Dixon's factorization method

In number theory, Dixon's factorization method (also Dixon's random squares method^[1] or Dixon's algorithm) is a general-purpose integer factorization algorithm; it is the prototypical factor base method. Unlike for other factor base methods, its run-time bound comes with a rigorous proof that does not rely on conjectures about the smoothness properties of the values taken by polynomial.

The algorithm was designed by John D. Dixon, a mathematician at Carleton University, and was published in 1981.^[2]

Basic idea

Dixon's method is based on finding a congruence of squares modulo the integer N which we intend to factor. Fermat's factorization algorithm finds such a congruence by selecting random or pseudo-random x values and hoping that the integer x² mod N is a perfect square (in the integers):

x^{2}\equiv y^{2}\quad ({\hbox{mod }}N),\qquad x\not \equiv \pm y\quad ({\hbox{mod }}N).

For example, if N = 84923, we notice (by starting at 292, the first number greater than √N and counting up) that 505² mod 84923 is 256, the square of 16. So (505 − 16)(505 + 16) = 0 mod 84923. Computing the greatest common divisor of 505 − 16 and N using Euclid's algorithm gives us 163, which is a factor of N.

In practice, selecting random x values will take an impractically long time to find a congruence of squares, since there are only √N squares less than N.

Dixon's method replaces the condition "is the square of an integer" with the much weaker one "has only small prime factors"; for example, there are 292 squares smaller than 84923; 662 numbers smaller than 84923 whose prime factors are only 2,3,5 or 7; and 4767 whose prime factors are all less than 30. (Such numbers are called B-smooth with respect to some bound B.)

If we have lots of numbers $a_{1}\ldots a_{n}$ whose squares can be factorized as $a_{i}^{2}\mod N=\prod _{{j=1}}^{m}b_{j}^{{e_{{ij}}}}$ for a fixed set $b_{1}\ldots b_{m}$ of small primes, linear algebra modulo 2 on the matrix $e_{ij}$ will give us a subset of the $a_{i}$ whose squares combine to a product of small primes to an even power — that is, a subset of the $a_{i}$ whose squares multiply to the square of a (hopefully different) number mod N.

Method

Suppose we are trying to factor the composite number N. We choose a bound B, and identify the factor base (which we will call P), the set of all primes less than or equal to B. Next, we search for positive integers z such that z² mod N is B-smooth. We can therefore write, for suitable exponents a_k,

z^{2}\equiv \prod _{{p_{i}\in P}}p_{i}^{{a_{i}}}{\pmod {N}}

When we have generated enough of these relations (it's generally sufficient that the number of relations be a few more than the size of P), we can use the methods of linear algebra (for example, Gaussian elimination) to multiply together these various relations in such a way that the exponents of the primes on the right-hand side are all even:

{z_{1}^{2}z_{2}^{2}\cdots z_{k}^{2}\equiv \prod _{{p_{i}\in P}}p_{i}^{{a_{{i,1}}+a_{{i,2}}+\cdots +a_{{i,k}}}}\ {\pmod {N}}\quad ({\text{where }}a_{{i,1}}+a_{{i,2}}+\cdots +a_{{i,k}}\equiv 0{\pmod {2}})}

This gives us a congruence of squares of the form a² ≡ b² (mod N), which can be turned into a factorization of N, N = gcd(a + b, N) × (N/gcd(a + b, N)). This factorization might turn out to be trivial (i.e. N = N × 1), which can only happen if a ≡ ±b (mod N), in which case we have to try again with a different combination of relations; but with luck we will get a nontrivial pair of factors of N, and the algorithm will terminate.

