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	"""
	Low-level functions for arbitrary-precision floating-point arithmetic.
	"""

	__docformat__ = 'plaintext'

	import math

	from bisect import bisect

	import sys

	# Importing random is slow
	#from random import getrandbits
	getrandbits = None

	from .backend import (MPZ, MPZ_TYPE, MPZ_ZERO, MPZ_ONE, MPZ_TWO, MPZ_FIVE,
	BACKEND, STRICT, HASH_MODULUS, HASH_BITS, gmpy, sage, sage_utils)

	from .libintmath import (giant_steps,
	trailtable, bctable, lshift, rshift, bitcount, trailing,
	sqrt_fixed, numeral, isqrt, isqrt_fast, sqrtrem,
	bin_to_radix)

	# We don't pickle tuples directly for the following reasons:
	# 1: pickle uses str() for ints, which is inefficient when they are large
	# 2: pickle doesn't work for gmpy mpzs
	# Both problems are solved by using hex()

	if BACKEND == 'sage':
	def to_pickable(x):
	sign, man, exp, bc = x
	return sign, hex(man), exp, bc
	else:
	def to_pickable(x):
	sign, man, exp, bc = x
	return sign, hex(man)[2:], exp, bc

	def from_pickable(x):
	sign, man, exp, bc = x
	return (sign, MPZ(man, 16), exp, bc)

	class ComplexResult(ValueError):
	pass

	try:
	intern
	except NameError:
	intern = lambda x: x

	# All supported rounding modes
	round_nearest = intern('n')
	round_floor = intern('f')
	round_ceiling = intern('c')
	round_up = intern('u')
	round_down = intern('d')
	round_fast = round_down

	def prec_to_dps(n):
	"""Return number of accurate decimals that can be represented
	with a precision of n bits."""
	return max(1, int(round(int(n)/3.3219280948873626)-1))

	def dps_to_prec(n):
	"""Return the number of bits required to represent n decimals
	accurately."""
	return max(1, int(round((int(n)+1)*3.3219280948873626)))

	def repr_dps(n):
	"""Return the number of decimal digits required to represent
	a number with n-bit precision so that it can be uniquely
	reconstructed from the representation."""
	dps = prec_to_dps(n)
	if dps == 15:
	return 17
	return dps + 3

	#----------------------------------------------------------------------------#
	# Some commonly needed float values #
	#----------------------------------------------------------------------------#

	# Regular number format:
	# (-1)*sign mantissa * 2**exponent, plus bitcount of mantissa
	fzero = (0, MPZ_ZERO, 0, 0)
	fnzero = (1, MPZ_ZERO, 0, 0)
	fone = (0, MPZ_ONE, 0, 1)
	fnone = (1, MPZ_ONE, 0, 1)
	ftwo = (0, MPZ_ONE, 1, 1)
	ften = (0, MPZ_FIVE, 1, 3)
	fhalf = (0, MPZ_ONE, -1, 1)

	# Arbitrary encoding for special numbers: zero mantissa, nonzero exponent
	fnan = (0, MPZ_ZERO, -123, -1)
	finf = (0, MPZ_ZERO, -456, -2)
	fninf = (1, MPZ_ZERO, -789, -3)

	# Was 1e1000; this is broken in Python 2.4
	math_float_inf = 1e300 * 1e300


	#----------------------------------------------------------------------------#
	# Rounding #
	#----------------------------------------------------------------------------#

	# This function can be used to round a mantissa generally. However,
	# we will try to do most rounding inline for efficiency.
	def round_int(x, n, rnd):
	if rnd == round_nearest:
	if x >= 0:
	t = x >> (n-1)
	if t & 1 and ((t & 2) or (x & h_mask[n<300][n])):
	return (t>>1)+1
	else:
	return t>>1
	else:
	return -round_int(-x, n, rnd)
	if rnd == round_floor:
	return x >> n
	if rnd == round_ceiling:
	return -((-x) >> n)
	if rnd == round_down:
	if x >= 0:
	return x >> n
	return -((-x) >> n)
	if rnd == round_up:
	if x >= 0:
	return -((-x) >> n)
	return x >> n

	# These masks are used to pick out segments of numbers to determine
	# which direction to round when rounding to nearest.
	class h_mask_big:
	def __getitem__(self, n):
	return (MPZ_ONE<<(n-1))-1

	h_mask_small = [0]+[((MPZ_ONE<<(_-1))-1) for _ in range(1, 300)]
	h_mask = [h_mask_big(), h_mask_small]

	# The >> operator rounds to floor. shifts_down[rnd][sign]
	# tells whether this is the right direction to use, or if the
	# number should be negated before shifting
	shifts_down = {round_floor:(1,0), round_ceiling:(0,1),
	round_down:(1,1), round_up:(0,0)}


	#----------------------------------------------------------------------------#
	# Normalization of raw mpfs #
	#----------------------------------------------------------------------------#

	# This function is called almost every time an mpf is created.
	# It has been optimized accordingly.

	def _normalize(sign, man, exp, bc, prec, rnd):
	"""
	Create a raw mpf tuple with value (-1)*sign man * 2**exp and
	normalized mantissa. The mantissa is rounded in the specified
	direction if its size exceeds the precision. Trailing zero bits
	are also stripped from the mantissa to ensure that the
	representation is canonical.

