MRAM-Based Cache System Design and Policy Optimization for RISC-V Multi-Core CPUs

摘要

On-chip cache, being the crucial constituent of central processing unit (CPU), accounts for a pivotal portion of the system#x2019;s overall power consumption. The typical static random access memory (SRAM)-based cache is vulnerable to high static leakage power consumption, while multiple challenges encountered in scaling up its capacity. In the article, magnetic random access memory (MRAM) cache is considered as a promising candidate in Reduced InstrucTIon Set Computer-Five (RISC-V) CPU systems. After analyzing the performances of single-, dual-, quad-, and octa-core systems, a quad-core RISC-V-based CPU system with a two-level hierarchical cache structure is designed, in which spin-orbit transfer (SOT)-MRAM is adopted as the L1 private cache and spin-transfer torque (STT)-MRAM as the L2 shared cache. Details on the microarchitecture of the multi-core CPU design are provided. Energy evaluation shows that this quad-core cache system can achieve 66.4#x0025; leakage power saving and 34.5#x0025; total power saving compared to SRAM. For high efficiency of data exchange in the novel MRAM CPU systems, three types of characteristics optimizing methods are proposed. An optimized cache-coherency protocol incorporating non-inclusive policy is proposed. The quad-core system is updated by adding the coherence control module and a directory in the design scheme. The simulation results on multiple dimensions show that the policy of the hybrid MRAM memory is a promising candidate for multi-core RISC-V system, with the benefits of low power consumption and high hit rate. Finally, the peripheral circuitry and manufacturing cost for the implementation of the MRAM cache is discussed in this article.