Memory hierarchy reconfiguration for energy and performance in general-purpose processor architectures

Conventional microarchitectures choose a single memory hierarchy design point targeted at the average application. In this paper, we propose a cache and TLB layout and design that leverages repeater insertion to provide dynamic low-cost configurability trading off size and speed on a per application phase basis. A novel configuration management algorithm dynamically detects phase changes and reacts to an application´s hit and miss intolerance in order to improve memory hierarchy performance while taking energy consumption into consideration. When applied to a two-level cache and TLB hierarchy at 0.1 μm technology, the result is an average 15% reduction in cycles per instruction (CPI), corresponding to an average 27% reduction in memory-CPI, across a broad class of applications compared to the best conventional two-level hierarchy of comparable size. Projecting to sub-.1 μm technology design considerations that call for a three-level conventional cache hierarchy for performance reasons, we demonstrate that a configurable L2/L3 cache hierarchy coupled with a conventional LI results in an average 43% reduction in memory hierarchy energy in addition to improved performance