A Study on Performance and Power Efficiency of Dense Non-Volatile Caches in Multi-Core Systems

Amin Jadidi; Mohammad Arjomand; Mahmut Kandemir; Chita Das

doi:10.1145/3078505.3078547

A Study on Performance and Power Efficiency of Dense Non-Volatile Caches in Multi-Core Systems

Amin Jadidi
, Mohammad Arjomand
, Mahmut Kandemir
, Chita Das

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

This paper presents a novel cache design based on Multi-Level Cell Spin-Transfer Torque RAM (MLC STT-RAM).Our design exploits the asymmetric nature of the MLC STT-RAM to build cache lines featuring heterogeneous performances, that is, half of the cache lines are read-friendly,while the other half are write-friendly-this asymmetry in read/write latencies are then used by a migration policy in order to overcome the high latency of the baseline MLC cache. Furthermore, in order to enhance the device lifetime, we propose to dynamically deactivate ways of a set in underutilized sets to convert MLC to Single-Level Cell (SLC)mode.Our experiments show that our design gives an average improvement of 12% in system performance and 26% in last-level cache(L3) access energy for various workloads.

Original language	English (US)
Pages (from-to)	27-28
Number of pages	2
Journal	Performance Evaluation Review
Volume	45
Issue number	1
DOIs	https://doi.org/10.1145/3078505.3078547
State	Published - Jun 5 2017

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 10 Reduced Inequalities

All Science Journal Classification (ASJC) codes

Software
Hardware and Architecture
Computer Networks and Communications

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10.1145/3078505.3078547

Cite this

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abstract = "This paper presents a novel cache design based on Multi-Level Cell Spin-Transfer Torque RAM (MLC STT-RAM).Our design exploits the asymmetric nature of the MLC STT-RAM to build cache lines featuring heterogeneous performances, that is, half of the cache lines are read-friendly,while the other half are write-friendly-this asymmetry in read/write latencies are then used by a migration policy in order to overcome the high latency of the baseline MLC cache. Furthermore, in order to enhance the device lifetime, we propose to dynamically deactivate ways of a set in underutilized sets to convert MLC to Single-Level Cell (SLC)mode.Our experiments show that our design gives an average improvement of 12\% in system performance and 26\% in last-level cache(L3) access energy for various workloads.",

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AU - Kandemir, Mahmut

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A Study on Performance and Power Efficiency of Dense Non-Volatile Caches in Multi-Core Systems

Abstract

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