1806 lines
57 KiB
Python
1806 lines
57 KiB
Python
"""
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Low-level functions for arbitrary-precision floating-point arithmetic.
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"""
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import math
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import random
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import re
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import sys
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from .backend import BACKEND, MPZ, MPZ_FIVE, MPZ_ONE, MPZ_ZERO, gmpy, int_types
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from .libintmath import (bctable, bin_to_radix, isqrt, numeral, sqrtrem,
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stddigits, trailing)
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class ComplexResult(ValueError):
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pass
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# All supported rounding modes
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round_nearest = sys.intern('n')
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round_floor = sys.intern('f')
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round_ceiling = sys.intern('c')
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round_up = sys.intern('u')
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round_down = sys.intern('d')
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def prec_to_dps(n):
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"""Return number of accurate decimals that can be represented
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with a precision of n bits."""
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return max(1, round(int(n)/blog2_10) - 1)
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def dps_to_prec(n):
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"""Return the number of bits required to represent n decimals
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accurately."""
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return max(1, round((int(n) + 1)*blog2_10))
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def repr_dps(n):
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"""Return the number of decimal digits required to represent
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a number with n-bit precision so that it can be uniquely
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reconstructed from the representation."""
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return 1 + math.ceil(int(n)/blog2_10)
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#----------------------------------------------------------------------------#
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# Some commonly needed float values #
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#----------------------------------------------------------------------------#
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# Regular number format:
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# (-1)**sign * mantissa * 2**exponent, plus mantissa.bit_length()
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fzero = (0, MPZ_ZERO, 0, 0)
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fone = (0, MPZ_ONE, 0, 1)
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fnone = (1, MPZ_ONE, 0, 1)
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ftwo = (0, MPZ_ONE, 1, 1)
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ften = (0, MPZ_FIVE, 1, 3)
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fhalf = (0, MPZ_ONE, -1, 1)
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# Arbitrary encoding for special numbers: zero mantissa, nonzero exponent
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fnan = (0, MPZ_ZERO, -123, -1)
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finf = (0, MPZ_ZERO, -456, -2)
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fninf = (1, MPZ_ZERO, -789, -3)
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math_float_inf = math.inf
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math_float_nan = math.nan
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blog2_10 = 3.3219280948873626
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float_mant_dig = sys.float_info.mant_dig
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float_min_exp = sys.float_info.min_exp
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float_max_exp = sys.float_info.max_exp
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float_eps = sys.float_info.epsilon
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float_max = sys.float_info.max
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float_min = sys.float_info.min
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float_min_subnormal_exp = float_min_exp - float_mant_dig
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#----------------------------------------------------------------------------#
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# Rounding #
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#----------------------------------------------------------------------------#
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# This function can be used to round a mantissa generally. However,
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# we will try to do most rounding inline for efficiency.
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def round_int(x, n, rnd):
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if rnd == round_nearest:
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if x >= 0:
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t = x >> (n-1)
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if t & 1 and ((t & 2) or (x & h_mask[n<300][n])):
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return (t>>1)+1
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else:
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return t>>1
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else:
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return -round_int(-x, n, rnd)
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if rnd == round_floor:
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return x >> n
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if rnd == round_ceiling:
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return -((-x) >> n)
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if rnd == round_down:
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if x >= 0:
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return x >> n
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return -((-x) >> n)
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if rnd == round_up:
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if x >= 0:
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return -((-x) >> n)
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return x >> n
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# These masks are used to pick out segments of numbers to determine
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# which direction to round when rounding to nearest.
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class h_mask_big:
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def __getitem__(self, n):
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return (MPZ_ONE<<(n-1))-1
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h_mask_small = [0]+[((MPZ_ONE<<(_-1))-1) for _ in range(1, 300)]
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h_mask = [h_mask_big(), h_mask_small]
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# The >> operator rounds to floor. shifts_down[rnd][sign]
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# tells whether this is the right direction to use, or if the
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# number should be negated before shifting
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shifts_down = {round_floor:(1,0), round_ceiling:(0,1),
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round_down:(1,1), round_up:(0,0)}
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#----------------------------------------------------------------------------#
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# Normalization of raw mpfs #
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#----------------------------------------------------------------------------#
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# This function is called almost every time an mpf is created.
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# It has been optimized accordingly.
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def normalize(sign, man, exp, bc, prec, rnd):
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"""
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Create a raw mpf tuple with value (-1)**sign * man * 2**exp and
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normalized mantissa. The mantissa is rounded according to the specified
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rounding mode if its size exceeds the precision. Trailing zero bits
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are also stripped from the mantissa to ensure that the
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representation is canonical.
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Conditions on the input:
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* The input must represent a regular (finite) number
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* The sign bit must be 0 or 1
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* The mantissa must be nonnegative
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* The exponent must be an integer
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* The bitcount must be exact
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If these conditions are not met, use from_man_exp, mpf_pos, or any
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of the conversion functions to create normalized raw mpf tuples.
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"""
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assert type(man) == MPZ
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assert type(bc) in _exp_types
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assert type(exp) in _exp_types
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assert bc == man.bit_length()
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assert man >= 0
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if not man:
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return fzero
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# Cut mantissa down to size if larger than target precision
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n = bc - prec
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if n > 0:
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if rnd == round_nearest:
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t = man >> (n-1)
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if t & 1 and ((t & 2) or (man & h_mask[n<300][n])):
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man = (t>>1)+1
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else:
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man = t>>1
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elif shifts_down[rnd][sign]:
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man >>= n
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else:
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man = -((-man)>>n)
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exp += n
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bc = prec
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# Strip trailing bits
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if not man & 1:
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t = trailing(man)
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man >>= t
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exp += t
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bc -= t
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# Bit count can be wrong if the input mantissa was 1 less than
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# a power of 2 and got rounded up, thereby adding an extra bit.
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# With trailing bits removed, all powers of two have mantissa 1,
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# so this is easy to check for.
