec, type=2)

	def mpi_factorial(z, prec): return mpi_gamma(z, prec, type=1)
	def mpci_factorial(z, prec): return mpci_gamma(z, prec, type=1)