SPIMulator: A Spintronic Processing-In-Memory Simulator for Racetracks

IF 2.8 3区 计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
Pavia Bera, Stephen Cahoon, Sanjukta Bhanja, Alex Jones
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引用次数: 0

Abstract

In-memory processing is becoming a popular method to alleviate the memory bottleneck of the von Neumann computing model. With the goal of improving both latency and energy cost associated with such in-memory processing, emerging non-volatile memory technologies, such as Spintronic magnetic memory, are of particular interest as they can provide a near-SRAM read/write performance and eliminate nearly all static energy without experiencing any endurance limitations. Spintronic Racetrack Memory (RM) further addresses density concerns of spin-transfer torque memory (STT-MRAM). Moreover, it has recently been demonstrated that portions of RM nanowires can function as a polymorphic gate, which can be leveraged to implement multi-operand bulk bitwise operations. With more complex control, they can also be leveraged to build arithmetic integer and floating point processing in memory (PIM) primitives. This paper proposes SPIMulator, a Spintronic PIM simulator that can simulate the storage and PIM architecture of executing PIM commands in Racetrack memory. SPIMulator functionally models the polymorphic gate properties recently proposed for Racetrack memory, which allows transverse access that determines the number of ‘1’s in a segment of each Racetrack nanowire. From this simulation, SPIMulator can report real-time performance statistics such as cycle count and energy. Thus, SPIMulator simulates the multi-operand bit-wise logic operations recently proposed and can be easily extended to implement new PIM operations as they are developed. Due to the functional nature of SPIMulator, it can serve as a programming environment that allows development of PIM-based codes for verification of new acceleration algorithms. We demonstrate the value of SPIMulator through the modeling and estimations of performance and energy consumption of a variety of example applications, including the Advanced Encryption Standard (AES) for encryption primarily based on logical and look-up operations; multiplication of matrices, a frequent requirement in scientific, signal processing, and machine learning algorithms; and bitmap indices a common search table employed for database lookups.

SPIMulator:用于赛道的自旋电子处理内存模拟器
内存处理正成为缓解冯-诺依曼计算模型内存瓶颈的流行方法。为了改善与这种内存处理相关的延迟和能耗成本,新兴的非易失性内存技术(如自旋电子磁性内存)尤其引人关注,因为它们可以提供接近 SRAM 的读/写性能,并消除几乎所有的静态能耗,而不会受到任何续航时间的限制。自旋电子磁道存储器(RM)进一步解决了自旋转移力矩存储器(STT-MRAM)的密度问题。此外,最近的研究表明,RM 纳米线的一部分可以作为多态门,利用它可以实现多操作数的批量位操作。通过更复杂的控制,还可以利用它们构建算术整数和浮点存储器处理(PIM)基元。本文提出的 SPIMulator 是一款 Spintronic PIM 仿真器,可以模拟在 Racetrack 内存中执行 PIM 命令的存储和 PIM 架构。SPIMulator 在功能上模拟了最近为 Racetrack 存储器提出的多态门特性,它允许横向访问,从而决定每个 Racetrack 纳米线段中 "1 "的数量。通过这种模拟,SPIMulator 可以报告实时性能统计数据,如周期计数和能量。这样,SPIMulator 就能模拟最近提出的多操作数比特慧逻辑运算,并能在开发出新的 PIM 运算时轻松加以扩展。由于 SPIMulator 的功能特性,它可以作为一种编程环境,允许开发基于 PIM 的代码,以验证新的加速算法。我们通过对各种示例应用的性能和能耗进行建模和估算,证明了 SPIMulator 的价值,这些应用包括主要基于逻辑和查找操作的高级加密标准(AES)加密;矩阵乘法(科学、信号处理和机器学习算法中的常见要求);以及位图索引(数据库查找中常用的搜索表)。
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
ACM Transactions on Embedded Computing Systems
ACM Transactions on Embedded Computing Systems 工程技术-计算机:软件工程
CiteScore
3.70
自引率
0.00%
发文量
138
审稿时长
6 months
期刊介绍: The design of embedded computing systems, both the software and hardware, increasingly relies on sophisticated algorithms, analytical models, and methodologies. ACM Transactions on Embedded Computing Systems (TECS) aims to present the leading work relating to the analysis, design, behavior, and experience with embedded computing systems.
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