	Conditions on the input:
	* The input must represent a regular (finite) number
	* The sign bit must be 0 or 1
	* The mantissa must be positive
	* The exponent must be an integer
	* The bitcount must be exact

	If these conditions are not met, use from_man_exp, mpf_pos, or any
	of the conversion functions to create normalized raw mpf tuples.
	"""
	if not man:
	return fzero
	# Cut mantissa down to size if larger than target precision
	n = bc - prec
	if n > 0:
	if rnd == round_nearest:
	t = man >> (n-1)
	if t & 1 and ((t & 2) or (man & h_mask[n<300][n])):
	man = (t>>1)+1
	else:
	man = t>>1
	elif shifts_down[rnd][sign]:
	man >>= n
	else:
	man = -((-man)>>n)
	exp += n
	bc = prec
	# Strip trailing bits
	if not man & 1:
	t = trailtable[int(man & 255)]
	if not t:
	while not man & 255:
	man >>= 8
	exp += 8
	bc -= 8
	t = trailtable[int(man & 255)]
	man >>= t
	exp += t
	bc -= t
	# Bit count can be wrong if the input mantissa was 1 less than
	# a power of 2 and got rounded up, thereby adding an extra bit.
	# With trailing bits removed, all powers of two have mantissa 1,
	# so this is easy to check for.
	if man == 1:
	bc = 1
	return sign, man, exp, bc

	def _normalize1(sign, man, exp, bc, prec, rnd):
	"""same as normalize, but with the added condition that
	man is odd or zero
	"""
	if not man:
	return fzero
	if bc <= prec:
	return sign, man, exp, bc
	n = bc - prec
	if rnd == round_nearest:
	t = man >> (n-1)
	if t & 1 and ((t & 2) or (man & h_mask[n<300][n])):
	man = (t>>1)+1
	else:
	man = t>>1
	elif shifts_down[rnd][sign]:
	man >>= n
	else:
	man = -((-man)>>n)
	exp += n
	bc = prec
	# Strip trailing bits
	if not man & 1:
	t = trailtable[int(man & 255)]
	if not t:
	while not man & 255:
	man >>= 8
	exp += 8
	bc -= 8
	t = trailtable[int(man & 255)]
	man >>= t
	exp += t
	bc -= t
	# Bit count can be wrong if the input mantissa was 1 less than
	# a power of 2 and got rounded up, thereby adding an extra bit.
	# With trailing bits removed, all powers of two have mantissa 1,
	# so this is easy to check for.
	if man == 1:
	bc = 1
	return sign, man, exp, bc

	try:
	_exp_types = (int, long)
	except NameError:
	_exp_types = (int,)

	def strict_normalize(sign, man, exp, bc, prec, rnd):
	"""Additional checks on the components of an mpf. Enable tests by setting
	the environment variable MPMATH_STRICT to Y."""
	assert type(man) == MPZ_TYPE
	assert type(bc) in _exp_types
	assert type(exp) in _exp_types
	assert bc == bitcount(man)
	return _normalize(sign, man, exp, bc, prec, rnd)

	def strict_normalize1(sign, man, exp, bc, prec, rnd):
	"""Additional checks on the components of an mpf. Enable tests by setting
	the environment variable MPMATH_STRICT to Y."""
	assert type(man) == MPZ_TYPE
	assert type(bc) in _exp_types
	assert type(exp) in _exp_types
	assert bc == bitcount(man)
	assert (not man) or (man & 1)
	return _normalize1(sign, man, exp, bc, prec, rnd)

	if BACKEND == 'gmpy' and '_mpmath_normalize' in dir(gmpy):
	_normalize = gmpy._mpmath_normalize
	_normalize1 = gmpy._mpmath_normalize

	if BACKEND == 'sage':
	_normalize = _normalize1 = sage_utils.normalize

	if STRICT:
	normalize = strict_normalize
	normalize1 = strict_normalize1
	else:
	normalize = _normalize
	normalize1 = _normalize1

	#----------------------------------------------------------------------------#
	# Conversion functions #
	#----------------------------------------------------------------------------#

	def from_man_exp(man, exp, prec=None, rnd=round_fast):
	"""Create raw mpf from (man, exp) pair. The mantissa may be signed.
	If no precision is specified, the mantissa is stored exactly."""
	man = MPZ(man)
	sign = 0
	if man < 0:
	sign = 1
	man = -man
	if man < 1024:
	bc = bctable[int(man)]
	else:
	bc = bitcount(man)
	if not prec:
	if not man:
	return fzero
	if not man & 1:
	if man & 2:
	return (sign, man >> 1, exp + 1, bc - 1)
	t = trailtable[int(man & 255)]
	if not t:
	while not man & 255:
	man >>= 8
	exp += 8
	bc -= 8
	t = trailtable[int(man & 255)]
	man >>= t
	exp += t
	bc -= t
	return (sign, man, exp, bc)
	return normalize(sign, man, exp, bc, prec, rnd)

	int_cache = dict((n, from_man_exp(n, 0)) for n in range(-10, 257))

	if BACKEND == 'gmpy' and '_mpmath_create' in dir(gmpy):
	from_man_exp = gmpy._mpmath_create

	if BACKEND == 'sage':
	from_man_exp = sage_utils.from_man_exp

	def from_int(n, prec=0, rnd=round_fast):
	"""Create a raw mpf from an integer. If no precision is specified,
	the mantissa is stored exactly."""
	if not prec:
	if n in int_cache:
	return int_cache[n]
	return from_man_exp(n, 0, prec, rnd)

	def to_man_exp(s):
	"""Return (man, exp) of a raw mpf. Raise an error if inf/nan."""
	sign, man, exp, bc = s
	if (not man) and exp:
	raise ValueError("mantissa and exponent are undefined for %s" % man)
	return man, exp

