International Association
for Cryptologic Research

Cryptographic group actions have attracted growing attention as a useful tool for constructing cryptographic schemes. Among their applications, commitment schemes are particularly interesting as fundamental primitives, playing a crucial role in protocols such as zero-knowledge proofs, multi-party computation, and more. In this paper, we introduce a novel framework for constructing commitment schemes based on cryptographic group actions. Specifically, we propose two key techniques for general group actions: re-randomization and randomness extraction. Roughly speaking, a re-randomization algorithm introduces randomness within an orbit for any input element, while a randomness extractor maps this randomness to uniformity over the message space. We demonstrate that these techniques can significantly facilitate the construction of commitment schemes, providing a flexible framework for constructing either perfectly hiding or perfectly binding commitments, depending on the type of extractor involved. Moreover, we extend our framework to support the construction of commitments with additional desirable properties beyond hiding and binding, such as dual-mode commitments and enhanced linkable commitments. These extensions are achieved by further adapting the extractor to satisfy trapdoor or homomorphic properties. Finally, we instantiate all our proposed commitment schemes using lattices, specifically leveraging the lattice isomorphism problem (LIP) and the lattice automorphism problem (LAP) as underlying cryptographic assumptions. To the best of our knowledge, this is the first commitment scheme construction based on LIP/LAP. Additionally, we use LIP to provide a repair and improvement to the tensor isomorphism-based non-interactive commitment scheme proposed by D'Alconzo, Flamini, and Gangemi (ASIACRYPT 2023), which was recently shown to be insecure by an attack from Gilchrist, Marco, Petit, and Tang (CRYPTO 2024).

Coppersmith's method is a well-known and practical method for solving polynomial modular equations involved in some cryptosystems such as RSA. An important and tedious task in this method consists in computing the asymptotic bounds. In this work, we address the challenge of computing such asymptotic bounds by introducing the Sumsets theory from Additive Combinatorics as a new analytical tool, which significantly streamlines manual calculations. More precisely, we develop the first provable algorithm for determining these asymptotic bounds, whereas the recent methods based on simple Lagrange interpolation are heuristic. Moreover, the experiments showed that our method is much more efficient than the previous method in practice. We also employ our method to improve the cryptanalytic results for the Commutative Isogeny Hidden Number Problem. Our approach may deepen the understanding of Coppersmith's method and inspire more security analysis methodologies.

At Eurocrypt'24, Mureau et al. formally defined the Lattice Isomorphism Problem for module lattices (module-LIP) in a number field $\mathbb{K}$, and proposed a heuristic randomized algorithm solving module-LIP for modules of rank 2 in $\mathbb{K}^2$ with a totally real number field $\mathbb{K}$, which runs in classical polynomial time for a large class of modules and a large class of totally real number field under some reasonable number theoretic assumptions. In this paper, by introducing a (pseudo) symplectic automorphism of the module, we successfully reduce the problem of solving module-LIP over CM number field to the problem of finding certain symplectic automorphism. Furthermore, we show that a weak (pseudo) symplectic automorphism can be computed efficiently, which immediately turns out to be the desired automorphism when the module is in a totally real number field. This directly results in a provable deterministic polynomial-time algorithm solving module-LIP for rank-2 modules in $\mathbb{K}^2$ where $\mathbb{K}$ is a totally real number field, without any assumptions or restrictions on the modules and the totally real number fields. Moreover, the weak symplectic automorphism can also be utilized to invalidate the omSVP assumption employed in HAWK's forgery security analysis, although it does not yield any actual attacks against HAWK itself.

$\mathbb{Z}^n$ is one of the simplest types of lattices, but the computational problems on its rotations, such as $\mathbb{Z}$SVP and $\mathbb{Z}$LIP, have been of great interest in cryptography. Recent advances have been made in building cryptographic primitives based on these problems, as well as in developing new algorithms for solving them. However, the theoretical complexity of $\mathbb{Z}$SVP and $\mathbb{Z}$LIP are still not well understood. In this work, we study the problems on rotations of $\mathbb{Z}^n$ by exploiting the symmetry property. We introduce a randomization framework that can be roughly viewed as `applying random automorphisms’ to the output of an oracle, without accessing the automorphism group. Using this framework, we obtain new reduction results for rotations of $\mathbb{Z}^n$. First, we present a reduction from $\mathbb{Z}$LIP to $\mathbb{Z}$SCVP. Here $\mathbb{Z}$SCVP is the problem of finding the shortest characteristic vectors, which is a special case of CVP where the target vector is a deep hole of the lattice. Moreover, we prove a reduction from $\mathbb{Z}$SVP to $\gamma$-$\mathbb{Z}$SVP for any constant $\gamma = O(1)$ in the same dimension, which implies that $\mathbb{Z}$SVP is as hard as its approximate version for any constant approximation factor. Second, we investigate the problem of finding a nontrivial automorphism for a given lattice, which is called LAP. Specifically, we use the randomization framework to show that $\mathbb{Z}$LAP is as hard as $\mathbb{Z}$LIP. We note that our result can be viewed as a $\mathbb{Z}^n$-analogue of Lenstra and Silverberg's result in [JoC2017], but with a different assumption: they assume the $G$-lattice structure, while we assume the access to an oracle that outputs a nontrivial automorphism.