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if man == 1:
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bc = 1
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return sign, man, int(exp), int(bc)
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_exp_types = (int,)
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if gmpy:
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normalize = gmpy._mpmath_normalize
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#----------------------------------------------------------------------------#
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# Conversion functions #
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#----------------------------------------------------------------------------#
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def from_man_exp(man, exp, prec=0, rnd=round_down):
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"""Create raw mpf from (man, exp) pair. The mantissa may be signed.
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If no precision is specified, the mantissa is stored exactly."""
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if isinstance(man, int_types):
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man = MPZ(man)
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else:
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raise TypeError("man expected to be an integer")
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sign = 0
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if man < 0:
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sign = 1
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man = -man
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if man < 1024:
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bc = bctable[man]
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else:
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bc = man.bit_length()
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if not prec:
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if not man:
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return fzero
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if not man & 1:
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t = trailing(man)
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return sign, man >> t, int(exp + t), int(bc - t)
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return sign, man, exp, bc
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return normalize(sign, man, exp, bc, prec, rnd)
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int_cache = dict((n, from_man_exp(n, 0)) for n in range(-10, 257))
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if gmpy:
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from_man_exp = gmpy._mpmath_create
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def from_int(n, prec=0, rnd=round_down):
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"""Create a raw mpf from an integer. If no precision is specified,
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the mantissa is stored exactly."""
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if not prec:
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if n in int_cache:
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return int_cache[n]
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return from_man_exp(MPZ(n), 0, prec, rnd)
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def to_man_exp(s, signed=True):
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"""Return (man, exp) of a raw mpf. Raise an error if inf/nan."""
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sign, man, exp, bc = s
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if (not man) and exp:
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raise ValueError("mantissa and exponent are defined "
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"for finite numbers only")
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if signed and sign:
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man = -man
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return man, exp
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def to_int(s, rnd=round_down):
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"""Convert a raw mpf to the nearest int. Rounding is done down by
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default (same as int(float) in Python), but can be changed. If the
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input is inf/nan, an exception is raised."""
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sign, man, exp, bc = s
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if (not man) and exp:
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if s == fnan:
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raise ValueError("cannot convert nan to int")
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raise OverflowError("cannot convert infinity to int")
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if exp >= 0:
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if sign:
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return (-man) << exp
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return man << exp
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# Make default rounding fast
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if rnd == round_down:
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if sign:
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return -(man >> (-exp))
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else:
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return man >> (-exp)
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if sign:
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return round_int(-man, -exp, rnd)
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else:
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return round_int(man, -exp, rnd)
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def mpf_round_int(s, rnd):
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sign, man, exp, bc = s
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if (not man) and exp:
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return s
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if exp >= 0:
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return s
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mag = exp+bc
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if mag < 1:
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if rnd == round_ceiling:
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if sign: return fzero
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else: return fone
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elif rnd == round_floor:
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if sign: return fnone
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else: return fzero
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elif rnd == round_nearest:
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if mag < 0 or man == MPZ_ONE: return fzero
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elif sign: return fnone
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else: return fone
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else:
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raise NotImplementedError
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return mpf_pos(s, min(bc, mag), rnd)
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def mpf_floor(s, prec=0, rnd=round_down):
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v = mpf_round_int(s, round_floor)
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if prec:
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v = mpf_pos(v, prec, rnd)
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return v
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def mpf_ceil(s, prec=0, rnd=round_down):
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v = mpf_round_int(s, round_ceiling)
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if prec:
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v = mpf_pos(v, prec, rnd)
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return v
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def mpf_nint(s, prec=0, rnd=round_down):
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v = mpf_round_int(s, round_nearest)
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if prec:
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v = mpf_pos(v, prec, rnd)
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return v
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def mpf_frac(s, prec=0, rnd=round_down):
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return mpf_sub(s, mpf_floor(s), prec, rnd)
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def from_float(x, prec=53, rnd=round_down):
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"""Create a raw mpf from a Python float, rounding if necessary.
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If prec >= 53, the result is guaranteed to represent exactly the
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same number as the input. If prec is not specified, use prec=53."""
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# frexp only raises an exception for nan on some platforms
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if x != x: return fnan
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if x == math_float_inf: return finf
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if x == -math_float_inf: return fninf
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m, e = math.frexp(x)
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return from_man_exp(MPZ(m*(1<<53)), e-53, prec, rnd)
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def from_npfloat(x, prec=113, rnd=round_down):
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"""Create a raw mpf from a numpy float, rounding if necessary.
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If prec >= 113, the result is guaranteed to represent exactly the
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same number as the input. If prec is not specified, use prec=113."""
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y = float(x)
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if x == y: # ldexp overflows for float16
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return from_float(y, prec, rnd)
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import numpy as np
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if np.isfinite(x):
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m, e = np.frexp(x)
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return from_man_exp(MPZ(np.ldexp(m, 113)), int(e)-113, prec, rnd)
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return fnan
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def from_Decimal(x, prec=0, rnd=round_down):
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"""Create a raw mpf from a Decimal, rounding if necessary.
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If prec is not specified, use the equivalent bit precision
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of the number of significant digits in x."""
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if x.is_nan(): return fnan
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if x.is_infinite(): return fninf if x.is_signed() else finf
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if not prec:
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prec = int(len(x.as_tuple()[1])*blog2_10)
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return from_str(str(x), prec, rnd)
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def to_float(s, strict=False, rnd=round_down):
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"""
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Convert a raw mpf to a Python float. The result is exact
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if s.bit_length() <= sys.float_info.mant_dig and no
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underflow/overflow occurs. Else result is correctly rounded.
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If the magnitude of rounded number is too large to represent as
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a regular float, it will be converted to infinity. Setting
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strict=True forces an OverflowError to be raised instead.