	def to_int(s, rnd=None):
	"""Convert a raw mpf to the nearest int. Rounding is done down by
	default (same as int(float) in Python), but can be changed. If the
	input is inf/nan, an exception is raised."""
	sign, man, exp, bc = s
	if (not man) and exp:
	raise ValueError("cannot convert inf or nan to int")
	if exp >= 0:
	if sign:
	return (-man) << exp
	return man << exp
	# Make default rounding fast
	if not rnd:
	if sign:
	return -(man >> (-exp))
	else:
	return man >> (-exp)
	if sign:
	return round_int(-man, -exp, rnd)
	else:
	return round_int(man, -exp, rnd)

	def mpf_round_int(s, rnd):
	sign, man, exp, bc = s
	if (not man) and exp:
	return s
	if exp >= 0:
	return s
	mag = exp+bc
	if mag < 1:
	if rnd == round_ceiling:
	if sign: return fzero
	else: return fone
	elif rnd == round_floor:
	if sign: return fnone
	else: return fzero
	elif rnd == round_nearest:
	if mag < 0 or man == MPZ_ONE: return fzero
	elif sign: return fnone
	else: return fone
	else:
	raise NotImplementedError
	return mpf_pos(s, min(bc, mag), rnd)

	def mpf_floor(s, prec=0, rnd=round_fast):
	v = mpf_round_int(s, round_floor)
	if prec:
	v = mpf_pos(v, prec, rnd)
	return v

	def mpf_ceil(s, prec=0, rnd=round_fast):
	v = mpf_round_int(s, round_ceiling)
	if prec:
	v = mpf_pos(v, prec, rnd)
	return v

	def mpf_nint(s, prec=0, rnd=round_fast):
	v = mpf_round_int(s, round_nearest)
	if prec:
	v = mpf_pos(v, prec, rnd)
	return v

	def mpf_frac(s, prec=0, rnd=round_fast):
	return mpf_sub(s, mpf_floor(s), prec, rnd)

	def from_float(x, prec=53, rnd=round_fast):
	"""Create a raw mpf from a Python float, rounding if necessary.
	If prec >= 53, the result is guaranteed to represent exactly the
	same number as the input. If prec is not specified, use prec=53."""
	# frexp only raises an exception for nan on some platforms
	if x != x:
	return fnan
	# in Python2.5 math.frexp gives an exception for float infinity
	# in Python2.6 it returns (float infinity, 0)
	try:
	m, e = math.frexp(x)
	except:
	if x == math_float_inf: return finf
	if x == -math_float_inf: return fninf
	return fnan
	if x == math_float_inf: return finf
	if x == -math_float_inf: return fninf
	return from_man_exp(int(m*(1<<53)), e-53, prec, rnd)

	def from_npfloat(x, prec=113, rnd=round_fast):
	"""Create a raw mpf from a numpy float, rounding if necessary.
	If prec >= 113, the result is guaranteed to represent exactly the
	same number as the input. If prec is not specified, use prec=113."""
	y = float(x)
	if x == y: # ldexp overflows for float16
	return from_float(y, prec, rnd)
	import numpy as np
	if np.isfinite(x):
	m, e = np.frexp(x)
	return from_man_exp(int(np.ldexp(m, 113)), int(e-113), prec, rnd)
	if np.isposinf(x): return finf
	if np.isneginf(x): return fninf
	return fnan

	def from_Decimal(x, prec=None, rnd=round_fast):
	"""Create a raw mpf from a Decimal, rounding if necessary.
	If prec is not specified, use the equivalent bit precision
	of the number of significant digits in x."""
	if x.is_nan(): return fnan
	if x.is_infinite(): return fninf if x.is_signed() else finf
	if prec is None:
	prec = int(len(x.as_tuple()[1])*3.3219280948873626)
	return from_str(str(x), prec, rnd)

	def to_float(s, strict=False, rnd=round_fast):
	"""
	Convert a raw mpf to a Python float. The result is exact if the
	bitcount of s is <= 53 and no underflow/overflow occurs.

	If the number is too large or too small to represent as a regular
	float, it will be converted to inf or 0.0. Setting strict=True
	forces an OverflowError to be raised instead.

	Warning: with a directed rounding mode, the correct nearest representable
	floating-point number in the specified direction might not be computed
	in case of overflow or (gradual) underflow.
	"""
	sign, man, exp, bc = s
	if not man:
	if s == fzero: return 0.0
	if s == finf: return math_float_inf
	if s == fninf: return -math_float_inf
	return math_float_inf/math_float_inf
	if bc > 53:
	sign, man, exp, bc = normalize1(sign, man, exp, bc, 53, rnd)
	if sign:
	man = -man
	try:
	return math.ldexp(man, exp)
	except OverflowError:
	if strict:
	raise
	# Overflow to infinity
	if exp + bc > 0:
	if sign:
	return -math_float_inf
	else:
	return math_float_inf
	# Underflow to zero
	return 0.0

	def from_rational(p, q, prec, rnd=round_fast):
	"""Create a raw mpf from a rational number p/q, round if
	necessary."""
	return mpf_div(from_int(p), from_int(q), prec, rnd)

	def to_rational(s):
	"""Convert a raw mpf to a rational number. Return integers (p, q)
	such that s = p/q exactly."""
	sign, man, exp, bc = s
	if sign:
	man = -man
	if bc == -1:
	raise ValueError("cannot convert %s to a rational number" % man)
	if exp >= 0:
	return man * (1<<exp), 1
	else:
	return man, 1<<(-exp)

	def to_fixed(s, prec):
	"""Convert a raw mpf to a fixed-point big integer"""
	sign, man, exp, bc = s
	offset = exp + prec
	if sign:
	if offset >= 0: return (-man) << offset
	else: return (-man) >> (-offset)
	else:
	if offset >= 0: return man << offset
	else: return man >> (-offset)


	##############################################################################
	##############################################################################

