Stream Cryptosystems

class sage.crypto.stream.LFSRCryptosystem(field=None)

Bases: sage.crypto.cryptosystem.SymmetricKeyCryptosystem

Linear feedback shift register cryptosystem class

encoding(M)
class sage.crypto.stream.ShrinkingGeneratorCryptosystem(field=None)

Bases: sage.crypto.cryptosystem.SymmetricKeyCryptosystem

Shrinking generator cryptosystem class

encoding(M)
sage.crypto.stream.blum_blum_shub(length, seed=None, p=None, q=None, lbound=None, ubound=None, ntries=100)

The Blum-Blum-Shub (BBS) pseudorandom bit generator.

See the original paper by Blum, Blum and Shub [BBS1986]. The BBS algorithm is also discussed in section 5.5.2 of [MvOV1996].

INPUT:

  • length – positive integer; the number of bits in the output pseudorandom bit sequence.
  • seed – (default: None) if \(p\) and \(q\) are Blum primes, then seed is a quadratic residue in the multiplicative group \((\ZZ/n\ZZ)^{\ast}\) where \(n = pq\). If seed=None, then the function would generate its own random quadratic residue in \((\ZZ/n\ZZ)^{\ast}\). If you provide a value for seed, then it is your responsibility to ensure that the seed is a quadratic residue in the multiplicative group \((\ZZ/n\ZZ)^{\ast}\).
  • p – (default: None) a large positive prime congruent to 3 modulo 4. Both p and q must be distinct. If p=None, then a value for p will be generated, where 0 < lower_bound <= p <= upper_bound.
  • q – (default: None) a large positive prime congruence to 3 modulo 4. Both p and q must be distinct. If q=None, then a value for q will be generated, where 0 < lower_bound <= q <= upper_bound.
  • lbound – (positive integer, default: None) the lower bound on how small each random primes \(p\) and \(q\) can be. So we have 0 < lbound <= p, q <= ubound. The lower bound must be distinct from the upper bound.
  • ubound – (positive integer, default: None) the upper bound on how large each random primes \(p\) and \(q\) can be. So we have 0 < lbound <= p, q <= ubound. The lower bound must be distinct from the upper bound.
  • ntries – (default: 100) the number of attempts to generate a random Blum prime. If ntries is a positive integer, then perform that many attempts at generating a random Blum prime. This might or might not result in a Blum prime.

OUTPUT:

  • A pseudorandom bit sequence whose length is specified by length.

Here is a common use case for this function. If you want this function to use pre-computed values for \(p\) and \(q\), you should pass those pre-computed values to this function. In that case, you only need to specify values for length, p and q, and you do not need to worry about doing anything with the parameters lbound and ubound. The pre-computed values \(p\) and \(q\) must be Blum primes. It is your responsibility to check that both \(p\) and \(q\) are Blum primes.

Here is another common use case. If you want the function to generate its own values for \(p\) and \(q\), you must specify the lower and upper bounds within which these two primes must lie. In that case, you must specify values for length, lbound and ubound, and you do not need to worry about values for the parameters p and q. The parameter ntries is only relevant when you want this function to generate p and q.

Note

Beware that there might not be any primes between the lower and upper bounds. So make sure that these two bounds are “sufficiently” far apart from each other for there to be primes congruent to 3 modulo 4. In particular, there should be at least two distinct primes within these bounds, each prime being congruent to 3 modulo 4. This function uses the function random_blum_prime() to generate random primes that are congruent to 3 modulo 4.

ALGORITHM:

The BBS algorithm as described below is adapted from the presentation in Algorithm 5.40, page 186 of [MvOV1996].

  1. Let \(L\) be the desired number of bits in the output bit sequence. That is, \(L\) is the desired length of the bit string.
  2. Let \(p\) and \(q\) be two large distinct primes, each congruent to 3 modulo 4.
  3. Let \(n = pq\) be the product of \(p\) and \(q\).
  4. Select a random seed value \(s \in (\ZZ/n\ZZ)^{\ast}\), where \((\ZZ/n\ZZ)^{\ast}\) is the multiplicative group of \(\ZZ/n\ZZ\).
  5. Let \(x_0 = s^2 \bmod n\).
  6. For \(i\) from 1 to \(L\), do
    1. Let \(x_i = x_{i-1}^2 \bmod n\).
    2. Let \(z_i\) be the least significant bit of \(x_i\).
  7. The output pseudorandom bit sequence is \(z_1, z_2, \dots, z_L\).

EXAMPLES:

A BBS pseudorandom bit sequence with a specified seed:

sage: from sage.crypto.stream import blum_blum_shub
sage: blum_blum_shub(length=6, seed=3, p=11, q=19)
110000

You could specify the length of the bit string, with given values for p and q:

sage: blum_blum_shub(length=6, p=11, q=19)  # random
001011

Or you could specify the length of the bit string, with given values for the lower and upper bounds:

sage: blum_blum_shub(length=6, lbound=10**4, ubound=10**5)  # random
110111

Under some reasonable hypotheses, Blum-Blum-Shub [BBS1982] sketch a proof that the period of the BBS stream cipher is equal to \(\lambda(\lambda(n))\), where \(\lambda(n)\) is the Carmichael function of \(n\). This is verified below in a few examples by using the function lfsr_connection_polynomial() (written by Tim Brock) which computes the connection polynomial of a linear feedback shift register sequence. The degree of that polynomial is the period.

sage: from sage.crypto.stream import blum_blum_shub
sage: from sage.crypto.util import carmichael_lambda
sage: carmichael_lambda(carmichael_lambda(7*11))
4
sage: s = [GF(2)(int(str(x))) for x in blum_blum_shub(60, p=7, q=11, seed=13)]
sage: lfsr_connection_polynomial(s)
x^3 + x^2 + x + 1
sage: carmichael_lambda(carmichael_lambda(11*23))
20
sage: s = [GF(2)(int(str(x))) for x in blum_blum_shub(60, p=11, q=23, seed=13)]
sage: lfsr_connection_polynomial(s)
x^19 + x^18 + x^17 + x^16 + x^15 + x^14 + x^13 + x^12 + x^11 + x^10 + x^9 + x^8 + x^7 + x^6 + x^5 + x^4 + x^3 + x^2 + x + 1