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"""
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sign, man, exp, bc = s
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if not man:
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if s == fzero: return 0.0
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if s == finf: return math_float_inf
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if s == fninf: return -math_float_inf
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return math_float_nan
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exp2 = exp + bc
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# The smallest normal number is 2^(-1022)=0.1p-1021, and the smallest
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# subnormal is 2^(-1074)=0.1p-1073
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if exp2 <= float_min_subnormal_exp:
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if sign:
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if rnd == round_floor or (rnd == round_nearest
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and mpf_cmp(s, (1, MPZ(1), float_min_subnormal_exp
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- 1, 1)) < 0):
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return -float_min * float_eps
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return 0.0
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if rnd == round_ceiling or (rnd == round_nearest
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and mpf_cmp(s, (0, MPZ(1), float_min_subnormal_exp
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- 1, 1)) > 0):
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return float_min * float_eps
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return 0.0
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# The largest normal number is 2^1024*(1-2^(-53))=0.111...111p1024
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if exp2 > float_max_exp:
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if sign:
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if rnd == round_down or rnd == round_ceiling:
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return -float_max
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if strict:
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raise OverflowError("math range error")
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return -math_float_inf
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if rnd == round_down or rnd == round_floor:
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return float_max
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if strict:
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raise OverflowError("math range error")
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return math_float_inf
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nbits = float_mant_dig
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if exp2 < float_min_exp:
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# In the subnormal case, compute the exact number of significant bits.
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nbits += exp2 - float_min_exp
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assert 1 <= nbits < float_mant_dig
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if bc > nbits:
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sign, man, exp, bc = normalize(sign, man, exp, bc, nbits, rnd)
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if sign:
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man = -man
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# Should be exact:
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return math.ldexp(man, exp)
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def from_rational(p, q, prec, rnd=round_down):
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"""Create a raw mpf from a rational number p/q, round if
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necessary."""
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return mpf_div(from_int(p), from_int(q), prec, rnd)
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def to_rational(s):
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"""Convert a raw mpf to a rational number. Return integers (p, q)
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such that s = p/q exactly."""
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if s == fnan:
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raise ValueError("cannot convert nan to a rational number")
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if s in (finf, fninf):
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raise OverflowError("cannot convert infinity to a rational number")
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sign, man, exp, bc = s
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if sign:
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man = -man
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if exp >= 0:
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return man * (1<<exp), MPZ(1)
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else:
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return man, MPZ(1)<<(-exp)
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def to_fixed(s, prec):
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"""Convert a raw mpf to a fixed-point big integer"""
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sign, man, exp, bc = s
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offset = exp + prec
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if sign:
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if offset >= 0: return (-man) << offset
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else: return (-man) >> (-offset)
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else:
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if offset >= 0: return man << offset
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else: return man >> (-offset)
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##############################################################################
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##############################################################################
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#----------------------------------------------------------------------------#
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# Arithmetic operations, etc. #
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#----------------------------------------------------------------------------#
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def mpf_rand(prec):
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"""Return a raw mpf chosen randomly from [0, 1), with prec bits
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in the mantissa."""
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return from_man_exp(MPZ(random.getrandbits(prec)), -prec, prec, round_floor)
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def mpf_eq(s, t):
|
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"""Test equality of two raw mpfs. This is simply tuple comparison
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unless either number is nan, in which case the result is False."""
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if not s[1] or not t[1]:
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if s == fnan or t == fnan:
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return False
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return s == t
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def mpf_hash(s):
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# Duplicate the new hash algorithm, introduced in Python 3.2.
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ssign, sman, sexp, sbc = s
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# Handle special numbers
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if not sman:
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if s == fnan: return object.__hash__(s)
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if s == finf: return sys.hash_info.inf
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if s == fninf: return -sys.hash_info.inf
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hash_modulus = sys.hash_info.modulus
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hash_bits = 31 if sys.hash_info.width == 32 else 61
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h = sman % hash_modulus
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if sexp >= 0:
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sexp = sexp % hash_bits
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else:
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sexp = hash_bits - 1 - ((-1 - sexp) % hash_bits)
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h = (h << sexp) % hash_modulus
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if ssign: h = -h
