Abstract:
To understand performance and energy tradeoffs in CPU–memory systems at lower geometries and new technologies, there is a need to update the processor and cache models us...Show MoreMetadata
Abstract:
To understand performance and energy tradeoffs in CPU–memory systems at lower geometries and new technologies, there is a need to update the processor and cache models used by instruction-level simulators. We improve the existing McPAT tool to support the 14-nm FinFET commercial technology, while respecting McPAT’s overall modeling methodology. We also include the results from the BOOM CPU core, synthesized with FinFET technology, into the McPAT tool to model the core components. For the first time, we extend McPAT to support the negative capacitance fin field-effect transistor (NC-FinFET), an emerging transistor technology with subthreshold swing (SS) below 60 mV/decade and unique leakage characteristics. Experiments using our FN-McPAT tool indicate that the NC-FinFET-based system is more energy-efficient relative to the FinFET-based system for memory-intensive workloads and vice versa for the compute-intensive workloads while operating at the highest voltage and frequency. In addition, we analyze the performance and energy consumption of last-level caches (LLCs) operating at various voltages and report novel insights into the energy consumption behavior for the NC-FinFET-based LLC. FN-McPAT is available for download at https://github.com/marg-tools/FN-McPAT.
Published in: IEEE Transactions on Very Large Scale Integration (VLSI) Systems ( Volume: 31, Issue: 9, September 2023)