Using Smart Routing for Secure and Dependable NoC-Based MPSoCs

Abstract

The Internet-of-Things (IoT) boosted the building of computational systems that share computation, communication and storage resources for uncountable types of applications. MultiProcessor System-on-Chip (MPSoC) is a fundamental component of such systems offering large parallelism degree in an ocean of processors and memories connected through one or more Network-on-Chips (NoCs). Therefore, a massive quantity of sensitive information of several applications can share computation and communication resources of the MPSoCs demanding security mechanisms and policies. Besides, the advances of CMOS technologies increases the quantity of static and dynamic faults, requiring a dependable and resilient target architecture, which can be partially fulfilled by an effective and efficient NoC design. This work addresses fault tolerance and security at NoC level with SDR, a routing algorithm that includes the concept of security zones in the MPSoC while providing support for dependable routing avoiding faulty links. The proposed routing algorithm prioritizes communication paths deemed secure in 2D mesh NoCs with deadlock freedom. Experimental results employing realistic workload scenarios based on the NASA Numeric Aerodynamic Simulation (NAS) Parallel Benchmark (NPB) and a fault model for 65nm and 22nm CMOS fabrication technologies demonstrates the scalability, security, and dependability of SDR.