	#----------------------------------------------------------------------------#
	# Arithmetic operations, etc. #
	#----------------------------------------------------------------------------#

	def mpf_rand(prec):
	"""Return a raw mpf chosen randomly from [0, 1), with prec bits
	in the mantissa."""
	global getrandbits
	if not getrandbits:
	import random
	getrandbits = random.getrandbits
	return from_man_exp(getrandbits(prec), -prec, prec, round_floor)

	def mpf_eq(s, t):
	"""Test equality of two raw mpfs. This is simply tuple comparison
	unless either number is nan, in which case the result is False."""
	if not s[1] or not t[1]:
	if s == fnan or t == fnan:
	return False
	return s == t

	def mpf_hash(s):
	# Duplicate the new hash algorithm introduces in Python 3.2.
	if sys.version_info >= (3, 2):
	ssign, sman, sexp, sbc = s

	# Handle special numbers
	if not sman:
	if s == fnan: return sys.hash_info.nan
	if s == finf: return sys.hash_info.inf
	if s == fninf: return -sys.hash_info.inf
	h = sman % HASH_MODULUS
	if sexp >= 0:
	sexp = sexp % HASH_BITS
	else:
	sexp = HASH_BITS - 1 - ((-1 - sexp) % HASH_BITS)
	h = (h << sexp) % HASH_MODULUS
	if ssign: h = -h
	if h == -1: h = -2
	return int(h)
	else:
	try:
	# Try to be compatible with hash values for floats and ints
	return hash(to_float(s, strict=1))
	except OverflowError:
	# We must unfortunately sacrifice compatibility with ints here.
	# We could do hash(man << exp) when the exponent is positive, but
	# this would cause unreasonable inefficiency for large numbers.
	return hash(s)

	def mpf_cmp(s, t):
	"""Compare the raw mpfs s and t. Return -1 if s < t, 0 if s == t,
	and 1 if s > t. (Same convention as Python's cmp() function.)"""

	# In principle, a comparison amounts to determining the sign of s-t.
	# A full subtraction is relatively slow, however, so we first try to
	# look at the components.
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t

	# Handle zeros and special numbers
	if not sman or not tman:
	if s == fzero: return -mpf_sign(t)
	if t == fzero: return mpf_sign(s)
	if s == t: return 0
	# Follow same convention as Python's cmp for float nan
	if t == fnan: return 1
	if s == finf: return 1
	if t == fninf: return 1
	return -1
	# Different sides of zero
	if ssign != tsign:
	if not ssign: return 1
	return -1
	# This reduces to direct integer comparison
	if sexp == texp:
	if sman == tman:
	return 0
	if sman > tman:
	if ssign: return -1
	else: return 1
	else:
	if ssign: return 1
	else: return -1
	# Check position of the highest set bit in each number. If
	# different, there is certainly an inequality.
	a = sbc + sexp
	b = tbc + texp
	if ssign:
	if a < b: return 1
	if a > b: return -1
	else:
	if a < b: return -1
	if a > b: return 1

	# Both numbers have the same highest bit. Subtract to find
	# how the lower bits compare.
	delta = mpf_sub(s, t, 5, round_floor)
	if delta[0]:
	return -1
	return 1

	def mpf_lt(s, t):
	if s == fnan or t == fnan:
	return False
	return mpf_cmp(s, t) < 0

	def mpf_le(s, t):
	if s == fnan or t == fnan:
	return False
	return mpf_cmp(s, t) <= 0

	def mpf_gt(s, t):
	if s == fnan or t == fnan:
	return False
	return mpf_cmp(s, t) > 0

	def mpf_ge(s, t):
	if s == fnan or t == fnan:
	return False
	return mpf_cmp(s, t) >= 0

	def mpf_min_max(seq):
	min = max = seq[0]
	for x in seq[1:]:
	if mpf_lt(x, min): min = x
	if mpf_gt(x, max): max = x
	return min, max

	def mpf_pos(s, prec=0, rnd=round_fast):
	"""Calculate 0+s for a raw mpf (i.e., just round s to the specified
	precision)."""
	if prec:
	sign, man, exp, bc = s
	if (not man) and exp:
	return s
	return normalize1(sign, man, exp, bc, prec, rnd)
	return s

	def mpf_neg(s, prec=None, rnd=round_fast):
	"""Negate a raw mpf (return -s), rounding the result to the
	specified precision. The prec argument can be omitted to do the
	operation exactly."""
	sign, man, exp, bc = s
	if not man:
	if exp:
	if s == finf: return fninf
	if s == fninf: return finf
	return s
	if not prec:
	return (1-sign, man, exp, bc)
	return normalize1(1-sign, man, exp, bc, prec, rnd)

	def mpf_abs(s, prec=None, rnd=round_fast):
	"""Return abs(s) of the raw mpf s, rounded to the specified
	precision. The prec argument can be omitted to generate an
	exact result."""
	sign, man, exp, bc = s
	if (not man) and exp:
	if s == fninf:
	return finf
	return s
	if not prec:
	if sign:
	return (0, man, exp, bc)
	return s
	return normalize1(0, man, exp, bc, prec, rnd)

	def mpf_sign(s):
	"""Return -1, 0, or 1 (as a Python int, not a raw mpf) depending on
	whether s is negative, zero, or positive. (Nan is taken to give 0.)"""
	sign, man, exp, bc = s
	if not man:
	if s == finf: return 1
	if s == fninf: return -1
	return 0
	return (-1) ** sign

	def mpf_add(s, t, prec=0, rnd=round_fast, _sub=0):
	"""
	Add the two raw mpf values s and t.

