English

Regular and almost universal hashing: an efficient implementation

Data Structures and Algorithms 2018-10-16 v2 Cryptography and Security

Abstract

Random hashing can provide guarantees regarding the performance of data structures such as hash tables---even in an adversarial setting. Many existing families of hash functions are universal: given two data objects, the probability that they have the same hash value is low given that we pick hash functions at random. However, universality fails to ensure that all hash functions are well behaved. We further require regularity: when picking data objects at random they should have a low probability of having the same hash value, for any fixed hash function. We present the efficient implementation of a family of non-cryptographic hash functions (PM+) offering good running times, good memory usage as well as distinguishing theoretical guarantees: almost universality and component-wise regularity. On a variety of platforms, our implementations are comparable to the state of the art in performance. On recent Intel processors, PM+ achieves a speed of 4.7 bytes per cycle for 32-bit outputs and 3.3 bytes per cycle for 64-bit outputs. We review vectorization through SIMD instructions (e.g., AVX2) and optimizations for superscalar execution.

Keywords

Cite

@article{arxiv.1609.09840,
  title  = {Regular and almost universal hashing: an efficient implementation},
  author = {Dmytro Ivanchykhin and Sergey Ignatchenko and Daniel Lemire},
  journal= {arXiv preprint arXiv:1609.09840},
  year   = {2018}
}

Comments

accepted for publication in Software: Practice and Experience in September 2016

R2 v1 2026-06-22T16:06:59.771Z