An Adjacent-Line-Merging Writeback Scheme for STT-RAM-Based Last-Level Caches

IEEE Transactions on Multi-Scale Computing Systems Pub Date : 2018-04-17 DOI:10.1109/TMSCS.2018.2827955

Masayuki Sato;Yoshiki Shoji;Zentaro Sakai;Ryusuke Egawa;Hiroaki Kobayashi

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引用次数: 1

Abstract

Spin-Transfer Torque RAM (STT-RAM) has attracted attention as a key element for the Last-Level Cache (LLC) of a future microprocessor. Since STT-RAM has a higher density than SRAM and non-volatility, STT-RAM can contribute to building the cache memory with a larger capacity and a less static energy. However, since STT-RAM changes its magnetization state in the case when storing data, the energy cost of write access requests for an STT-RAM LLC is more expensive than that of an SRAM LLC. As a result, the total energy consumption of the STT-RAM LLC for write-intensive applications may increase. To solve this problem, this paper proposes an Adjacent-Line-Merging Writeback Scheme. Since a larger cache line of an STT-RAM cache can contribute to the reduction in the write energy cost per byte, the upper-level cache merges two adjacent small lines to one large line, and then writes the merged line back to the STT-RAM LLC. Moreover, the larger line size for the LLC leads to a reduction in the static energy cost. The evaluation results show that the proposed scheme can reduce the energy consumption of the STT-RAM LLC by up to 26, and 9.3 percent on average.

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一种基于STT RAM的末级缓存的邻行合并写回方案

自旋转移力矩RAM（STT-RAM）作为未来微处理器的末级高速缓存（LLC）的关键元件，引起了人们的关注。由于STT-RAM具有比SRAM更高的密度和非易失性，STT-RAM可以有助于构建具有更大容量和更少静态能量的高速缓冲存储器。然而，由于STT-RAM在存储数据的情况下改变其磁化状态，所以STT-RAM LLC的写访问请求的能量成本比SRAM LLC的能量成本更昂贵。因此，用于写密集型应用的STT-RAM有限责任公司的总能量消耗可能增加。为了解决这个问题，本文提出了一种邻线合并写回方案。由于STT-RAM高速缓存的较大高速缓存行可以有助于降低每字节的写入能量成本，因此上级高速缓存将两条相邻的小行合并为一条大行，然后将合并后的行写回STT-RAM LLC。此外，LLC的较大行大小导致静态能量成本的降低。评估结果表明，该方案可将STT-RAM LLC的能耗降低26%，平均降低9.3%。

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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IEEE Transactions on Multi-Scale Computing Systems

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