# Originally contributed by Sjoerd Mullender. # Significantly modified by Jeffrey Yasskin . """Rational, infinite-precision, real numbers.""" import math import numbers import operator import re __all__ = ["Rational"] RationalAbc = numbers.Rational def _gcd(a, b): """Calculate the Greatest Common Divisor. Unless b==0, the result will have the same sign as b (so that when b is divided by it, the result comes out positive). """ while b: a, b = b, a%b return a def _binary_float_to_ratio(x): """x -> (top, bot), a pair of ints s.t. x = top/bot. The conversion is done exactly, without rounding. bot > 0 guaranteed. Some form of binary fp is assumed. Pass NaNs or infinities at your own risk. >>> _binary_float_to_ratio(10.0) (10, 1) >>> _binary_float_to_ratio(0.0) (0, 1) >>> _binary_float_to_ratio(-.25) (-1, 4) """ if x == 0: return 0, 1 f, e = math.frexp(x) signbit = 1 if f < 0: f = -f signbit = -1 assert 0.5 <= f < 1.0 # x = signbit * f * 2**e exactly # Suck up CHUNK bits at a time; 28 is enough so that we suck # up all bits in 2 iterations for all known binary double- # precision formats, and small enough to fit in an int. CHUNK = 28 top = 0 # invariant: x = signbit * (top + f) * 2**e exactly while f: f = math.ldexp(f, CHUNK) digit = trunc(f) assert digit >> CHUNK == 0 top = (top << CHUNK) | digit f = f - digit assert 0.0 <= f < 1.0 e = e - CHUNK assert top # Add in the sign bit. top = signbit * top # now x = top * 2**e exactly; fold in 2**e if e>0: return (top * 2**e, 1) else: return (top, 2 ** -e) _RATIONAL_FORMAT = re.compile( r'^\s*(?P[-+]?)(?P\d+)(?:/(?P\d+))?\s*$') class Rational(RationalAbc): """This class implements rational numbers. Rational(8, 6) will produce a rational number equivalent to 4/3. Both arguments must be Integral. The numerator defaults to 0 and the denominator defaults to 1 so that Rational(3) == 3 and Rational() == 0. Rationals can also be constructed from strings of the form '[-+]?[0-9]+(/[0-9]+)?', optionally surrounded by spaces. """ __slots__ = ('_numerator', '_denominator') # We're immutable, so use __new__ not __init__ def __new__(cls, numerator=0, denominator=1): """Constructs a Rational. Takes a string, another Rational, or a numerator/denominator pair. """ self = super(Rational, cls).__new__(cls) if denominator == 1: if isinstance(numerator, str): # Handle construction from strings. input = numerator m = _RATIONAL_FORMAT.match(input) if m is None: raise ValueError('Invalid literal for Rational: ' + input) numerator = int(m.group('num')) # Default denominator to 1. That's the only optional group. denominator = int(m.group('denom') or 1) if m.group('sign') == '-': numerator = -numerator elif (not isinstance(numerator, numbers.Integral) and isinstance(numerator, RationalAbc)): # Handle copies from other rationals. other_rational = numerator numerator = other_rational.numerator denominator = other_rational.denominator if (not isinstance(numerator, numbers.Integral) or not isinstance(denominator, numbers.Integral)): raise TypeError("Rational(%(numerator)s, %(denominator)s):" " Both arguments must be integral." % locals()) if denominator == 0: raise ZeroDivisionError('Rational(%s, 0)' % numerator) g = _gcd(numerator, denominator) self._numerator = int(numerator // g) self._denominator = int(denominator // g) return self @classmethod def from_float(cls, f): """Converts a finite float to a rational number, exactly. Beware that Rational.from_float(0.3) != Rational(3, 10). """ if not isinstance(f, float): raise TypeError("%s.from_float() only takes floats, not %r (%s)" % (cls.__name__, f, type(f).__name__)) if math.isnan(f) or math.isinf(f): raise TypeError("Cannot convert %r to %s." % (f, cls.__name__)) return cls(*_binary_float_to_ratio(f)) @classmethod def from_decimal(cls, dec): """Converts a finite Decimal instance to a rational number, exactly.""" from decimal import Decimal if not isinstance(dec, Decimal): raise TypeError( "%s.from_decimal() only takes Decimals, not %r (%s)" % (cls.__name__, dec, type(dec).__name__)) if not dec.is_finite(): # Catches infinities and nans. raise TypeError("Cannot convert %s to %s." % (dec, cls.__name__)) sign, digits, exp = dec.as_tuple() digits = int(''.join(map(str, digits))) if sign: digits = -digits if exp >= 0: return cls(digits * 10 ** exp) else: return cls(digits, 10 ** -exp) @property def numerator(a): return a._numerator @property def denominator(a): return a._denominator def __repr__(self): """repr(self)""" return ('Rational(%r,%r)' % (self.numerator, self.denominator)) def __str__(self): """str(self)""" if self.denominator == 1: return str(self.numerator) else: return '%s/%s' % (self.numerator, self.denominator) def _operator_fallbacks(monomorphic_operator, fallback_operator): """Generates forward and reverse operators given a purely-rational operator and a function from the operator module. Use this like: __op__, __rop__ = _operator_fallbacks(just_rational_op, operator.op) """ def forward(a, b): if isinstance(b, RationalAbc): # Includes ints. return monomorphic_operator(a, b) elif isinstance(b, float): return fallback_operator(float(a), b) elif isinstance(b, complex): return fallback_operator(complex(a), b) else: return NotImplemented forward.__name__ = '__' + fallback_operator.__name__ + '__' forward.__doc__ = monomorphic_operator.__doc__ def reverse(b, a): if isinstance(a, RationalAbc): # Includes ints. return monomorphic_operator(a, b) elif isinstance(a, numbers.Real): return fallback_operator(float(a), float(b)) elif isinstance(a, numbers.Complex): return fallback_operator(complex(a), complex(b)) else: return NotImplemented reverse.