Energy Behaviour of NUCA Caches in CMPs

Advances in technology of semiconductor make nowadays possible to design Chip Multiprocessor Systems equipped with huge on-chip Last Level Caches. Due to the wire delay problem, the use of traditional cache memories with a uniform access time would result in unacceptable response latencies. NUCA (Non Uniform Cache Access) architecture has been proposed as a viable solution to hide the adverse impact of wires delay on performance. Many previous studies have focused on the effectiveness of NUCA architectures, but the study of the energy and power aspects of NUCA caches is still limited. In this work, we present an energy model specifically suited for NUCA-based CMP systems, together with a methodology to employ the model to evaluate the NUCA energy consumption. Moreover, we present a performance and energy dissipation analysis for two 8-core CMP systems with an S-NUCA and a D-NUCA, respectively. Experimental results show that, similarly to the monolithic processor, the static power also dominates the total power budget in the CMP system.