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if h == -1: h = -2
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return int(h)
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def mpf_cmp(s, t):
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"""Compare the raw mpfs s and t. Return -1 if s < t, 0 if s == t,
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and 1 if s > t. (Same convention as Python's cmp() function.)"""
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# In principle, a comparison amounts to determining the sign of s-t.
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# A full subtraction is relatively slow, however, so we first try to
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# look at the components.
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ssign, sman, sexp, sbc = s
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tsign, tman, texp, tbc = t
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# Handle zeros and special numbers
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if not sman or not tman:
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if s == fzero: return -mpf_sign(t)
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if t == fzero: return mpf_sign(s)
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if s == t: return 0
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# Follow same convention as Python's cmp for float nan
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if t == fnan: return 1
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if s == finf: return 1
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if t == fninf: return 1
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return -1
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# Different sides of zero
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if ssign != tsign:
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if not ssign: return 1
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return -1
|
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# This reduces to direct integer comparison
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if sexp == texp:
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if sman == tman:
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return 0
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if sman > tman:
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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_down):
|
|
"""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 normalize(sign, man, exp, bc, prec, rnd)
|
|
return s
|
|
|
|
def mpf_neg(s, prec=0, rnd=round_down):
|
|
"""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 normalize(1-sign, man, exp, bc, prec, rnd)
|
|
|
|
def mpf_abs(s, prec=0, rnd=round_down):
|
|
"""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 normalize(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_down, _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 normalize(ssign, sman, sexp-offset,
|
|
sman.bit_length(), 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 = man.bit_length()
|
|
return normalize(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 normalize(tsign, tman, texp-offset,
|
|
tman.bit_length(), 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 = man.bit_length()
|
|
return normalize(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 = man.bit_length()
|
|
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 normalize(tsign, tman, texp, tbc, prec or tbc, rnd)
|
|
return t
|
|
if texp:
|
|
return t
|
|
if sman:
|
|
return normalize(ssign, sman, sexp, sbc, prec or sbc, rnd)
|
|
return s
|
|
|
|
def mpf_sub(s, t, prec=0, rnd=round_down):
|
|
"""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_down, 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 = MPZ(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-man.bit_length() > 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 mpf_mul(s, t, prec=0, rnd=round_down):
|
|
"""Multiply two raw mpfs"""
|
|
ssign, sman, sexp, sbc = s
|
|
tsign, tman, texp, tbc = t
|
|
sign = ssign ^ tsign
|
|
man = sman*tman
|
|
if man:
|
|
bc = man.bit_length()
|
|
if prec:
|
|
return normalize(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_down):
|
|
"""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, man.bit_length(), prec, rnd)
|
|
|
|
def python_mpf_mul_int(s, n, prec, rnd=round_down):
|
|
"""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[n] - 1
|
|
else:
|
|
bc += n.bit_length() - 1
|
|
bc += man>>bc
|
|
return normalize(sign, man, exp, bc, prec, rnd)
|
|
|
|
mpf_mul_int = python_mpf_mul_int
|
|
|
|
if gmpy:
|
|
mpf_mul_int = gmpy_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 = y*2**n to (y, n) with abs(y) in [0.5, 1) if nonzero"""
|
|
sign, man, exp, bc = x
|
|
if not man:
|
|
return (x, 0)
|
|
return mpf_shift(x, -bc-exp), bc+exp
|
|
|
|
def mpf_div(s, t, prec, rnd=round_down):
|
|
"""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 normalize(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
|
|
if not prec:
|
|
extra = max(sbc, tbc) - sbc + tbc + 5
|
|
else:
|
|
extra = prec - sbc + tbc + 5
|
|
if extra < 5:
|
|
extra = 5
|
|
quot, rem = divmod(sman<<extra, tman)
|
|
if rem:
|
|
quot = (quot<<1) + 1
|
|
extra += 1
|
|
bc = quot.bit_length()
|
|
return normalize(sign, quot, sexp-texp-extra, bc, prec or bc, rnd)
|
|
|
|
def mpf_rdiv_int(n, t, prec, rnd=round_down):
|
|
"""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 normalize(sign, quot, -exp-extra, quot.bit_length(), prec, rnd)
|
|
return normalize(sign, quot, -exp-extra, quot.bit_length(), prec, rnd)
|
|
|
|
def mpf_mod(s, t, prec, rnd=round_down):
|
|
ssign, sman, sexp, sbc = s
|
|
tsign, tman, texp, tbc = t
|
|
if ((not sman) and sexp) or ((not tman) and texp):
|
|
if t == finf or t == fninf:
|
|
return s
|
|
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, man.bit_length(), 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_down):
|
|
"""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 fone
|
|
return fzero
|
|
if s == fninf:
|
|
if n > 0: return [finf, fninf][n & 1]
|
|
if n == 0: return fone
|
|
return fzero
|
|
if n == 0:
|
|
return fone
|
|
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[man>>bc]
|
|
return normalize(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 normalize(result_sign, man, exp*n, man.bit_length(), 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*n.bit_length() + 4
|
|
_, pm, pe, pbc = fone
|
|
while 1:
|
|
if n & 1:
|
|
pm = pm*man
|
|
pe = pe+exp
|
|
pbc += bc - 2
|
|
pbc = pbc + bctable[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[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, base=10):
|
|
"""Helper function for representing the floating-point number s as
|
|
a string with dps digits. Returns (sign, string, exponent) where
|
|
sign is '' or '-', string is the digit string in the given base,
|
|
and exponent is the exponent as an int.
|
|
|
|
If inexact, the string 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'*int(dps), 0
|
|
|
|
if base == 10:
|
|
blog2 = blog2_10
|
|
elif pow(2, blog2 := int(math.log2(base))) == base:
|
|
pass
|
|
else:
|
|
raise NotImplementedError
|
|
|
|
bitprec = int(dps * blog2) + 10
|
|
|
|
# Cut down to size
|
|
# TODO: account for precision when doing this
|
|
exp_from_1 = exp + bc
|
|
if base == 10 and 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 = exp.bit_length() + 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 / blog2 + 0.5)
|
|
sf = to_fixed(s, fixprec)
|
|
sb = bin_to_radix(sf, fixprec, base, fixdps)
|
|
digits = numeral(sb, base=base, size=dps)
|
|
|
|
exponent += len(digits) - fixdps - 1
|
|
return sign, digits, exponent
|
|
|
|
def round_digits(sign, digits, dps, base, rnd=round_down, fixed=False):
|
|
"""
|
|
Returns the rounded digits, and the number of places the decimal point was
|
|
shifted.
|
|
"""
|
|
|
|
assert len(digits) > dps
|
|
assert rnd in (round_nearest, round_up, round_down, round_ceiling,
|
|
round_floor)
|
|
|
|
if rnd == round_ceiling:
|
|
rnd = round_down if sign else round_up
|
|
elif rnd == round_floor:
|
|
rnd = round_up if sign else round_down
|
|
|
|
exponent = 0
|
|
|
|
if rnd == round_down:
|
|
return digits[:dps], 0
|
|
elif rnd == round_nearest:
|
|
rnd_digs = stddigits[(base//2 + base % 2):base]
|
|
else:
|
|
rnd_digs = stddigits[1:base]
|
|
|
|
tie_down = False
|
|
tie_up = False
|
|
|
|
if rnd == round_nearest:
|
|
# The first digit after dps is a 5 and we should determine whether we
|
|
# round it up or down.
|
|
if digits[dps] == rnd_digs[0]:
|
|
tie_down = True
|
|
|
|
# If the digit we round to is even, we may round down if all the
|
|
# following digits are 0.
|
|
for i in range(dps+1, len(digits)):
|
|
if digits[i] != '0':
|
|
tie_down = False
|
|
break
|
|
# If the digit we round to is odd, we round up no matter what.
|
|
if digits[dps-1] in stddigits[1:base:2]:
|
|
tie_down = False
|
|
|
|
elif rnd == round_up:
|
|
# If any digit following a 0 is different from zero, we round up.
|
|
if digits[dps] == '0':
|
|
for i in range(dps+1, len(digits)):
|
|
if digits[i] != '0':