	With prec=0, no rounding is performed. Note that this can
	produce a very large mantissa (potentially too large to fit
	in memory) if exponents are far apart.
	"""
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t
	tsign ^= _sub
	# Standard case: two nonzero, regular numbers
	if sman and tman:
	offset = sexp - texp
	if offset:
	if offset > 0:
	# Outside precision range; only need to perturb
	if offset > 100 and prec:
	delta = sbc + sexp - tbc - texp
	if delta > prec + 4:
	offset = prec + 4
	sman <<= offset
	if tsign == ssign: sman += 1
	else: sman -= 1
	return normalize1(ssign, sman, sexp-offset,
	bitcount(sman), prec, rnd)
	# Add
	if ssign == tsign:
	man = tman + (sman << offset)
	# Subtract
	else:
	if ssign: man = tman - (sman << offset)
	else: man = (sman << offset) - tman
	if man >= 0:
	ssign = 0
	else:
	man = -man
	ssign = 1
	bc = bitcount(man)
	return normalize1(ssign, man, texp, bc, prec or bc, rnd)
	elif offset < 0:
	# Outside precision range; only need to perturb
	if offset < -100 and prec:
	delta = tbc + texp - sbc - sexp
	if delta > prec + 4:
	offset = prec + 4
	tman <<= offset
	if ssign == tsign: tman += 1
	else: tman -= 1
	return normalize1(tsign, tman, texp-offset,
	bitcount(tman), prec, rnd)
	# Add
	if ssign == tsign:
	man = sman + (tman << -offset)
	# Subtract
	else:
	if tsign: man = sman - (tman << -offset)
	else: man = (tman << -offset) - sman
	if man >= 0:
	ssign = 0
	else:
	man = -man
	ssign = 1
	bc = bitcount(man)
	return normalize1(ssign, man, sexp, bc, prec or bc, rnd)
	# Equal exponents; no shifting necessary
	if ssign == tsign:
	man = tman + sman
	else:
	if ssign: man = tman - sman
	else: man = sman - tman
	if man >= 0:
	ssign = 0
	else:
	man = -man
	ssign = 1
	bc = bitcount(man)
	return normalize(ssign, man, texp, bc, prec or bc, rnd)
	# Handle zeros and special numbers
	if _sub:
	t = mpf_neg(t)
	if not sman:
	if sexp:
	if s == t or tman or not texp:
	return s
	return fnan
	if tman:
	return normalize1(tsign, tman, texp, tbc, prec or tbc, rnd)
	return t
	if texp:
	return t
	if sman:
	return normalize1(ssign, sman, sexp, sbc, prec or sbc, rnd)
	return s

	def mpf_sub(s, t, prec=0, rnd=round_fast):
	"""Return the difference of two raw mpfs, s-t. This function is
	simply a wrapper of mpf_add that changes the sign of t."""
	return mpf_add(s, t, prec, rnd, 1)

	def mpf_sum(xs, prec=0, rnd=round_fast, absolute=False):
	"""
	Sum a list of mpf values efficiently and accurately
	(typically no temporary roundoff occurs). If prec=0,
	the final result will not be rounded either.

	There may be roundoff error or cancellation if extremely
	large exponent differences occur.

	With absolute=True, sums the absolute values.
	"""
	man = 0
	exp = 0
	max_extra_prec = prec*2 or 1000000 # XXX
	special = None
	for x in xs:
	xsign, xman, xexp, xbc = x
	if xman:
	if xsign and not absolute:
	xman = -xman
	delta = xexp - exp
	if xexp >= exp:
	# x much larger than existing sum?
	# first: quick test
	if (delta > max_extra_prec) and \
	((not man) or delta-bitcount(abs(man)) > max_extra_prec):
	man = xman
	exp = xexp
	else:
	man += (xman << delta)
	else:
	delta = -delta
	# x much smaller than existing sum?
	if delta-xbc > max_extra_prec:
	if not man:
	man, exp = xman, xexp
	else:
	man = (man << delta) + xman
	exp = xexp
	elif xexp:
	if absolute:
	x = mpf_abs(x)
	special = mpf_add(special or fzero, x, 1)
	# Will be inf or nan
	if special:
	return special
	return from_man_exp(man, exp, prec, rnd)

	def gmpy_mpf_mul(s, t, prec=0, rnd=round_fast):
	"""Multiply two raw mpfs"""
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t
	sign = ssign ^ tsign
	man = sman*tman
	if man:
	bc = bitcount(man)
	if prec:
	return normalize1(sign, man, sexp+texp, bc, prec, rnd)
	else:
	return (sign, man, sexp+texp, bc)
	s_special = (not sman) and sexp
	t_special = (not tman) and texp
	if not s_special and not t_special:
	return fzero
	if fnan in (s, t): return fnan
	if (not tman) and texp: s, t = t, s
	if t == fzero: return fnan
	return {1:finf, -1:fninf}[mpf_sign(s) * mpf_sign(t)]

	def gmpy_mpf_mul_int(s, n, prec, rnd=round_fast):
	"""Multiply by a Python integer."""
	sign, man, exp, bc = s
	if not man:
	return mpf_mul(s, from_int(n), prec, rnd)
	if not n:
	return fzero
	if n < 0:
	sign ^= 1
	n = -n
	man *= n
	return normalize(sign, man, exp, bitcount(man), prec, rnd)

	def python_mpf_mul(s, t, prec=0, rnd=round_fast):
	"""Multiply two raw mpfs"""
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t
	sign = ssign ^ tsign
	man = sman*tman
	if man:
	bc = sbc + tbc - 1
	bc += int(man>>bc)
	if prec:
	return normalize1(sign, man, sexp+texp, bc, prec, rnd)
	else:
	return (sign, man, sexp+texp, bc)
	s_special = (not sman) and sexp
	t_special = (not tman) and texp
	if not s_special and not t_special:
	return fzero
	if fnan in (s, t): return fnan
	if (not tman) and texp: s, t = t, s
	if t == fzero: return fnan
	return {1:finf, -1:fninf}[mpf_sign(s) * mpf_sign(t)]

