Stress-Aware Loops Mapping on CGRAs with Dynamic Multi-Map Reconfiguration

摘要

With VLSI process technology scaling into nano-scale, the increasingly serious aging issues (e.g., NBTI and HCI aging effects) have brought a significant threat to system reliability. Coarse-grained reconfigurable architectures (CGRAs) exhibit the feature to reconfigure and execute different mapping schemes (Maps) dynamically, compensating for each other to mitigate aging issues effectively. In this paper, a two-stage stress-aware loops mapping algorithm is first proposed for the CGRA-mapped designs by jointing the intra-kernel and inter-kernel stress optimizations. With pipelining techniques, the intra-kernel stress optimization employs the stress-aware force-directed and effective MCC (Maximal Compatibility Class) methods to optimize operations’ placement and mapping distribution on processing elements (PEs), which helps to avoid overmany operations to be mapped on the same PEs and reduce the accumulated stresses. By leveraging the dynamic reconfiguration feature, the inter-kernel stress optimization develops a multi-map scheduling method to reconfigure a set of ordered maps on CGRA dynamically, which diversifies the PEs’ usage and compensates for the stresses on different PEs among them. Experimental results show that our approach can reduce the maximum stress by 82.0% for NBTI and 70.4% for HCI, and improve the aging efficiency by 6.01X and MTTF by 3.16X averagely, while keeping the optimized performance.