# Copyright 2007 Google, Inc. All Rights Reserved. # Licensed to PSF under a Contributor Agreement. """Abstract Base Classes (ABCs) for numbers, according to PEP 3141. TODO: Fill out more detailed documentation on the operators.""" from abc import ABCMeta, abstractmethod, abstractproperty __all__ = ["Number", "Exact", "Inexact", "Complex", "Real", "Rational", "Integral", ] class Number(object): """All numbers inherit from this class. If you just want to check if an argument x is a number, without caring what kind, use isinstance(x, Number). """ __metaclass__ = ABCMeta class Exact(Number): """Operations on instances of this type are exact. As long as the result of a homogenous operation is of the same type, you can assume that it was computed exactly, and there are no round-off errors. Laws like commutativity and associativity hold. """ Exact.register(int) Exact.register(long) class Inexact(Number): """Operations on instances of this type are inexact. Given X, an instance of Inexact, it is possible that (X + -X) + 3 == 3, but X + (-X + 3) == 0. The exact form this error takes will vary by type, but it's generally unsafe to compare this type for equality. """ Inexact.register(complex) Inexact.register(float) # Inexact.register(decimal.Decimal) class Complex(Number): """Complex defines the operations that work on the builtin complex type. In short, those are: a conversion to complex, .real, .imag, +, -, *, /, abs(), .conjugate, ==, and !=. If it is given heterogenous arguments, and doesn't have special knowledge about them, it should fall back to the builtin complex type as described below. """ @abstractmethod def __complex__(self): """Return a builtin complex instance. Called for complex(self).""" def __bool__(self): """True if self != 0. Called for bool(self).""" return self != 0 @abstractproperty def real(self): """Retrieve the real component of this number. This should subclass Real. """ raise NotImplementedError @abstractproperty def imag(self): """Retrieve the real component of this number. This should subclass Real. """ raise NotImplementedError @abstractmethod def __add__(self, other): """self + other""" raise NotImplementedError @abstractmethod def __radd__(self, other): """other + self""" raise NotImplementedError @abstractmethod def __neg__(self): """-self""" raise NotImplementedError def __pos__(self): """+self""" raise NotImplementedError def __sub__(self, other): """self - other""" return self + -other def __rsub__(self, other): """other - self""" return -self + other @abstractmethod def __mul__(self, other): """self * other""" raise NotImplementedError @abstractmethod def __rmul__(self, other): """other * self""" raise NotImplementedError @abstractmethod def __div__(self, other): """self / other; should promote to float or complex when necessary.""" raise NotImplementedError @abstractmethod def __rdiv__(self, other): """other / self""" raise NotImplementedError @abstractmethod def __pow__(self, exponent): """self**exponent; should promote to float or complex when necessary.""" raise NotImplementedError @abstractmethod def __rpow__(self, base): """base ** self""" raise NotImplementedError @abstractmethod def __abs__(self): """Returns the Real distance from 0. Called for abs(self).""" raise NotImplementedError @abstractmethod def conjugate(self): """(x+y*i).conjugate() returns (x-y*i).""" raise NotImplementedError @abstractmethod def __eq__(self, other): """self == other""" raise NotImplementedError # __ne__ is inherited from object and negates whatever __eq__ does. Complex.register(complex) class Real(Complex): """To Complex, Real adds the operations that work on real numbers. In short, those are: a conversion to float, trunc(), divmod, %, <, <=, >, and >=. Real also provides defaults for the derived operations. """ @abstractmethod def __float__(self): """Any Real can be converted to a native float object. Called for float(self).""" raise NotImplementedError @abstractmethod def __trunc__(self): """trunc(self): Truncates self to an Integral. Returns an Integral i such that: * i>0 iff self>0; * abs(i) <= abs(self); * for any Integral j satisfying the first two conditions, abs(i) >= abs(j) [i.e. i has "maximal" abs among those]. i.e. "truncate towards 0". """ raise NotImplementedError @abstractmethod def __floor__(self): """Finds the greatest Integral <= self.""" raise NotImplementedError @abstractmethod def __ceil__(self): """Finds the least Integral >= self.""" raise NotImplementedError @abstractmethod def __round__(self, ndigits=None): """Rounds self to ndigits decimal places, defaulting to 0. If ndigits is omitted or None, returns an Integral, otherwise returns a Real. Rounds half toward even. """ raise NotImplementedError def __divmod__(self, other): """divmod(self, other): The pair (self // other, self % other). Sometimes this can be computed faster than the pair of operations. """ return (self // other, self % other) def __rdivmod__(self, other): """divmod(other, self): The pair (self // other, self % other). Sometimes this can be computed faster than the pair of operations. """ return (other // self, other % self) @abstractmethod def __floordiv__(self, other): """self // other: The floor() of self/other.""" raise NotImplementedError @abstractmethod def __rfloordiv__(self, other): """other // self: The floor() of other/self.""" raise NotImplementedError @abstractmethod def __mod__(self, other): """self % other""" raise NotImplementedError @abstractmethod def __rmod__(self, other): """other % self""" raise NotImplementedError @abstractmethod def __lt__(self, other): """self < other < on Reals defines a total ordering, except perhaps for NaN.""" raise NotImplementedError @abstractmethod def __le__(self, other): """self <= other""" raise NotImplementedError # Concrete implementations of Complex abstract methods. def __complex__(self): """complex(self) == complex(float(self), 0)""" return complex(float(self)) @property def real(self): """Real numbers are their real component.""" return +self @property def imag(self): """Real numbers have no imaginary component.""" return 0 def conjugate(self): """Conjugate is a no-op for Reals.""" return +self Real.register(float) # Real.register(decimal.Decimal) class Rational(Real, Exact): """.numerator and .denominator should be in lowest terms.""" @abstractproperty def numerator(self): raise NotImplementedError @abstractproperty def denominator(self): raise NotImplementedError # Concrete implementation of Real's conversion to float. def __float__(self): """float(self) = self.numerator / self.denominator""" return self.numerator / self.denominator class Integral(Rational): """Integral adds a conversion to long and the bit-string operations.""" @abstractmethod def __long__(self): """long(self)""" raise NotImplementedError def __index__(self): """index(self)""" return long(self) @abstractmethod def __pow__(self, exponent, modulus=None): """self ** exponent % modulus, but maybe faster. Accept the modulus argument if you want to support the 3-argument version of pow(). Raise a TypeError if exponent < 0 or any argument isn't Integral. Otherwise, just implement the 2-argument version described in Complex. """ raise NotImplementedError @abstractmethod def __lshift__(self, other): """self << other""" raise NotImplementedError @abstractmethod def __rlshift__(self, other): """other << self""" raise NotImplementedError @abstractmethod def __rshift__(self, other): """self >> other""" raise NotImplementedError @abstractmethod def __rrshift__(self, other): """other >> self""" raise NotImplementedError @abstractmethod def __and__(self, other): """self & other""" raise NotImplementedError @abstractmethod def __rand__(self, other): """other & self""" raise NotImplementedError @abstractmethod def __xor__(self, other): """self ^ other""" raise NotImplementedError @abstractmethod def __rxor__(self, other): """other ^ self""" raise NotImplementedError @abstractmethod def __or__(self, other): """self | other""" raise NotImplementedError @abstractmethod def __ror__(self, other): """other | self""" raise NotImplementedError @abstractmethod def __invert__(self): """~self""" raise NotImplementedError # Concrete implementations of Rational and Real abstract methods. def __float__(self): """float(self) == float(long(self))""" return float(long(self)) @property def numerator(self): """Integers are their own numerators.""" return +self @property def denominator(self): """Integers have a denominator of 1.""" return 1 Integral.register(int) Integral.register(long)