	def python_mpf_mul_int(s, n, prec, rnd=round_fast):
	"""Multiply by a Python integer."""
	sign, man, exp, bc = s
	if not man:
	return mpf_mul(s, from_int(n), prec, rnd)
	if not n:
	return fzero
	if n < 0:
	sign ^= 1
	n = -n
	man *= n
	# Generally n will be small
	if n < 1024:
	bc += bctable[int(n)] - 1
	else:
	bc += bitcount(n) - 1
	bc += int(man>>bc)
	return normalize(sign, man, exp, bc, prec, rnd)


	if BACKEND == 'gmpy':
	mpf_mul = gmpy_mpf_mul
	mpf_mul_int = gmpy_mpf_mul_int
	else:
	mpf_mul = python_mpf_mul
	mpf_mul_int = python_mpf_mul_int

	def mpf_shift(s, n):
	"""Quickly multiply the raw mpf s by 2**n without rounding."""
	sign, man, exp, bc = s
	if not man:
	return s
	return sign, man, exp+n, bc

	def mpf_frexp(x):
	"""Convert x = y2*n to (y, n) with abs(y) in [0.5, 1) if nonzero"""
	sign, man, exp, bc = x
	if not man:
	if x == fzero:
	return (fzero, 0)
	else:
	raise ValueError
	return mpf_shift(x, -bc-exp), bc+exp

	def mpf_div(s, t, prec, rnd=round_fast):
	"""Floating-point division"""
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t
	if not sman or not tman:
	if s == fzero:
	if t == fzero: raise ZeroDivisionError
	if t == fnan: return fnan
	return fzero
	if t == fzero:
	raise ZeroDivisionError
	s_special = (not sman) and sexp
	t_special = (not tman) and texp
	if s_special and t_special:
	return fnan
	if s == fnan or t == fnan:
	return fnan
	if not t_special:
	if t == fzero:
	return fnan
	return {1:finf, -1:fninf}[mpf_sign(s) * mpf_sign(t)]
	return fzero
	sign = ssign ^ tsign
	if tman == 1:
	return normalize1(sign, sman, sexp-texp, sbc, prec, rnd)
	# Same strategy as for addition: if there is a remainder, perturb
	# the result a few bits outside the precision range before rounding
	extra = prec - sbc + tbc + 5
	if extra < 5:
	extra = 5
	quot, rem = divmod(sman<<extra, tman)
	if rem:
	quot = (quot<<1) + 1
	extra += 1
	return normalize1(sign, quot, sexp-texp-extra, bitcount(quot), prec, rnd)
	return normalize(sign, quot, sexp-texp-extra, bitcount(quot), prec, rnd)

	def mpf_rdiv_int(n, t, prec, rnd=round_fast):
	"""Floating-point division n/t with a Python integer as numerator"""
	sign, man, exp, bc = t
	if not n or not man:
	return mpf_div(from_int(n), t, prec, rnd)
	if n < 0:
	sign ^= 1
	n = -n
	extra = prec + bc + 5
	quot, rem = divmod(n<<extra, man)
	if rem:
	quot = (quot<<1) + 1
	extra += 1
	return normalize1(sign, quot, -exp-extra, bitcount(quot), prec, rnd)
	return normalize(sign, quot, -exp-extra, bitcount(quot), prec, rnd)

	def mpf_mod(s, t, prec, rnd=round_fast):
	ssign, sman, sexp, sbc = s
	tsign, tman, texp, tbc = t
	if ((not sman) and sexp) or ((not tman) and texp):
	return fnan
	# Important special case: do nothing if t is larger
	if ssign == tsign and texp > sexp+sbc:
	return s
	# Another important special case: this allows us to do e.g. x % 1.0
	# to find the fractional part of x, and it will work when x is huge.
	if tman == 1 and sexp > texp+tbc:
	return fzero
	base = min(sexp, texp)
	sman = (-1)*ssign sman
	tman = (-1)*tsign tman
	man = (sman << (sexp-base)) % (tman << (texp-base))
	if man >= 0:
	sign = 0
	else:
	man = -man
	sign = 1
	return normalize(sign, man, base, bitcount(man), prec, rnd)

	reciprocal_rnd = {
	round_down : round_up,
	round_up : round_down,
	round_floor : round_ceiling,
	round_ceiling : round_floor,
	round_nearest : round_nearest
	}

	negative_rnd = {
	round_down : round_down,
	round_up : round_up,
	round_floor : round_ceiling,
	round_ceiling : round_floor,
	round_nearest : round_nearest
	}

	def mpf_pow_int(s, n, prec, rnd=round_fast):
	"""Compute s**n, where s is a raw mpf and n is a Python integer."""
	sign, man, exp, bc = s

	if (not man) and exp:
	if s == finf:
	if n > 0: return s
	if n == 0: return fnan
	return fzero
	if s == fninf:
	if n > 0: return [finf, fninf][n & 1]
	if n == 0: return fnan
	return fzero
	return fnan

	n = int(n)
	if n == 0: return fone
	if n == 1: return mpf_pos(s, prec, rnd)
	if n == 2:
	_, man, exp, bc = s
	if not man:
	return fzero
	man = man*man
	if man == 1:
	return (0, MPZ_ONE, exp+exp, 1)
	bc = bc + bc - 2
	bc += bctable[int(man>>bc)]
	return normalize1(0, man, exp+exp, bc, prec, rnd)
	if n == -1: return mpf_div(fone, s, prec, rnd)
	if n < 0:
	inverse = mpf_pow_int(s, -n, prec+5, reciprocal_rnd[rnd])
	return mpf_div(fone, inverse, prec, rnd)

	result_sign = sign & n

	# Use exact integer power when the exact mantissa is small
	if man == 1:
	return (result_sign, MPZ_ONE, exp*n, 1)
	if bc*n < 1000:
	man **= n
	return normalize1(result_sign, man, exp*n, bitcount(man), prec, rnd)

