PMFFRC: a large-scale genomic short reads compression optimizer via memory modeling and redundant clustering

Sun, Hui; Zheng, Yingfeng; Xie, Haonan; Ma, Huidong; Liu, Xiaoguang; Wang, Gang

doi:10.1186/s12859-023-05566-9

BMC Bioinformatics

2023

DOI: 10.1186/s12859-023-05566-9

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PMFFRC: a large-scale genomic short reads compression optimizer via memory modeling and redundant clustering

Hui Sun,

Yingfeng Zheng,

Haonan Xie

et al.

Abstract: Background Genomic sequencing reads compressors are essential for balancing high-throughput sequencing short reads generation speed, large-scale genomic data sharing, and infrastructure storage expenditure. However, most existing short reads compressors rarely utilize big-memory systems and duplicative information between diverse sequencing files to achieve a higher compression ratio for conserving reads data storage space. Results We employ compre… Show more

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2024

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PQSDC: a parallel lossless compressor for quality scores data via sequences partition and run-length prediction mapping

Sun,

Zheng,

Xie

et al. 2024

Bioinformatics

Self Cite

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Motivation The quality scores data (QSD) account for 70% in compressed FastQ files obtained from the short and long reads sequencing technologies. Designing effective compressors for QSD that counterbalance compression ratio, time cost, and memory consumption is essential in scenarios such as large-scale genomics data sharing and long-term data backup. This study presents a novel parallel lossless QSD-dedicated compression algorithm named PQSDC, which fulfills the above requirements well. PQSDC is based on two core components: a parallel sequences-partition model designed to reduce peak memory consumption and time cost during compression and decompression processes, as well as a parallel four-level run-length prediction mapping model to enhance compression ratio. Besides, the PQSDC algorithm is also designed to be highly concurrent using multi-core CPU clusters. Results We evaluate PQSDC and 4 state-of-the-art compression algorithms on 27 real-world datasets, including 61.857 billion QSD characters and 632.908 million QSD sequences. (1) For short reads, compared to baselines, the maximum improvement of PQSDC reaches 7.06% in average compression ratio, and 8.01% in weighted average compression ratio. During compression and decompression, the maximum total time savings of PQSDC are 79.96% and 84.56%, respectively; the maximum average memory savings are 68.34% and 77.63%, respectively. (2) For long reads, the maximum improvement of PQSDC reaches 12.51% and 13.42% in average and weighted average compression ratio, respectively. The maximum total time savings during compression and decompression are 53.51% and 72.53%, respectively; the maximum average memory savings are 19.44% and 17.42%, respectively. (3) Furthermore, PQSDC ranks second in compression robustness among the tested algorithms, indicating that it is less affected by the probability distribution of the QSD collections. Overall, our work provides a promising solution for QSD parallel compression, which balances storage cost, time consumption, and memory occupation primely. Availability The proposed PQSDC compressor can be downloaded from https://github.com/fahaihi/PQSDC. Supplementary information Supplementary data are available at Bioinformatics online.

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PQSDC: a parallel lossless compressor for quality scores data via sequences partition and run-length prediction mapping

Sun,

Zheng,

Xie

et al. 2024

Bioinformatics

Self Cite

View full text Add to dashboard Cite

show abstract

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PMFFRC: a large-scale genomic short reads compression optimizer via memory modeling and redundant clustering

Cited by 1 publication

References 27 publications

PQSDC: a parallel lossless compressor for quality scores data via sequences partition and run-length prediction mapping

PQSDC: a parallel lossless compressor for quality scores data via sequences partition and run-length prediction mapping

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