def __init__(self, field = None):
"""
Create a linear feedback shift cryptosystem.
INPUT: A string monoid over a binary alphabet.
OUTPUT:
EXAMPLES::
sage: E = LFSRCryptosystem(FiniteField(2))
sage: E
LFSR cryptosystem over Finite Field of size 2
TESTS::
sage: E = LFSRCryptosystem(FiniteField(2))
sage: E == loads(dumps(E))
True
TODO: Implement LFSR cryptosystem for arbitrary rings. The current
implementation is limited to the finite field of 2 elements only
because of the dependence on binary strings.
"""
if field is None:
field = FiniteField(2)
if field.cardinality() != 2:
raise NotImplementedError("Not yet implemented.")
S = BinaryStrings()
P = PolynomialRing(FiniteField(2),'x')
SymmetricKeyCryptosystem.__init__(self, S, S, None)
self._field = field
def __init__(self, field = None):
"""
Create a shrinking generator cryptosystem.
INPUT: A string monoid over a binary alphabet.
OUTPUT:
EXAMPLES::
sage: E = ShrinkingGeneratorCryptosystem()
sage: E
Shrinking generator cryptosystem over Finite Field of size 2
"""
if field is None:
field = FiniteField(2)
if field.cardinality() != 2:
raise NotImplementedError("Not yet implemented.")
S = BinaryStrings()
P = PolynomialRing(field, 'x')
SymmetricKeyCryptosystem.__init__(self, S, S, None)
self._field = field
