English

Efficient Chromosome Parallelization for Precision Medicine Genomic Workflows

Distributed, Parallel, and Cluster Computing 2025-11-21 v1 Artificial Intelligence Machine Learning Performance Genomics

Abstract

Large-scale genomic workflows used in precision medicine can process datasets spanning tens to hundreds of gigabytes per sample, leading to high memory spikes, intensive disk I/O, and task failures due to out-of-memory errors. Simple static resource allocation methods struggle to handle the variability in per-chromosome RAM demands, resulting in poor resource utilization and long runtimes. In this work, we propose multiple mechanisms for adaptive, RAM-efficient parallelization of chromosome-level bioinformatics workflows. First, we develop a symbolic regression model that estimates per-chromosome memory consumption for a given task and introduces an interpolating bias to conservatively minimize over-allocation. Second, we present a dynamic scheduler that adaptively predicts RAM usage with a polynomial regression model, treating task packing as a Knapsack problem to optimally batch jobs based on predicted memory requirements. Additionally, we present a static scheduler that optimizes chromosome processing order to minimize peak memory while preserving throughput. Our proposed methods, evaluated on simulations and real-world genomic pipelines, provide new mechanisms to reduce memory overruns and balance load across threads. We thereby achieve faster end-to-end execution, showcasing the potential to optimize large-scale genomic workflows.

Keywords

Cite

@article{arxiv.2511.15977,
  title  = {Efficient Chromosome Parallelization for Precision Medicine Genomic Workflows},
  author = {Daniel Mas Montserrat and Ray Verma and Míriam Barrabés and Francisco M. de la Vega and Carlos D. Bustamante and Alexander G. Ioannidis},
  journal= {arXiv preprint arXiv:2511.15977},
  year   = {2025}
}

Comments

Accepted at AAAI 2026

R2 v1 2026-07-01T07:46:27.989Z