|
|
tie_up = True
|
|
break
|
|
|
|
# Add or subtract a unit to the digit following the one we round to.
|
|
if tie_down:
|
|
digits = digits[:dps] + stddigits[int(digits[dps], base) - 1]
|
|
elif tie_up:
|
|
digits = digits[:dps] + '1'
|
|
|
|
# Rounding up kills some instances of "...99999"
|
|
if digits[dps] in rnd_digs:
|
|
digits = digits[:dps]
|
|
i = dps - 1
|
|
dig = stddigits[base-1]
|
|
while i >= 0 and digits[i] == dig:
|
|
i -= 1
|
|
if i >= 0:
|
|
digits = digits[:i] + stddigits[int(digits[i], base) + 1] + \
|
|
'0' * (dps - i - 1)
|
|
else:
|
|
# When rounding up 0.9999... in fixed format, we lose one dps.
|
|
digits = '1' + '0' * (dps - (0 if fixed else 1))
|
|
exponent += 1
|
|
else:
|
|
digits = digits[:dps]
|
|
|
|
return digits, exponent
|
|
|
|
|
|
def to_str(s, dps, strip_zeros=True, min_fixed=None, max_fixed=None,
|
|
show_zero_exponent=False, base=10, binary_exp=False,
|
|
rnd=round_nearest):
|
|
"""
|
|
Convert a raw mpf to a floating-point literal in the given base
|
|
with at most `dps` 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.
|
|
|
|
If binary_exp is True and the base is either 2 or 16, the number will
|
|
be printed in a binary or hexadecimal notation, where the exponent
|
|
separator is the 'p' and the exponent is written in decimal rather than
|
|
hexadecimal or binary. The number is normalized, i.e. the first
|
|
digit is 1. This is format of the float.fromhex().
|
|
|
|
The literal is formatted so that it can be parsed back to a number
|
|
by from_str, float(), float.fromhex() or Decimal().
|
|
"""
|
|
sep = '@' if base > 10 else 'e'
|
|
|
|
if binary_exp:
|
|
sep = 'p'
|
|
if base not in (2, 16):
|
|
raise ValueError("binary_exp option could be used for base 2 and 16")
|
|
|
|
if rnd not in (round_nearest, round_floor, round_ceiling, round_up,
|
|
round_down):
|
|
raise ValueError("rnd should be one of " +
|
|
", ".join([round_nearest, round_floor, round_ceiling,
|
|
round_up, round_down]) + ".")
|
|
|
|
if base == 2:
|
|
prefix = "0b"
|
|
elif base == 8:
|
|
prefix = "0o"
|
|
elif base == 16:
|
|
prefix = "0x"
|
|
else:
|
|
prefix = ""
|
|
|
|
# Special numbers
|
|
if not s[1]:
|
|
if s == fzero:
|
|
if dps: t = '0.0'
|
|
else: t = '.0'
|
|
if show_zero_exponent:
|
|
t += sep + '+0'
|
|
return prefix + 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+10, base)
|
|
|
|
rnd_digs = stddigits[(base//2 + base%2):base]
|
|
|
|
# No digits: show only .0; round exponent to nearest
|
|
if not dps:
|
|
if digits[0] in rnd_digs:
|
|
exponent += 1
|
|
digits = ".0"
|
|
|
|
else:
|
|
if binary_exp and base == 16:
|
|
exponent *= 4
|
|
# normalization
|
|
if int(digits[0], 16) > 1:
|
|
shift = math.floor(math.log2(int(digits[0], 16)))
|
|
exponent += shift
|
|
n = int(digits, 16) >> shift
|
|
digits = hex(n)[2:]
|
|
|
|
digits, exp_add = round_digits(s[0], digits, dps, base, rnd)
|
|
exponent += exp_add
|
|
|
|
# Prettify numbers close to unit magnitude
|
|
if not binary_exp and min_fixed < exponent < max_fixed:
|
|
if exponent < 0:
|
|
digits = ("0"*(-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"
|
|
|
|
sign += prefix
|
|
|
|
if exponent == 0 and dps and not show_zero_exponent: return sign + digits
|
|
return sign + digits + sep + f"{exponent:+}"
|
|
|
|
def str_to_man_exp(x, base=10):
|
|
"""Helper function for from_str."""
|
|
x = x.lower().rstrip('l').replace('_', '')
|
|
# Split into mantissa, exponent
|
|
if base <= 10:
|
|
sep = 'e'
|
|
else:
|
|
sep = '@'
|
|
if pow(2, e2 := int(math.log2(base))) == base and e2 in [1, 4] and x.find('p') >= 0:
|
|
sep = 'p'
|
|
parts = x.split(sep)
|
|
if len(parts) == 1:
|
|
exp = 0
|
|
elif len(parts) == 2:
|
|
x = parts[0]
|
|
exp = int(parts[1])
|
|
else:
|
|
raise ValueError("couldn't convert a str to mpf")
|
|
# Look for radix point in mantissa
|
|
parts = x.split('.')
|
|
if len(parts) == 2:
|
|
a, b = parts[0], parts[1].rstrip('0')
|
|
if sep != 'p':
|
|
exp -= len(b)
|
|
else:
|
|
exp -= len(b)*e2
|
|
if a == '':
|
|
a = '0'
|
|
x = a + b
|
|
int_max_str_digits = 0
|
|
if BACKEND == 'python' and hasattr(sys, 'get_int_max_str_digits'):
|
|
int_max_str_digits = sys.get_int_max_str_digits()
|
|
sys.set_int_max_str_digits(0)
|
|
x = MPZ(x, base)
|
|
if int_max_str_digits:
|
|
sys.set_int_max_str_digits(int_max_str_digits)
|
|
return x, exp
|
|
|
|
special_str = {'inf':finf, '+inf':finf, '-inf':fninf, 'nan':fnan,
|
|
'oo':finf, '+oo':finf, '-oo':fninf}
|
|
|
|
def from_str(x, prec=0, rnd=round_down, base=0):
|
|
"""Create a raw mpf from a string x in a given base, 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 string syntax accepted for float() or float.fromhex()
|
|
is accepted too.
