Extent Mapping Scheme for Flash Memory Devices

2012 IEEE 20th International Symposium on Modeling, Analysis and Simulation of Computer and Telecommunication Systems Pub Date : 2012-08-07 DOI:10.1109/MASCOTS.2012.45

Young-Kyoon Suh, Bongki Moon, A. Efrat, Jin-Soo Kim, Sang-Won Lee

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引用次数: 5

Abstract

Flash memory devices commonly rely on traditional address mapping schemes such as page mapping, block mapping or a hybrid of the two. Page mapping is more flexible than block mapping or hybrid mapping without being restricted by block boundaries. However, its mapping table tends to grow large quickly as the capacity of flash memory devices does. To overcome this limitation, we propose a novel mapping scheme that is fundamentally different from the existing mapping strategies. We call this new scheme Virtual Extent Trie (VET), as it manages mapping information by treating each I/O request as an extent and by using extents as basic mapping units rather than pages or blocks. By storing extents instead of individual addresses, VET consumes much less memory to store mapping information and still remains as flexible as page mapping. We observed in our experiments that VET reduced memory consumption by up to an order of magnitude in comparison with the traditional mapping schemes for several real world workloads. The VET scheme also scaled well with increasing address spaces by synthetic workloads. With a binary search mechanism, VET limits the mapping time to O(log log|U |), where U denotes the set of all possible logical addresses. Though the asymptotic mapping cost of VET is higher than the O(1) time of a page mapping scheme, the amount of increased overhead was almost negligible or low enough to be hidden by an accompanying I/O operation.

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闪存设备的范围映射方案

闪存设备通常依赖于传统的地址映射方案，如页面映射、块映射或两者的混合。页映射比块映射或混合映射更灵活，不受块边界的限制。然而，它的映射表倾向于随着闪存设备容量的增长而迅速增长。为了克服这一限制，我们提出了一种与现有映射策略根本不同的新型映射方案。我们称这种新方案为虚拟范围三(Virtual Extent Trie, VET)，因为它通过将每个I/O请求视为一个范围，并使用范围作为基本映射单元(而不是页或块)来管理映射信息。通过存储区段而不是单个地址，VET消耗更少的内存来存储映射信息，并且仍然保持与页面映射一样的灵活性。我们在实验中观察到，对于几个真实世界的工作负载，与传统的映射方案相比，VET将内存消耗降低了一个数量级。随着合成工作负载的地址空间的增加，VET方案也可以很好地扩展。使用二进制搜索机制，VET将映射时间限制为O(log log|U |)，其中U表示所有可能的逻辑地址的集合。尽管VET的渐近映射成本高于页面映射方案的O(1)时间，但增加的开销几乎可以忽略不计，或者低到足以被伴随的I/O操作所隐藏。

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

2012 IEEE 20th International Symposium on Modeling, Analysis and Simulation of Computer and Telecommunication Systems

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