	# Use directed rounding all the way through to maintain rigorous
	# bounds for interval arithmetic
	rounds_down = (rnd == round_nearest) or \
	shifts_down[rnd][result_sign]

	# Now we perform binary exponentiation. Need to estimate precision
	# to avoid rounding errors from temporary operations. Roughly log_2(n)
	# operations are performed.
	workprec = prec + 4*bitcount(n) + 4
	_, pm, pe, pbc = fone
	while 1:
	if n & 1:
	pm = pm*man
	pe = pe+exp
	pbc += bc - 2
	pbc = pbc + bctable[int(pm >> pbc)]
	if pbc > workprec:
	if rounds_down:
	pm = pm >> (pbc-workprec)
	else:
	pm = -((-pm) >> (pbc-workprec))
	pe += pbc - workprec
	pbc = workprec
	n -= 1
	if not n:
	break
	man = man*man
	exp = exp+exp
	bc = bc + bc - 2
	bc = bc + bctable[int(man >> bc)]
	if bc > workprec:
	if rounds_down:
	man = man >> (bc-workprec)
	else:
	man = -((-man) >> (bc-workprec))
	exp += bc - workprec
	bc = workprec
	n = n // 2

	return normalize(result_sign, pm, pe, pbc, prec, rnd)


	def mpf_perturb(x, eps_sign, prec, rnd):
	"""
	For nonzero x, calculate x + eps with directed rounding, where
	eps < prec relatively and eps has the given sign (0 for
	positive, 1 for negative).

	With rounding to nearest, this is taken to simply normalize
	x to the given precision.
	"""
	if rnd == round_nearest:
	return mpf_pos(x, prec, rnd)
	sign, man, exp, bc = x
	eps = (eps_sign, MPZ_ONE, exp+bc-prec-1, 1)
	if sign:
	away = (rnd in (round_down, round_ceiling)) ^ eps_sign
	else:
	away = (rnd in (round_up, round_ceiling)) ^ eps_sign
	if away:
	return mpf_add(x, eps, prec, rnd)
	else:
	return mpf_pos(x, prec, rnd)


	#----------------------------------------------------------------------------#
	# Radix conversion #
	#----------------------------------------------------------------------------#

	def to_digits_exp(s, dps):
	"""Helper function for representing the floating-point number s as
	a decimal with dps digits. Returns (sign, string, exponent) where
	sign is '' or '-', string is the digit string, and exponent is
	the decimal exponent as an int.

	If inexact, the decimal representation is rounded toward zero."""

	# Extract sign first so it doesn't mess up the string digit count
	if s[0]:
	sign = '-'
	s = mpf_neg(s)
	else:
	sign = ''
	_sign, man, exp, bc = s

	if not man:
	return '', '0', 0

	bitprec = int(dps * math.log(10,2)) + 10

	# Cut down to size
	# TODO: account for precision when doing this
	exp_from_1 = exp + bc
	if abs(exp_from_1) > 3500:
	from .libelefun import mpf_ln2, mpf_ln10
	# Set b = int(exp * log(2)/log(10))
	# If exp is huge, we must use high-precision arithmetic to
	# find the nearest power of ten
	expprec = bitcount(abs(exp)) + 5
	tmp = from_int(exp)
	tmp = mpf_mul(tmp, mpf_ln2(expprec))
	tmp = mpf_div(tmp, mpf_ln10(expprec), expprec)
	b = to_int(tmp)
	s = mpf_div(s, mpf_pow_int(ften, b, bitprec), bitprec)
	_sign, man, exp, bc = s
	exponent = b
	else:
	exponent = 0

	# First, calculate mantissa digits by converting to a binary
	# fixed-point number and then converting that number to
	# a decimal fixed-point number.
	fixprec = max(bitprec - exp - bc, 0)
	fixdps = int(fixprec / math.log(10,2) + 0.5)
	sf = to_fixed(s, fixprec)
	sd = bin_to_radix(sf, fixprec, 10, fixdps)
	digits = numeral(sd, base=10, size=dps)

	exponent += len(digits) - fixdps - 1
	return sign, digits, exponent

	def to_str(s, dps, strip_zeros=True, min_fixed=None, max_fixed=None,
	show_zero_exponent=False):
	"""
	Convert a raw mpf to a decimal floating-point literal with at
	most `dps` decimal digits in the mantissa (not counting extra zeros
	that may be inserted for visual purposes).

	The number will be printed in fixed-point format if the position
	of the leading digit is strictly between min_fixed
	(default = min(-dps/3,-5)) and max_fixed (default = dps).

	To force fixed-point format always, set min_fixed = -inf,
	max_fixed = +inf. To force floating-point format, set
	min_fixed >= max_fixed.

