Higher-dimensional sieving for the number field sieve algorithms

Abstract: Since 2016 and the introduction of the exTNFS (extended tower number field sieve) algorithm, the security of cryptosystems based on nonprime finite fields, mainly the pairing-and torus-based ones, is being reassessed. The feasibility of the relation collection, a crucial step of the NFS variants, is especially investigated. It usually involves polynomials of degree 1, i.e., a search space of dimension 2. However, exTNFS uses bivariate polynomials of at least four coefficients. If sieving in dimension 2 is well… Show more

“…These algorithms either find and extract smooth parts of the norms, or completely factor them. The family of sieving algorithms [13,26], batch algorithms [6, Algorithm 2.1] and ECM [7,25] are examples of such methods used in factorization and DLP computations. They all have different complexities and properties and thus cannot be used on the same amount of input norms N i .…”

“…Taking the polynomials a(ι) and b(ι) of degree deg h − 1 leads to d = 2 × deg h hence d ≥ 4. There exist two competitive algorithms that can be used when d ≥ 3: the transition vectors method [13] and the recursive hyperplan one [26], see Section 3.1 for these algorithms. They both use as a sieving space a d-orthotope whereas in this work we consider a d-sphere.…”

“…Transition vectors for lattice sieving in [13]. In 2018, Grémy suggested a sieving algorithm inspired by Franke-Kleinjung's algorithm in dimension 2 but extended to higher dimensions.…”

“…In dimension 4, this method seems to have sufficient prospects of success. However, even with the relaxed variant, experiments ran in dimension 6 in [13] point to the limits of this method due to the poor quality of the nearly-transitionvectors and the number of calls required to the dedicated fall-back strategy. [13] concluded that "using cuboid search is probably a too hard constraint that implies the hardness or even an impossibility for the sieving process".…”

“…In dimension 2, Franke and Kleinjung [10] proposed in 2005 an efficient algorithm used in all previous records. For higher dimensions, after a pioneer work in F p 12 by Hayasaka et al [19], the transition vectors method from Grémy [13] and a recursive plane method proposed by McGuire and Robinson [26] were tested in dimension 3 and used for record computations using NFS. However, the efficiency of their algorithms for even higher dimensions is questionable.…”

Lattice Enumeration for Tower NFS: A 521-Bit Discrete Logarithm Computation

“…These algorithms either find and extract smooth parts of the norms, or completely factor them. The family of sieving algorithms [13,26], batch algorithms [6, Algorithm 2.1] and ECM [7,25] are examples of such methods used in factorization and DLP computations. They all have different complexities and properties and thus cannot be used on the same amount of input norms N i .…”

“…Taking the polynomials a(ι) and b(ι) of degree deg h − 1 leads to d = 2 × deg h hence d ≥ 4. There exist two competitive algorithms that can be used when d ≥ 3: the transition vectors method [13] and the recursive hyperplan one [26], see Section 3.1 for these algorithms. They both use as a sieving space a d-orthotope whereas in this work we consider a d-sphere.…”

“…Transition vectors for lattice sieving in [13]. In 2018, Grémy suggested a sieving algorithm inspired by Franke-Kleinjung's algorithm in dimension 2 but extended to higher dimensions.…”

“…In dimension 4, this method seems to have sufficient prospects of success. However, even with the relaxed variant, experiments ran in dimension 6 in [13] point to the limits of this method due to the poor quality of the nearly-transitionvectors and the number of calls required to the dedicated fall-back strategy. [13] concluded that "using cuboid search is probably a too hard constraint that implies the hardness or even an impossibility for the sieving process".…”

“…In dimension 2, Franke and Kleinjung [10] proposed in 2005 an efficient algorithm used in all previous records. For higher dimensions, after a pioneer work in F p 12 by Hayasaka et al [19], the transition vectors method from Grémy [13] and a recursive plane method proposed by McGuire and Robinson [26] were tested in dimension 3 and used for record computations using NFS. However, the efficiency of their algorithms for even higher dimensions is questionable.…”

Lattice Enumeration for Tower NFS: A 521-Bit Discrete Logarithm Computation

Lattice Enumeration and Automorphisms for Tower NFS: A 521-Bit Discrete Logarithm Computation