Integer factorization functions#
AUTHORS:
Andre Apitzsch (2011-01-13): initial version
- sage.rings.factorint.aurifeuillian(n, m, F=None, check=True)#
Return the Aurifeuillian factors \(F_n^\pm(m^2n)\).
This is based off Theorem 3 of [Bre1993].
INPUT:
n– integerm– integerF– integer (default:None)check– boolean (default:True)
OUTPUT:
A list of factors.
EXAMPLES:
sage: from sage.rings.factorint import aurifeuillian sage: aurifeuillian(2,2) [5, 13] sage: aurifeuillian(2,2^5) [1985, 2113] sage: aurifeuillian(5,3) [1471, 2851] sage: aurifeuillian(15,1) [19231, 142111] sage: aurifeuillian(12,3) Traceback (most recent call last): ... ValueError: n has to be square-free sage: aurifeuillian(1,2) Traceback (most recent call last): ... ValueError: n has to be greater than 1 sage: aurifeuillian(2,0) Traceback (most recent call last): ... ValueError: m has to be positive
Note
There is no need to set \(F\). It’s only for increasing speed of
factor_aurifeuillian().
- sage.rings.factorint.factor_aurifeuillian(n, check=True)#
Return Aurifeuillian factors of \(n\) if \(n = x^{(2k-1)x} \pm 1\) (where the sign is ‘-’ if x = 1 mod 4, and ‘+’ otherwise) else \(n\)
INPUT:
n– integer
OUTPUT:
List of factors of \(n\) found by Aurifeuillian factorization.
EXAMPLES:
sage: from sage.rings.factorint import factor_aurifeuillian as fa sage: fa(2^6+1) [5, 13] sage: fa(2^58+1) [536838145, 536903681] sage: fa(3^3+1) [4, 1, 7] sage: fa(5^5-1) [4, 11, 71] sage: prod(_) == 5^5-1 True sage: fa(2^4+1) [17] sage: fa((6^2*3)^3+1) [109, 91, 127]
REFERENCES:
- sage.rings.factorint.factor_cunningham(m, proof=None)#
Return factorization of self obtained using trial division for all primes in the so called Cunningham table. This is efficient if self has some factors of type \(b^n+1\) or \(b^n-1\), with \(b\) in \(\{2,3,5,6,7,10,11,12\}\).
You need to install an optional package to use this method, this can be done with the following command line:
sage -i cunningham_tables.INPUT:
proof– bool (default:None); whether or not to prove primality of each factor, this is only for factors not in the Cunningham table
EXAMPLES:
sage: from sage.rings.factorint import factor_cunningham sage: factor_cunningham(2^257-1) # optional - cunningham_tables 535006138814359 * 1155685395246619182673033 * 374550598501810936581776630096313181393 sage: factor_cunningham((3^101+1)*(2^60).next_prime(),proof=False) # optional - cunningham_tables 2^2 * 379963 * 1152921504606847009 * 1017291527198723292208309354658785077827527
- sage.rings.factorint.factor_trial_division(m, limit='LONG_MAX')#
Return partial factorization of self obtained using trial division for all primes up to limit, where limit must fit in a C signed long.
INPUT:
limit– integer (default:LONG_MAX) that fits in a C signed long
EXAMPLES:
sage: from sage.rings.factorint import factor_trial_division sage: n = 920384092842390423848290348203948092384082349082 sage: factor_trial_division(n, 1000) 2 * 11 * 41835640583745019265831379463815822381094652231 sage: factor_trial_division(n, 2000) 2 * 11 * 1531 * 27325696005058797691594630609938486205809701
- sage.rings.factorint.factor_using_pari(n, int_=False, debug_level=0, proof=None)#
Factor this integer using PARI.
This function returns a list of pairs, not a
Factorizationobject. The first element of each pair is the factor, of typeIntegerifint_isFalseorintotherwise, the second element is the positive exponent, of typeint.INPUT:
int_– (default:False), whether the factors are of typeintinstead ofIntegerdebug_level– (default: 0), debug level of the call to PARIproof– (default:None), whether the factors are required to be proven prime; ifNone, the global default is used
OUTPUT:
A list of pairs.
EXAMPLES:
sage: factor(-2**72 + 3, algorithm='pari') # indirect doctest -1 * 83 * 131 * 294971519 * 1472414939
Check that PARI’s debug level is properly reset (trac ticket #18792):
sage: alarm(0.5); factor(2^1000 - 1, verbose=5) Traceback (most recent call last): ... AlarmInterrupt sage: pari.get_debug_level() 0