	The literal is formatted so that it can be parsed back to a number
	by to_str, float() or Decimal().
	"""

	# Special numbers
	if not s[1]:
	if s == fzero:
	if dps: t = '0.0'
	else: t = '.0'
	if show_zero_exponent:
	t += 'e+0'
	return t
	if s == finf: return '+inf'
	if s == fninf: return '-inf'
	if s == fnan: return 'nan'
	raise ValueError

	if min_fixed is None: min_fixed = min(-(dps//3), -5)
	if max_fixed is None: max_fixed = dps

	# to_digits_exp rounds to floor.
	# This sometimes kills some instances of "...00001"
	sign, digits, exponent = to_digits_exp(s, dps+3)

	# No digits: show only .0; round exponent to nearest
	if not dps:
	if digits[0] in '56789':
	exponent += 1
	digits = ".0"

	else:
	# Rounding up kills some instances of "...99999"
	if len(digits) > dps and digits[dps] in '56789':
	digits = digits[:dps]
	i = dps - 1
	while i >= 0 and digits[i] == '9':
	i -= 1
	if i >= 0:
	digits = digits[:i] + str(int(digits[i]) + 1) + '0' * (dps - i - 1)
	else:
	digits = '1' + '0' * (dps - 1)
	exponent += 1
	else:
	digits = digits[:dps]

	# Prettify numbers close to unit magnitude
	if min_fixed < exponent < max_fixed:
	if exponent < 0:
	digits = ("0"*int(-exponent)) + digits
	split = 1
	else:
	split = exponent + 1
	if split > dps:
	digits += "0"*(split-dps)
	exponent = 0
	else:
	split = 1

	digits = (digits[:split] + "." + digits[split:])

	if strip_zeros:
	# Clean up trailing zeros
	digits = digits.rstrip('0')
	if digits[-1] == ".":
	digits += "0"

	if exponent == 0 and dps and not show_zero_exponent: return sign + digits
	if exponent >= 0: return sign + digits + "e+" + str(exponent)
	if exponent < 0: return sign + digits + "e" + str(exponent)

	def str_to_man_exp(x, base=10):
	"""Helper function for from_str."""
	x = x.lower().rstrip('l')
	# Verify that the input is a valid float literal
	float(x)
	# Split into mantissa, exponent
	parts = x.split('e')
	if len(parts) == 1:
	exp = 0
	else: # == 2
	x = parts[0]
	exp = int(parts[1])
	# Look for radix point in mantissa
	parts = x.split('.')
	if len(parts) == 2:
	a, b = parts[0], parts[1].rstrip('0')
	exp -= len(b)
	x = a + b
	x = MPZ(int(x, base))
	return x, exp

	special_str = {'inf':finf, '+inf':finf, '-inf':fninf, 'nan':fnan}

	def from_str(x, prec, rnd=round_fast):
	"""Create a raw mpf from a decimal literal, rounding in the
	specified direction if the input number cannot be represented
	exactly as a binary floating-point number with the given number of
	bits. The literal syntax accepted is the same as for Python
	floats.

	TODO: the rounding does not work properly for large exponents.
	"""
	x = x.lower().strip()
	if x in special_str:
	return special_str[x]

	if '/' in x:
	p, q = x.split('/')
	p, q = p.rstrip('l'), q.rstrip('l')
	return from_rational(int(p), int(q), prec, rnd)

	man, exp = str_to_man_exp(x, base=10)

	# XXX: appropriate cutoffs & track direction
	# note no factors of 5
	if abs(exp) > 400:
	s = from_int(man, prec+10)
	s = mpf_mul(s, mpf_pow_int(ften, exp, prec+10), prec, rnd)
	else:
	if exp >= 0:
	s = from_int(man * 10**exp, prec, rnd)
	else:
	s = from_rational(man, 10**-exp, prec, rnd)
	return s

	# Binary string conversion. These are currently mainly used for debugging
	# and could use some improvement in the future

	def from_bstr(x):
	man, exp = str_to_man_exp(x, base=2)
	man = MPZ(man)
	sign = 0
	if man < 0:
	man = -man
	sign = 1
	bc = bitcount(man)
	return normalize(sign, man, exp, bc, bc, round_floor)

	def to_bstr(x):
	sign, man, exp, bc = x
	return ['','-'][sign] + numeral(man, size=bitcount(man), base=2) + ("e%i" % exp)


	#----------------------------------------------------------------------------#
	# Square roots #
	#----------------------------------------------------------------------------#


	def mpf_sqrt(s, prec, rnd=round_fast):
	"""
	Compute the square root of a nonnegative mpf value. The
	result is correctly rounded.
	"""
	sign, man, exp, bc = s
	if sign:
	raise ComplexResult("square root of a negative number")
	if not man:
	return s
	if exp & 1:
	exp -= 1
	man <<= 1
	bc += 1
	elif man == 1:
	return normalize1(sign, man, exp//2, bc, prec, rnd)
	shift = max(4, 2*prec-bc+4)
	shift += shift & 1
	if rnd in 'fd':
	man = isqrt(man<<shift)
	else:
	man, rem = sqrtrem(man<<shift)
	# Perturb up
	if rem:
	man = (man<<1)+1
	shift += 2
	return from_man_exp(man, (exp-shift)//2, prec, rnd)

	def mpf_hypot(x, y, prec, rnd=round_fast):
	"""Compute the Euclidean norm sqrt(x2 + y2) of two raw mpfs
	x and y."""
	if y == fzero: return mpf_abs(x, prec, rnd)
	if x == fzero: return mpf_abs(y, prec, rnd)
	hypot2 = mpf_add(mpf_mul(x,x), mpf_mul(y,y), prec+4)
	return mpf_sqrt(hypot2, prec, rnd)


	if BACKEND == 'sage':
	try:
	import sage.libs.mpmath.ext_libmp as ext_lib
	mpf_add = ext_lib.mpf_add
	mpf_sub = ext_lib.mpf_sub
	mpf_mul = ext_lib.mpf_mul
	mpf_div = ext_lib.mpf_div
	mpf_sqrt = ext_lib.mpf_sqrt
	except ImportError:
	pass