|
|
|
|
TODO: the rounding does not work properly for large exponents.
|
|
"""
|
|
x = x.lower().strip()
|
|
if x in special_str:
|
|
return special_str[x]
|
|
|
|
if not base:
|
|
if x.startswith(('0b', '-0b', '0B', '-0B')):
|
|
base = 2
|
|
elif x.startswith(('0x', '-0x', '0X', '-0X')):
|
|
base = 16
|
|
elif x.startswith(('0o', '-0o')):
|
|
base = 8
|
|
else:
|
|
base = 10
|
|
|
|
if '/' in x:
|
|
p, q = x.split('/')
|
|
p, q = p.rstrip('l'), q.rstrip('l')
|
|
return from_rational(int(p, base), int(q, base), prec, rnd)
|
|
|
|
man, exp = str_to_man_exp(x, base)
|
|
|
|
if 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)
|
|
elif pow(2, e2 := int(math.log2(base))) == base:
|
|
if x.find('p') < 0:
|
|
s = from_man_exp(man, exp*e2, prec, rnd)
|
|
else:
|
|
s = from_man_exp(man, exp, prec, rnd)
|
|
else:
|
|
raise NotImplementedError
|
|
return s
|
|
|
|
|
|
#----------------------------------------------------------------------------#
|
|
# String formatting #
|
|
#----------------------------------------------------------------------------#
|
|
|
|
_FLOAT_FORMAT_SPECIFICATION_MATCHER = re.compile(r"""
|
|
(?:
|
|
(?P<fill_char>.)?
|
|
(?P<align>[<>=^])
|
|
)?
|
|
(?P<sign>[-+ ]?)
|
|
(?P<no_neg_0>z)?
|
|
(?P<alternate>\#)?
|
|
(?P<zeropad>0(?=0*[1-9]))?
|
|
(?P<width>[0-9]+)?
|
|
(?P<thousands_separators>[,_])?
|
|
(?:\.
|
|
(?=[,_0-9]) # lookahead for digit or separator
|
|
(?P<precision>[0-9]+)?
|
|
(?P<frac_separators>[,_])?
|
|
)?
|
|
(?P<rounding>[UDYZN])?
|
|
(?P<type>[aAbeEfFgG%])?
|
|
""", re.DOTALL | re.VERBOSE).fullmatch
|
|
|
|
_GMPY_ROUND_CHAR_DICT = {
|
|
'U': round_ceiling,
|
|
'D': round_floor,
|
|
'Y': round_up,
|
|
'Z': round_down,
|
|
'N': round_nearest
|
|
}
|
|
|
|
def calc_padding(nchars, width, align):
|
|
'''
|
|
Computes the left and right padding required to fill the required width,
|
|
according to how the string will be aligned.
|
|
'''
|
|
ntotal = max(nchars, width)
|
|
|
|
if align in ('>', '='):
|
|
lpad = ntotal - nchars
|
|
rpad = 0
|
|
elif align == '^':
|
|
lpad = (ntotal - nchars)//2
|
|
rpad = ntotal - nchars - lpad
|
|
else:
|
|
lpad = 0
|
|
rpad = ntotal - nchars
|
|
|
|
return (lpad, rpad)
|
|
|
|
|
|
def read_format_spec(format_spec):
|
|
'''
|
|
Reads the format spec into a dictionary.
|
|
This is more or less copied from the CPython implementation for regular
|
|
floats.
|
|
'''
|
|
|
|
format_dict = {
|
|
'fill_char': ' ',
|
|
'align': '>',
|
|
'sign': '-',
|
|
'no_neg_0': False,
|
|
'alternate': False,
|
|
'thousands_separators': '',
|
|
'frac_separators': '',
|
|
'width': -1,
|
|
'precision': -1,
|
|
'type': ''
|
|
}
|
|
|
|
if match := _FLOAT_FORMAT_SPECIFICATION_MATCHER(format_spec):
|
|
format_dict['fill_char'] = match['fill_char'] or format_dict['fill_char']
|
|
format_dict['align'] = match['align'] or format_dict['align']
|
|
format_dict['sign'] = match['sign'] or format_dict['sign']
|
|
format_dict['no_neg_0'] = bool(match['no_neg_0']) or format_dict['no_neg_0']
|
|
format_dict['alternate'] = bool(match['alternate']) or \
|
|
format_dict['alternate']
|
|
format_dict['thousands_separators'] = match['thousands_separators'] \
|
|
or format_dict['thousands_separators']
|
|
format_dict['width'] = int(match['width'] or format_dict['width'])
|
|
format_dict['precision'] = int(match['precision'] or format_dict['precision'])
|
|
format_dict['frac_separators'] = match['frac_separators'] \
|
|
or format_dict['frac_separators']
|
|
rounding_char = match['rounding']
|
|
format_dict['type'] = match['type'] or format_dict['type']
|
|
|
|
if rounding_char is not None:
|
|
format_dict['rounding'] = _GMPY_ROUND_CHAR_DICT[rounding_char]
|
|
|
|
if match['zeropad']:
|
|
if not match['align']:
|
|
format_dict['align'] = '='
|
|
if not match['fill_char']:
|
|
format_dict['fill_char'] = '0'
|
|
|
|
if format_dict['precision'] < 0 and format_dict['type'].lower() not in ['', 'a', 'b']:
|
|
format_dict['precision'] = 6
|
|
else:
|
|
raise ValueError("Invalid format specifier '{}'".format(format_spec))
|
|
|
|
return format_dict
|
|
|
|
|
|
def format_fixed(s, dps, rnd=round_down):
|
|
# First, get the exponent to know how many digits we will need
|
|
base = 10
|
|
_, _, exponent = to_digits_exp(s, 1, base)
|
|
|
|
# Now that we have an estimate, compute the correct digits
|
|
# (we do this because the previous computation could yield the wrong
|
|
# exponent by +- 1)
|
|
_, digits, exponent = to_digits_exp(
|
|
s, max(dps+exponent+4, int(s[3]/blog2_10)), base)
