分区实时NAND闪存

2018 IEEE Real-Time Systems Symposium (RTSS) Pub Date : 2018-12-01 DOI:10.1109/RTSS.2018.00036

Katherine Missimer, R. West

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引用次数: 9

摘要

本文研究了实时存储系统中NAND闪存的性能和可预测性的保证问题。我们的方法实现了一种新的闪存转换层方案，利用了固态存储设备内部的并行性。我们描述了分区实时闪存转换层(PaRT-FTL)，它将一组闪存芯片分割成独立的读写集。这确保了对不同芯片的读写并行进行。但是，PaRT-FTL还能够为来自闪存芯片的读请求重建数据，而闪存芯片正忙于处理写请求或执行垃圾收集。因此，读不会因为写或存储空间回收而阻塞。PaRT-FTL与之前的实时方法进行了比较，包括调度、过度供应和部分垃圾收集。我们表明，通过使用编码技术隔离读写请求，PaRT-FTL为实时应用程序提供了更好的延迟保证。

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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Partitioned Real-Time NAND Flash Storage

This paper addresses the problem of guaranteeing performance and predictability of NAND flash memory in a real-time storage system. Our approach implements a new flash translation layer scheme that exploits internal parallelism within solid state storage devices. We describe the Partitioned Real-Time Flash Translation Layer (PaRT-FTL), which splits a set of flash chips into separate read and write sets. This ensures reads and writes to separate chips proceed in parallel. However, PaRT-FTL is also able to rebuild the data for a read request from a flash chip that is busy servicing a write request or performing garbage collection. Consequently, reads are never blocked by writes or storage space reclamation. PaRT-FTL is compared to previous real-time approaches including scheduling, over-provisioning and partial garbage collection. We show that by isolating read and write requests using encoding techniques, PaRT-FTL provides better latency guarantees for real-time applications.

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2018 IEEE Real-Time Systems Symposium (RTSS)

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