FoToNoC: A hierarchical management strategy based on folded torus-like Network-on-Chip for dark silicon many-core systems

Abstract

In this dark silicon era, techniques have been developed to selectively activate nonadjacent cores in physical locations to maintain the safe temperature and allowable power budget on a many-core chip. This will result in unexpected increase in the communication overhead due to longer average distance between active cores in a typical mesh-based Network-on-Chip (NoC), and in turn reduce the system performance and energy efficiency. In this paper, we present FoToNoC, a Folded Torus-like NoC, and a hierarchical management strategy on top of it, to address this tradeoff problem for heterogeneous many-core systems. Optimizations of chip temperature, inter-core communication, application performance, and system energy consumption are well isolated in FoToNoC, and addressed in different design phases and aspects. A cluster-based hierarchical strategy is proposed to manage the system adaptively in several different control levels. Compared with mesh-based systems on a set of synthetic and real benchmarks, FoToNoC can achieve on average 39.4% performance improvement when similar temperature conditions are maintained, and the proposed strategy can further reduce the total energy consumption by up to 42.0%.