|
|
orig_dps = dps
|
|
dps += exponent + 1
|
|
|
|
# The number we want to print is lower in magnitude that the requested
|
|
# precision. We should only print 0s.
|
|
if dps < 0:
|
|
int_part = '0'
|
|
frac_part = orig_dps*'0'
|
|
|
|
else:
|
|
digits, exp_add = round_digits(s[0], digits, dps, base, rnd, True)
|
|
exponent += exp_add
|
|
|
|
# Here we prepend the corresponding 0s to the digits string, according
|
|
# to the value of exponent
|
|
if exponent < 0:
|
|
digits = ("0"*(-exponent)) + digits
|
|
split = 1
|
|
else:
|
|
split = exponent + 1
|
|
int_part = digits[:split]
|
|
|
|
# Finally, assemble the digits including the decimal point
|
|
if orig_dps == 0:
|
|
return int_part, ''
|
|
|
|
frac_part = digits[split:]
|
|
|
|
return int_part, frac_part
|
|
|
|
|
|
def format_scientific(s, dps, rnd=round_down):
|
|
base = 10
|
|
|
|
# First, get the exponent to know how many digits we will need
|
|
dps += 1
|
|
_, digits, exponent = to_digits_exp(s, max(dps + 10,
|
|
int(s[3]/blog2_10) + 10),
|
|
base)
|
|
digits, exp_add = round_digits(s[0], digits, dps, base, rnd)
|
|
exponent += exp_add
|
|
|
|
return digits[0], digits[1:], f'e{exponent:+03d}'
|
|
|
|
|
|
def format_hexadecimal(s, dps, rnd=round_down):
|
|
prec = 4*dps + 1 if dps >= 0 else s[1].bit_length()
|
|
|
|
if s[1]:
|
|
s = mpf_pos(s, prec, rnd)
|
|
|
|
exponent = s[2] + s[3] - 1
|
|
man = s[1] | (1 << s[3] + 2) # set leading digit (ignored) to 0x9
|
|
man <<= 1 + 4*((s[3] + 3)//4) - s[3]
|
|
|
|
frac_digits = hex(man)[3:]
|
|
digits = "1"
|
|
else:
|
|
exponent = 0
|
|
frac_digits = ""
|
|
digits = "0"
|
|
|
|
if dps >= 0:
|
|
frac_digits = frac_digits[:dps]
|
|
frac_digits += "0"*(dps - len(frac_digits))
|
|
else:
|
|
# Clean up trailing zeros
|
|
frac_digits = frac_digits.rstrip('0')
|
|
|
|
return digits, frac_digits, f'p{exponent:+01d}'
|
|
|
|
|
|
def format_binary(s, dps, rnd=round_down):
|
|
prec = dps + 1 if dps >= 0 else s[1].bit_length()
|
|
s = mpf_pos(s, prec, rnd)
|
|
|
|
digits = bin(s[1])[2:]
|
|
digits = digits + '0'*(dps + 1 - len(digits))
|
|
exponent = s[2]
|
|
if s[1]:
|
|
exponent += s[1].bit_length() - 1
|
|
return digits[0], digits[1:], f'p{exponent:+01d}'
|
|
|
|
|
|
_MAP_SPEC_STR = {finf: 'inf', fninf: 'inf', fnan: 'nan'}
|
|
|
|
|
|
def fill_sep(digits, sep, prev, nmod, sep_range):
|
|
return prev + sep.join(digits[pos:pos + sep_range]
|
|
for pos in range(nmod, len(digits), sep_range))
|
|
|
|
|
|
def format_digits(num, format_dict, prec, rnd, _pretty_repr_dps):
|
|
capitalize = False
|
|
if format_dict['type'] in list('AFGE'):
|
|
capitalize = True
|
|
|
|
fmt_type = format_dict['type'].lower()
|
|
|
|
percent = False
|
|
if fmt_type == '%':
|
|
percent = True
|
|
fmt_type = 'f'
|
|
num = mpf_mul(num, from_int(100), prec, rnd=round_nearest)
|
|
|
|
dps = format_dict['precision']
|
|
|
|
int_part = ''
|
|
exponent = ''
|
|
sign = ''
|
|
|
|
# Now the general case
|
|
strip_last_zero = False
|
|
strip_zeros = False
|
|
|
|
rnd = format_dict.get('rounding', rnd)
|
|
|
|
if not fmt_type or fmt_type == 'g':
|
|
if not format_dict['alternate']:
|
|
strip_zeros = True
|
|
if fmt_type == 'g':
|
|
strip_last_zero = True
|
|
|
|
if dps < 0:
|
|
dps = repr_dps(prec) if _pretty_repr_dps else prec_to_dps(prec)
|
|
if dps == 0:
|
|
dps = 1
|
|
|
|
_, tdigits, exp = to_digits_exp(num, max(53/blog2_10, dps), 10)
|
|
if num[1]:
|
|
_, exp_add = round_digits(num, tdigits, dps, 10, rnd)
|
|
exp += exp_add
|
|
|
|
fix0 = 0 if fmt_type else 1
|
|
if -4 <= exp < dps - fix0:
|
|
dps = max(0, dps - exp - 1)
|
|
else:
|
|
fmt_type = 'e'
|
|
dps = max(0, dps - 1)
|
|
|
|
if num in _MAP_SPEC_STR: # special cases
|
|
frac_part = _MAP_SPEC_STR[num]
|
|
if capitalize:
|
|
frac_part = frac_part.upper()
|
|
|
|
elif fmt_type == 'e':
|
|
int_part, frac_part, exponent = format_scientific(num, dps, rnd=rnd)
|
|
if strip_zeros:
|
|
frac_part = frac_part.rstrip('0')
|
|
if frac_part or format_dict['alternate']:
|
|
frac_part = '.' + frac_part
|
|
if capitalize:
|
|
exponent = exponent.replace('e', 'E')
|
|
|
|
elif fmt_type == 'a':
|
|
int_part, frac_part, exponent = format_hexadecimal(num, dps, rnd=rnd)
|
|
if capitalize:
|
|
int_part = '0X' + int_part
|
|
frac_part = frac_part.upper()
|
|
exponent = exponent.replace('p', 'P')
|
|
else:
|
|
int_part = '0x' + int_part
|
|
if frac_part or format_dict['alternate']:
|
|
frac_part = '.' + frac_part
