Contention-Aware Scheduling for Asymmetric Multicore Processors

Asymmetric multicore processors (AMPs) have been proposed as an energy-efficient alternative to symmetric mul-ticore processors (SMPs). However, AMPs derive their performance from core specialization, which requires co-running applications to be scheduled to run on their most appropriate core types. Despite extensive research on AMP scheduling, developing an effective scheduling algorithm remains challenging. Contention for shared resources is a key performance-limiting factor, which often renders existing contention-free scheduling algorithms ineffective. We introduce a contention-aware scheduling algorithm for ARM´s big.LITTLE, a commercial AMP platform. Our algorithm comprises an offline stage and an online stage. The offline stage builds a performance interference model for an application by training it with a set of co-running applications. Guided by this model, the online stage schedules a workload by assigning its applications to their most appropriate core types in order to minimize the performance degradation caused by contention for shared resources. Our model can accurately predict the performance degradation of an application when co-running with other applications with an average prediction error of 9.60%. Compared with the default scheduler provided for ARM´s big.LITTLE and the speedup-factor-driven scheduler, our contention-aware scheduler can improve overall system performance by up to 28.32% and 28.51%, respectively.