Extremely-Compressed SSDs with I/O Behavior Prediction

IF 2.1 3区计算机科学 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

ACM Transactions on Storage Pub Date : 2024-07-16 DOI:10.1145/3677044

Xiangyu Yao, Qiao Li, Kaihuan Lin, Xinbiao Gan, Jie Zhang, Congming Gao, Zhirong Shen, Quanqing Xu, Chuanhui Yang, Jason Xue

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Abstract

As the data volume continues to grow exponentially, there is an increasing demand for large storage system capacity. Data compression techniques effectively reduce the volume of written data, enhancing space efficiency. As a result, many modern SSDs have already incorporated data compression capabilities. However, data compression introduces additional processing overhead in critical I/O paths, potentially affecting system performance. Currently, most compression solutions in flash-based storage systems employ fixed compression algorithms for all incoming data without leveraging differences among various data access patterns. This leads to sub-optimal compression efficiency. This paper proposes a data-type-aware Flash Translation Layer (DAFTL) scheme to maximize space efficiency without compromising system performance. First, we propose an I/O behavior prediction method to forecast future access on specific data. Then, DAFTL matches data types with distinct I/O behaviors to compression algorithms of varying intensities, achieving an optimal balance between performance and space efficiency. Specifically, it employs higher-intensity compression algorithms for less frequently accessed data to maximize space efficiency. For frequently accessed data, it utilizes lower-intensity but faster compression algorithms to maintain system performance. Finally, an improved compact compression method is proposed to effectively eliminate page fragmentation and further enhance space efficiency. Extensive evaluations using a variety of real-world workloads, as well as the workloads with real data we collected on our platforms, demonstrate that DAFTL achieves more data reductions than other approaches. When compared to the state-of-the-art compression schemes, DAFTL reduces the total number of pages written to the SSD by an average of 8%, 21.3%, and 25.6% for data with high, medium, and low compressibility, respectively. In the case of workloads with real data, DAFTL achieves an average reduction of 10.4% in the total number of pages written to SSD. Furthermore, DAFTL exhibits comparable or even improved read and write performance compared to other solutions.

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具有 I/O 行为预测功能的极压缩固态硬盘

随着数据量不断呈指数级增长，对大容量存储系统的需求也越来越大。数据压缩技术能有效减少写入数据量，提高空间效率。因此，许多现代固态硬盘已经集成了数据压缩功能。但是，数据压缩会在关键 I/O 路径中引入额外的处理开销，从而可能影响系统性能。目前，基于闪存的存储系统中的大多数压缩解决方案都对所有输入数据采用固定的压缩算法，而不利用各种数据访问模式之间的差异。这导致压缩效率达不到最优。本文提出了一种数据类型感知闪存转换层（DAFTL）方案，在不影响系统性能的前提下最大限度地提高空间效率。首先，我们提出了一种 I/O 行为预测方法，以预测未来对特定数据的访问。然后，DAFTL 将具有不同 I/O 行为的数据类型与不同强度的压缩算法相匹配，从而在性能和空间效率之间实现最佳平衡。具体来说，它对访问频率较低的数据采用强度较高的压缩算法，以最大限度地提高空间效率。对于频繁访问的数据，则采用强度较低但速度较快的压缩算法，以保持系统性能。最后，还提出了一种改进的压缩方法，以有效消除页面碎片，进一步提高空间效率。使用各种实际工作负载以及我们在平台上收集的真实数据进行的广泛评估表明，DAFTL 比其他方法减少了更多数据。与最先进的压缩方案相比，DAFTL 在高压缩率、中压缩率和低压缩率数据的情况下，写入固态硬盘的总页数平均分别减少了 8%、21.3% 和 25.6%。在使用真实数据的工作负载中，DAFTL平均减少了写入固态硬盘的总页数的10.4%。此外，与其他解决方案相比，DAFTL 的读写性能相当，甚至有所提高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

ACM Transactions on Storage COMPUTER SCIENCE, HARDWARE & ARCHITECTURE-COMPUTER SCIENCE, SOFTWARE ENGINEERING

CiteScore

4.20

自引率

5.90%

发文量

审稿时长

>12 weeks

期刊介绍： The ACM Transactions on Storage (TOS) is a new journal with an intent to publish original archival papers in the area of storage and closely related disciplines. Articles that appear in TOS will tend either to present new techniques and concepts or to report novel experiences and experiments with practical systems. Storage is a broad and multidisciplinary area that comprises of network protocols, resource management, data backup, replication, recovery, devices, security, and theory of data coding, densities, and low-power. Potential synergies among these fields are expected to open up new research directions.