Highly scaled CMOS devices in the nanoscale regime would inevitably exhibit statistical or probabilistic behavior. Such behavior is due to process variations and other perturbations such as noise. Therefore current circuit design methodologies, which depend on the existence of deterministic and uniform devices with no consideration for either power consumption or probabilistic behavior, would no longer be sufficient to design robust circuits. To help overcome this challenge, we have been characterizing CMOS devices with probabilistic behavior (probabilistic CMOS or PCMOS devices) at several levels: from foundational principles to analytical modeling, simulation, fabrication and measurement, as well as innovative approaches to harnessing PCMOS devices in system-on-a-chip architectures which can implement a wide range of applications. In this paper, we present a broad overview of our contributions in the domain of PCMOS, and outline ongoing work and future challenges in this area.
Intertask/interprocess synchronization overheads may be significant in a multiprocessor-shared memory System-on-a-Chip implementation. These overheads are observed in terms of lock latency, lock delay and memory bandwidth consumption in the system. It has been shown that a hardware solution brings a much better performance improvement than the synchronization algorithms developed in software [3]. Our previous work presented a SoC Lock Cache (SoCLC) hardware mechanism which resolves the Critical Section (CS) interactions among multiple processors and improves the performance criteria in terms of lock latency, lock delay and bandwidth consumption in a shared memory multiprocessor SoC for short CSes [1]. This paper extends our previous work to support long CSes as well. This combined support involves modifications both in the RTOS kernel level facilities (such as support for preemptive versus non-preemptive synchronization, interrupt handling and RTOS initialization) and in the hardware mechanism. The worst-case simulation results of a database application model with client-server pair of tasks on a fourprocessor system showed that our mechanism achieved a 57% improvement in lock latency, 14% speed up in lock delay and a 35% overall speedup in total execution time.
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