Sketching and Streaming for Dictionary Compression
Abstract
We initiate the study of sub-linear sketching and streaming techniques for estimating the output size of common dictionary compressors such as Lempel-Ziv '77, the run-length Burrows-Wheeler transform, and grammar compression. To this end, we focus on a measure that has recently gained much attention in the information-theoretic community and which approximates up to a polylogarithmic multiplicative factor the output sizes of those compressors: the normalized substring complexity function . We present a data sketch of words that allows computing a multiplicative -approximation of with high probability, where is the string length. The sketches of two strings can be merged in time to yield the sketch of , speeding up by orders of magnitude tasks such as the computation of all-pairs \emph{Normalized Compression Distances} (NCD). If random access is available on the input, our sketch can be updated in time for each character right-extension of the string. This yields a polylogarithmic-space algorithm for approximating , improving exponentially over the working space of the state-of-the-art algorithms running in nearly-linear time. Motivated by the fact that random access is not always available on the input data, we then present a streaming algorithm computing our sketch in working space and worst-case delay per character. We show that an implementation of our streaming algorithm can estimate {\delta} on a dataset of 189GB with a throughput of 203MB per minute while using only 5MB of RAM, and that our sketch speeds up the computation of all-pairs NCD distances by one order of magnitude, with applications to phylogenetic tree reconstruction.
Cite
@article{arxiv.2310.17980,
title = {Sketching and Streaming for Dictionary Compression},
author = {Ruben Becker and Matteo Canton and Davide Cenzato and Sung-Hwan Kim and Bojana Kodric and Nicola Prezza},
journal= {arXiv preprint arXiv:2310.17980},
year = {2024}
}