Architecture and data migration methodology for L1 cache design with hybrid SRAM and volatile STT-RAM configuration

Abstract

Spin-Transfer Torque RAM (STT-RAM) has the advantages of circuit density and ignorable leakage power. However, it suffers from the bad write latency and poor write power consumption. Therefore, it is difficult to replace entire SRAM with STT-RAM in the L1 cache, but we can relax the retention time of STT-RAM cell to improve its write performance and replace some of the SRAM capacity to reduce leakage power. In this paper, we propose a locality-aware approach for L1 cache design with hybrid SRAM and volatile STT-RAM configuration. Based on the principle of cache locality, data block is mapped to SRAM firstly to reduce write latency and write energy, and is moved to volatile STT-RAM to reduce leakage power consumption. After a time period when there is no access of a data block in the volatile STT-RAM, we then stop its refresh operations to further reduce power consumption. Experimental results show that in comparison with the SRAM only L1 cache configuration, our hybrid cache configuration and data migration methodology reduce energy consumption by about 15–20%, with only nearly to 5% of latency overhead. Also when comparing to the STT-RAM only L1 cache configuration, we reduce memory access latency nearly to 20% with close or even better energy consumption.