Prolonging Lifetime of PCM-Based Main Memories through On-Demand Page Pairing

ACM Trans. Design Autom. Electr. Syst. Pub Date : 2015-03-02 DOI:10.1145/2699867

Marjan Asadinia, M. Arjomand, H. Sarbazi-Azad

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引用次数: 11

Abstract

With current memory scalability challenges, Phase-Change Memory (PCM) is viewed as an attractive replacement to DRAM. The preliminary concern for PCM applicability is its limited write endurance that results in fast wear-out of memory cells. Worse, process variation in the deep-nanometer regime increases the variation in cell lifetime, resulting in an early and sudden reduction in main memory capacity due to the wear-out of a few cells. Recent studies have proposed redirection or correction schemes to alleviate this problem, but all suffer poor throughput or latency. In this article, we show that one of the inefficiency sources in current schemes, even when wear-leveling algorithms are used, is the nonuniform write endurance limit incurred by process variation, that is, when some memory pages have reached their endurance limit, other pages may be far from their limit. In this line, we present a technique that aims to displace a faulty page to a healthy page. This technique, called On-Demand Page Paired PCM (OD3P, for short), when applied at page level, can improve PCM time-to-failure by 20% on average for different multithreaded and multiprogrammed workloads while also improving IPC by 14% on average compared to previous page-level techniques. The comparison between line-level OD3P and previous line-level techniques reveals about 2× improvement of lifetime and performance.

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通过按需页面配对延长pcm主存储器的寿命

面对当前存储器可扩展性的挑战，相变存储器(PCM)被视为DRAM的一个有吸引力的替代品。对PCM适用性的初步关注是其有限的写入持久性，这会导致内存单元的快速损耗。更糟糕的是，在深度纳米范围内的工艺变化增加了电池寿命的变化，由于一些电池的磨损，导致主存储器容量的早期和突然减少。最近的研究提出了重定向或纠正方案来缓解这个问题，但所有这些方案的吞吐量或延迟都很差。在本文中，我们展示了当前方案中低效率的来源之一，即使使用了损耗均衡算法，也是进程变化引起的不均匀写入持久性限制，也就是说，当一些内存页面达到其持久性限制时，其他页面可能远未达到其极限。在这一行中，我们将介绍一种旨在将有故障的页面替换为健康页面的技术。这种技术称为按需页面配对PCM(简称OD3P)，当应用于页面级时，对于不同的多线程和多程序工作负载，可以将PCM到故障的平均时间提高20%，同时与以前的页面级技术相比，还可以将IPC平均提高14%。将线级OD3P与以前的线级技术进行比较，可以发现寿命和性能提高了2倍。

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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ACM Trans. Design Autom. Electr. Syst.

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