Informed Prefetching for Distributed Multi-Level Storage Systems

In this paper, we present an informed prefetching technique called IPODS that makes use of application-disclosed access patterns to prefetch hinted blocks in distributed multi-level storage systems. We develop a prefetching pipeline in IPODS, where an informed prefetching process is divided into a s...

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Bibliographic Details
Published in:Journal of signal processing systems 2018-04, Vol.90 (4), p.619-640
Main Authors: Al Assaf, Maen M., Jiang, Xunfei, Qin, Xiao, Abid, Mohamed Riduan, Qiu, Meikang, Zhang, Jifu
Format: Article
Language:English
Subjects:
Access time
Buffers
Circuits and Systems
Clients
Computer Imaging
Computer networks
Digital audio players
Disks
Electrical Engineering
Engineering
Image Processing and Computer Vision
Levels
Network latency
Network storage
Pattern Recognition
Pattern Recognition and Graphics
Pipelines
Signal,Image and Speech Processing
Storage systems
Vision
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Summary:In this paper, we present an informed prefetching technique called IPODS that makes use of application-disclosed access patterns to prefetch hinted blocks in distributed multi-level storage systems. We develop a prefetching pipeline in IPODS, where an informed prefetching process is divided into a set of independent prefetching steps and separated among multiple storage levels in a distributed system. In the IPODS system, while data blocks are prefetched from hard disks to memory buffers in remote storage servers, data blocks buffered in the servers are prefetched through networks to the clients’ local cache. We show that these two prefetching steps can be handled in a pipelining manner to improve I/O performance of distributed storage systems. Our IPODS technique differs from existing prefetching schemes in two ways. First, it reduces applications’ I/O stalls by keeping hinted data in clients’ local caches and storage servers’ fast buffers (e.g., solid state disks). Second, in a prefetching pipeline, multiple informed prefetching mechanisms coordinate semi-dependently to fetch blocks (1) from low-level (slow) to high-level (fast) storage devices in servers and (2) from high-level devices in servers to the clients’ local cache. The prefetching pipeline in IPODS judiciously hides network latency in distributed storage systems, thereby reducing the overall I/O access time in distributed systems. Using a wide range of real-world I/O traces, our experiments show that IPODS can noticeably improve I/O performance of distributed storage systems by 6%.
ISSN:1939-8018
1939-8115
DOI:10.1007/s11265-017-1277-z