Example

We will try to factor N = 84923 using bound B = 7. Our factor base is then P = {2, 3, 5, 7}. We then search randomly for integers between $\left\lceil {\sqrt {84923}}\right\rceil =292$ and N whose squares are B-smooth. Suppose that two of the numbers we find are 513 and 537:

513^{2}\mod 84923=8400=2^{4}\cdot 3\cdot 5^{2}\cdot 7

537^{2}\mod 84923=33600=2^{6}\cdot 3\cdot 5^{2}\cdot 7

(513\cdot 537)^{2}\mod 84923=2^{{10}}\cdot 3^{2}\cdot 5^{4}\cdot 7^{2}

Then

{\begin{aligned}&{}\qquad (513\cdot 537)^{2}\mod 84923=(275481)^{2}\mod 84923\\&=(84923\cdot 3+20712)^{2}\mod 84923\\&=(84923\cdot 3)^{2}+2\cdot (84923\cdot 3\cdot 20712)+20712^{2}\mod 84923\\&=0+0+20712^{2}\mod 84923\end{aligned}}

That is, $20712^{2}\mod 84923=(2^{5}\cdot 3\cdot 5^{2}\cdot 7)^{2}\mod 84923=16800^{2}\mod 84923.$

The resulting factorization is 84923 = gcd(20712 − 16800, 84923) × gcd(20712 + 16800, 84923) = 163 × 521.

Optimizations

The quadratic sieve is an optimization of Dixon's method. It selects values of x close to the square root of N such that x² modulo N is small, thereby largely increasing the chance of obtaining a smooth number.

Other ways to optimize Dixon's method include using a better algorithm to solve the matrix equation, taking advantage of the sparsity of the matrix: a number z cannot have more than $\log _{2}z$ factors, so each row of the matrix is almost all zeros. In practice, the block Lanczos algorithm is often used. Also, the size of the factor base must be chosen carefully: if it is too small, it will be difficult to find numbers that factorize completely over it, and if it is too large, more relations will have to be collected.

A more sophisticated analysis, using the approximation that a number has all its prime factors less than $N^{{1/a}}$ with probability about $a^{{-a}}$ (an approximation to the Dickman–de Bruijn function), indicates that choosing too small a factor base is much worse than too large, and that the ideal factor base size is some power of $\exp \left({\sqrt {\log N\log \log N}}\right)$ .

The optimal complexity of Dixon's method is

O\left(\exp \left(2{\sqrt 2}{\sqrt {\log n\log \log n}}\right)\right)

in big-O notation, or

L_{n}[1/2,2{\sqrt 2}]

in L-notation.

References

↑ Kleinjung, Thorsten; et al. (2010). "Factorization of a 768-bit RSA modulus". Advances in Cryptology – CRYPTO 2010. Lecture Notes in Computer Science. 6223. pp. 333–350. doi:10.1007/978-3-642-14623-7_18.
↑ Dixon, J. D. (1981). "Asymptotically fast factorization of integers". Math. Comp. 36 (153): 255–260. doi:10.1090/S0025-5718-1981-0595059-1. JSTOR 2007743.

Number-theoretic algorithms

Primality tests	AKS test APR test Baillie–PSW Elliptic curve Pocklington Fermat Lucas Lucas–Lehmer Lucas–Lehmer–Riesel Proth's theorem Pépin's Quadratic Frobenius test Solovay–Strassen Miller–Rabin

Prime-generating	Sieve of Atkin Sieve of Eratosthenes Sieve of Sundaram Wheel factorization

Integer factorization	Continued fraction (CFRAC) Dixon's Lenstra elliptic curve (ECM) Euler's Pollard's rho p − 1 p + 1 Quadratic sieve (QS) General number field sieve (GNFS) Special number field sieve (SNFS) Rational sieve Fermat's Shanks' square forms Trial division Shor's

Multiplication	Ancient Egyptian Long Karatsuba Toom–Cook Schönhage–Strassen Fürer's

Discrete logarithm	Baby-step giant-step Pollard rho Pollard kangaroo Pohlig–Hellman Index calculus Function field sieve

Greatest common divisor	Binary Euclidean Extended Euclidean Lehmer's

Modular square root	Cipolla Pocklington's Tonelli–Shanks

Other algorithms	Chakravala Cornacchia LLL Integer square root Modular exponentiation Schoof's

Italics indicate that algorithm is for numbers of special forms

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