|
|
|
|
elif fmt_type == 'b':
|
|
int_part, frac_part, exponent = format_binary(num, dps, rnd=rnd)
|
|
if frac_part or format_dict['alternate']:
|
|
frac_part = '.' + frac_part
|
|
|
|
else: # fixed-point formats
|
|
int_part, frac_part = format_fixed(num, dps, rnd=rnd)
|
|
|
|
if strip_zeros:
|
|
frac_part = frac_part.rstrip('0')
|
|
if not frac_part and not fmt_type:
|
|
frac_part = '0'
|
|
if (frac_part or format_dict['alternate']
|
|
or (dps and not strip_last_zero)):
|
|
frac_part = '.' + frac_part
|
|
|
|
sep_range = 3
|
|
sep = format_dict['frac_separators']
|
|
if sep and frac_part:
|
|
frac_part = fill_sep(frac_part, sep, frac_part[0], 1, sep_range)
|
|
digits = frac_part + exponent
|
|
|
|
sign = '-' if num[0] else ''
|
|
if sign != '-' and format_dict['sign'] != '-':
|
|
sign = format_dict['sign']
|
|
if fmt_type == 'f' and format_dict['no_neg_0']:
|
|
if int_part == "0" and all(_ in ['0', '.', '_', ',']
|
|
for _ in digits):
|
|
if format_dict['sign'] == '-':
|
|
sign = ''
|
|
else:
|
|
sign = format_dict['sign']
|
|
|
|
if percent:
|
|
digits += '%'
|
|
|
|
sep = format_dict['thousands_separators']
|
|
width = format_dict['width']
|
|
min_leading = width - len(digits) - len(sign)
|
|
if (int_part and fmt_type not in ['a', 'b']
|
|
and format_dict['fill_char'] == '0' and format_dict['align'] == '='
|
|
and min_leading > len(int_part)):
|
|
int_part = int_part.zfill(sep_range*min_leading//(sep_range + 1) + 1
|
|
if sep else min_leading)
|
|
|
|
# Add the thousands separator every 3 characters.
|
|
split = len(int_part)
|
|
if sep and split > sep_range:
|
|
# the first thousand separator may be located before 3 characters
|
|
nmod = split % sep_range
|
|
if nmod != 0:
|
|
prev = int_part[:nmod] + sep
|
|
else:
|
|
prev = ''
|
|
int_part = fill_sep(int_part, sep, prev, nmod, sep_range)
|
|
|
|
return sign, int_part + digits
|
|
|
|
|
|
def format_mpf(num, format_spec, prec, rnd, _pretty_repr_dps):
|
|
format_dict = read_format_spec(format_spec)
|
|
sign, digits = format_digits(num, format_dict, prec, rnd, _pretty_repr_dps)
|
|
nchars = len(digits) + len(sign)
|
|
lpad, rpad = calc_padding(
|
|
nchars, format_dict['width'], format_dict['align'])
|
|
|
|
if format_dict['align'] == '=':
|
|
return sign + lpad*format_dict['fill_char'] + digits + \
|
|
rpad*format_dict['fill_char']
|
|
|
|
return lpad*format_dict['fill_char'] + sign + digits \
|
|
+ rpad*format_dict['fill_char']
|
|
|
|
|
|
def format_mpc(num, format_spec, prec, rnd, _pretty_repr_dps):
|
|
format_dict = read_format_spec(format_spec)
|
|
|
|
if format_dict['fill_char'] == '0':
|
|
raise ValueError("Zero padding is not allowed in complex format "
|
|
"specifier.")
|
|
if format_dict['align'] == '=':
|
|
raise ValueError("'=' alignment flag is not allowed in complex format "
|
|
"specifier.")
|
|
if format_dict['type'] == '%':
|
|
raise ValueError("'%' formatting type is not allowed in complex "
|
|
"format specifier.")
|
|
|
|
fmt_type = format_dict['type'].lower()
|
|
if not fmt_type:
|
|
format_dict['type'] = 'g'
|
|
sign_re, digits_re = format_digits(num[0], format_dict, prec, rnd, _pretty_repr_dps)
|
|
fmt_sign = format_dict['sign']
|
|
format_dict['sign'] = '+'
|
|
sign_im, digits_im = format_digits(num[1], format_dict, prec, rnd, _pretty_repr_dps)
|
|
digits_im += 'j'
|
|
|
|
if not fmt_type:
|
|
if num[0] == fzero:
|
|
sign_re = ''
|
|
digits_re = ''
|
|
if sign_im == '+':
|
|
sign_im = fmt_sign if fmt_sign in [' ', '+'] else ''
|
|
else:
|
|
sign_re = '(' + sign_re
|
|
digits_im += ')'
|
|
|
|
nchars = len(sign_re) + len(digits_re) + len(sign_im) + len(digits_im)
|
|
|
|
lpad, rpad = calc_padding(nchars, format_dict['width'],
|
|
format_dict['align'])
|
|
|
|
return (lpad*format_dict['fill_char'] + sign_re + digits_re + sign_im
|
|
+ digits_im + rpad*format_dict['fill_char'])
|
|
|
|
|
|
#----------------------------------------------------------------------------#
|
|
# Square roots #
|
|
#----------------------------------------------------------------------------#
|
|
|
|
|
|
def mpf_sqrt(s, prec, rnd=round_down):
|
|
"""
|
|
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 normalize(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_down):
|
|
"""Compute the Euclidean norm sqrt(x**2 + y**2) 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+10, rnd)
|
|
return mpf_sqrt(hypot2, prec, rnd)
|