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2. Factorization of polynomials over finite fields - Wikipedia

   en.wikipedia.org/wiki/Factorization_of...

   Polynomial factoring algorithms use basic polynomial operations such as products, divisions, gcd, powers of one polynomial modulo another, etc. A multiplication of two polynomials of degree at most n can be done in O(n 2) operations in F q using "classical" arithmetic, or in O(nlog(n) log(log(n)) ) operations in F q using "fast" arithmetic.

3. General number field sieve - Wikipedia

   en.wikipedia.org/wiki/General_number_field_sieve

   An optimal strategy for choosing these polynomials is not known; one simple method is to pick a degree d for a polynomial, consider the expansion of n in base m (allowing digits between −m and m) for a number of different m of order n 1/d, and pick f(x) as the polynomial with the smallest coefficients and g(x) as x − m.

4. Cantor–Zassenhaus algorithm - Wikipedia

   en.wikipedia.org/wiki/Cantor–Zassenhaus_algorithm

   The Cantor–Zassenhaus algorithm takes as input a square-free polynomial (i.e. one with no repeated factors) of degree n with coefficients in a finite field whose irreducible polynomial factors are all of equal degree (algorithms exist for efficiently factoring arbitrary polynomials into a product of polynomials satisfying these conditions, for instance, () / ((), ′ ()) is a squarefree ...

5. Berlekamp's algorithm - Wikipedia

   en.wikipedia.org/wiki/Berlekamp's_algorithm

   In mathematics, particularly computational algebra, Berlekamp's algorithm is a well-known method for factoring polynomials over finite fields (also known as Galois fields). The algorithm consists mainly of matrix reduction and polynomial GCD computations. It was invented by Elwyn Berlekamp in 1967.

6. Factorization of polynomials - Wikipedia

   en.wikipedia.org/wiki/Factorization_of_polynomials

   Each of these polynomials can be tested for being a factor by polynomial division. Since there were finitely many and each () has finitely many divisors, there are finitely many such tuples. So, an exhaustive search allows finding all factors of degree at most d. For example, consider

7. Polynomial long division - Wikipedia

   en.wikipedia.org/wiki/Polynomial_long_division

   The result R = 0 occurs if and only if the polynomial A has B as a factor. Thus long division is a means for testing whether one polynomial has another as a factor, and, if it does, for factoring it out. For example, if a root r of A is known, it can be factored out by dividing A by (x – r).

8. Special number field sieve - Wikipedia

   en.wikipedia.org/wiki/Special_number_field_sieve

   The SNFS works as follows. Let n be the integer we want to factor. As in the rational sieve, the SNFS can be broken into two steps: First, find a large number of multiplicative relations among a factor base of elements of Z/nZ, such that the number of multiplicative relations is larger than the number of elements in the factor base.

9. Lenstra elliptic-curve factorization - Wikipedia

   en.wikipedia.org/wiki/Lenstra_elliptic-curve...

   The second-fastest is the multiple polynomial quadratic sieve, and the fastest is the general number field sieve. The Lenstra elliptic-curve factorization is named after Hendrik Lenstra. Practically speaking, ECM is considered a special-purpose factoring algorithm, as it is most suitable for finding small factors.