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207 lines
5.9 KiB
207 lines
5.9 KiB
"""Implementation of :class:`FiniteField` class. """
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from sympy.polys.domains.field import Field
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from sympy.polys.domains.modularinteger import ModularIntegerFactory
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from sympy.polys.domains.simpledomain import SimpleDomain
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from sympy.polys.polyerrors import CoercionFailed
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from sympy.utilities import public
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from sympy.polys.domains.groundtypes import SymPyInteger
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@public
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class FiniteField(Field, SimpleDomain):
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r"""Finite field of prime order :ref:`GF(p)`
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A :ref:`GF(p)` domain represents a `finite field`_ `\mathbb{F}_p` of prime
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order as :py:class:`~.Domain` in the domain system (see
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:ref:`polys-domainsintro`).
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A :py:class:`~.Poly` created from an expression with integer
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coefficients will have the domain :ref:`ZZ`. However, if the ``modulus=p``
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option is given then the domain will be a finite field instead.
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>>> from sympy import Poly, Symbol
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>>> x = Symbol('x')
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>>> p = Poly(x**2 + 1)
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>>> p
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Poly(x**2 + 1, x, domain='ZZ')
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>>> p.domain
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ZZ
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>>> p2 = Poly(x**2 + 1, modulus=2)
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>>> p2
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Poly(x**2 + 1, x, modulus=2)
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>>> p2.domain
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GF(2)
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It is possible to factorise a polynomial over :ref:`GF(p)` using the
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modulus argument to :py:func:`~.factor` or by specifying the domain
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explicitly. The domain can also be given as a string.
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>>> from sympy import factor, GF
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>>> factor(x**2 + 1)
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x**2 + 1
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>>> factor(x**2 + 1, modulus=2)
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(x + 1)**2
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>>> factor(x**2 + 1, domain=GF(2))
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(x + 1)**2
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>>> factor(x**2 + 1, domain='GF(2)')
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(x + 1)**2
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It is also possible to use :ref:`GF(p)` with the :py:func:`~.cancel`
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and :py:func:`~.gcd` functions.
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>>> from sympy import cancel, gcd
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>>> cancel((x**2 + 1)/(x + 1))
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(x**2 + 1)/(x + 1)
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>>> cancel((x**2 + 1)/(x + 1), domain=GF(2))
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x + 1
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>>> gcd(x**2 + 1, x + 1)
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1
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>>> gcd(x**2 + 1, x + 1, domain=GF(2))
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x + 1
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When using the domain directly :ref:`GF(p)` can be used as a constructor
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to create instances which then support the operations ``+,-,*,**,/``
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>>> from sympy import GF
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>>> K = GF(5)
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>>> K
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GF(5)
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>>> x = K(3)
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>>> y = K(2)
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>>> x
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3 mod 5
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>>> y
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2 mod 5
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>>> x * y
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1 mod 5
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>>> x / y
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4 mod 5
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Notes
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=====
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It is also possible to create a :ref:`GF(p)` domain of **non-prime**
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order but the resulting ring is **not** a field: it is just the ring of
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the integers modulo ``n``.
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>>> K = GF(9)
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>>> z = K(3)
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>>> z
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3 mod 9
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>>> z**2
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0 mod 9
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It would be good to have a proper implementation of prime power fields
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(``GF(p**n)``) but these are not yet implemented in SymPY.
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.. _finite field: https://en.wikipedia.org/wiki/Finite_field
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"""
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rep = 'FF'
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alias = 'FF'
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is_FiniteField = is_FF = True
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is_Numerical = True
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has_assoc_Ring = False
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has_assoc_Field = True
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dom = None
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mod = None
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def __init__(self, mod, symmetric=True):
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from sympy.polys.domains import ZZ
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dom = ZZ
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if mod <= 0:
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raise ValueError('modulus must be a positive integer, got %s' % mod)
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self.dtype = ModularIntegerFactory(mod, dom, symmetric, self)
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self.zero = self.dtype(0)
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self.one = self.dtype(1)
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self.dom = dom
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self.mod = mod
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def __str__(self):
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return 'GF(%s)' % self.mod
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def __hash__(self):
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return hash((self.__class__.__name__, self.dtype, self.mod, self.dom))
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def __eq__(self, other):
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"""Returns ``True`` if two domains are equivalent. """
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return isinstance(other, FiniteField) and \
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self.mod == other.mod and self.dom == other.dom
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def characteristic(self):
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"""Return the characteristic of this domain. """
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return self.mod
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def get_field(self):
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"""Returns a field associated with ``self``. """
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return self
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def to_sympy(self, a):
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"""Convert ``a`` to a SymPy object. """
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return SymPyInteger(int(a))
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def from_sympy(self, a):
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"""Convert SymPy's Integer to SymPy's ``Integer``. """
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if a.is_Integer:
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return self.dtype(self.dom.dtype(int(a)))
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elif a.is_Float and int(a) == a:
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return self.dtype(self.dom.dtype(int(a)))
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else:
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raise CoercionFailed("expected an integer, got %s" % a)
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def from_FF(K1, a, K0=None):
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"""Convert ``ModularInteger(int)`` to ``dtype``. """
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return K1.dtype(K1.dom.from_ZZ(a.val, K0.dom))
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def from_FF_python(K1, a, K0=None):
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"""Convert ``ModularInteger(int)`` to ``dtype``. """
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return K1.dtype(K1.dom.from_ZZ_python(a.val, K0.dom))
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def from_ZZ(K1, a, K0=None):
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"""Convert Python's ``int`` to ``dtype``. """
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return K1.dtype(K1.dom.from_ZZ_python(a, K0))
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def from_ZZ_python(K1, a, K0=None):
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"""Convert Python's ``int`` to ``dtype``. """
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return K1.dtype(K1.dom.from_ZZ_python(a, K0))
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def from_QQ(K1, a, K0=None):
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"""Convert Python's ``Fraction`` to ``dtype``. """
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if a.denominator == 1:
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return K1.from_ZZ_python(a.numerator)
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def from_QQ_python(K1, a, K0=None):
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"""Convert Python's ``Fraction`` to ``dtype``. """
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if a.denominator == 1:
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return K1.from_ZZ_python(a.numerator)
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def from_FF_gmpy(K1, a, K0=None):
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"""Convert ``ModularInteger(mpz)`` to ``dtype``. """
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return K1.dtype(K1.dom.from_ZZ_gmpy(a.val, K0.dom))
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def from_ZZ_gmpy(K1, a, K0=None):
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"""Convert GMPY's ``mpz`` to ``dtype``. """
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return K1.dtype(K1.dom.from_ZZ_gmpy(a, K0))
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def from_QQ_gmpy(K1, a, K0=None):
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"""Convert GMPY's ``mpq`` to ``dtype``. """
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if a.denominator == 1:
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return K1.from_ZZ_gmpy(a.numerator)
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def from_RealField(K1, a, K0):
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"""Convert mpmath's ``mpf`` to ``dtype``. """
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p, q = K0.to_rational(a)
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if q == 1:
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return K1.dtype(K1.dom.dtype(p))
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FF = GF = FiniteField
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