__name__ = '__r' + fallback_operator.__name__ + '__' reverse.__doc__ = monomorphic_operator.__doc__ return forward, reverse def _add(a, b): """a + b""" return Rational(a.numerator * b.denominator + b.numerator * a.denominator, a.denominator * b.denominator) __add__, __radd__ = _operator_fallbacks(_add, operator.add) def _sub(a, b): """a - b""" return Rational(a.numerator * b.denominator - b.numerator * a.denominator, a.denominator * b.denominator) __sub__, __rsub__ = _operator_fallbacks(_sub, operator.sub) def _mul(a, b): """a * b""" return Rational(a.numerator * b.numerator, a.denominator * b.denominator) __mul__, __rmul__ = _operator_fallbacks(_mul, operator.mul) def _div(a, b): """a / b""" return Rational(a.numerator * b.denominator, a.denominator * b.numerator) __truediv__, __rtruediv__ = _operator_fallbacks(_div, operator.truediv) def __floordiv__(a, b): """a // b""" return math.floor(a / b) def __rfloordiv__(b, a): """a // b""" return math.floor(a / b) @classmethod def _mod(cls, a, b): div = a // b return a - b * div def __mod__(a, b): """a % b""" return a._mod(a, b) def __rmod__(b, a): """a % b""" return b._mod(a, b) def __pow__(a, b): """a ** b If b is not an integer, the result will be a float or complex since roots are generally irrational. If b is an integer, the result will be rational. """ if isinstance(b, RationalAbc): if b.denominator == 1: power = b.numerator if power >= 0: return Rational(a.numerator ** power, a.denominator ** power) else: return Rational(a.denominator ** -power, a.numerator ** -power) else: # A fractional power will generally produce an # irrational number. return float(a) ** float(b) else: return float(a) ** b def __rpow__(b, a): """a ** b""" if b.denominator == 1 and b.numerator >= 0: # If a is an int, keep it that way if possible. return a ** b.numerator if isinstance(a, RationalAbc): return Rational(a.numerator, a.denominator) ** b if b.denominator == 1: return a ** b.numerator return a ** float(b) def __pos__(a): """+a: Coerces a subclass instance to Rational""" return Rational(a.numerator, a.denominator) def __neg__(a): """-a""" return Rational(-a.numerator, a.denominator) def __abs__(a): """abs(a)""" return Rational(abs(a.numerator), a.denominator) def __trunc__(a): """trunc(a)""" if a.numerator < 0: return -(-a.numerator // a.denominator) else: return a.numerator // a.denominator def __floor__(a): """Will be math.floor(a) in 3.0.""" return a.numerator // a.denominator def __ceil__(a): """Will be math.ceil(a) in 3.0.""" # The negations cleverly convince floordiv to return the ceiling. return -(-a.numerator // a.denominator) def __round__(self, ndigits=None): """Will be round(self, ndigits) in 3.0. Rounds half toward even. """ if ndigits is None: floor, remainder = divmod(self.numerator, self.denominator) if remainder * 2 < self.denominator: return floor elif remainder * 2 > self.denominator: return floor + 1 # Deal with the half case: elif floor % 2 == 0: return floor else: return floor + 1 shift = 10**abs(ndigits) # See _operator_fallbacks.forward to check that the results of # these operations will always be Rational and therefore have # round(). if ndigits > 0: return Rational(round(self * shift), shift) else: return Rational(round(self / shift) * shift) def __hash__(self): """hash(self) Tricky because values that are exactly representable as a float must have the same hash as that float. """ if self.denominator == 1: # Get integers right. return hash(self.numerator) # Expensive check, but definitely correct. if self == float(self): return hash(float(self)) else: # Use tuple's hash to avoid a high collision rate on # simple fractions. return hash((self.numerator, self.denominator)) def __eq__(a, b): """a == b""" if isinstance(b, RationalAbc): return (a.numerator == b.numerator and a.denominator == b.denominator) if isinstance(b, numbers.Complex) and b.imag == 0: b = b.real if isinstance(b, float): return a == a.from_float(b) else: # XXX: If b.__eq__ is implemented like this method, it may # give the wrong answer after float(a) changes a's # value. Better ways of doing this are welcome. return float(a) == b def _subtractAndCompareToZero(a, b, op): """Helper function for comparison operators. Subtracts b from a, exactly if possible, and compares the result with 0 using op, in such a way that the comparison won't recurse. If the difference raises a TypeError, returns NotImplemented instead. """ if isinstance(b, numbers.Complex) and b.imag == 0: b = b.real if isinstance(b, float): b = a.from_float(b) try: # XXX: If b <: Real but not <: RationalAbc, this is likely # to fall back to a float. If the actual values differ by # less than MIN_FLOAT, this could falsely call them equal, # which would make <= inconsistent with ==. Better ways of # doing this are welcome. diff = a - b except TypeError: return NotImplemented if isinstance(diff, RationalAbc): return op(diff.numerator, 0) return op(diff, 0) def __lt__(a, b): """a < b""" return a._subtractAndCompareToZero(b, operator.lt) def __gt__(a, b): """a > b""" return a._subtractAndCompareToZero(b, operator.gt) def __le__(a, b): """a <= b""" return a._subtractAndCompareToZero(b, operator.le) def __ge__(a, b): """a >= b""" return a._subtractAndCompareToZero(b, operator.ge) def __bool__(a): """a != 0""" return a.numerator != 0