Shared Memory-contention-aware Concurrent DNN Execution for Diversely Heterogeneous System-on-Chips
Ismet Dagli, Mehmet E. Belviranlı
Abstract
Two distinguishing features of state-of-the-art mobile and autonomous systems are: 1) There are often multiple workloads, mainly deep neural network (DNN) inference, running concurrently and continuously. 2) They operate on shared memory System-on-Chips (SoC) that embed heterogeneous accelerators tailored for specific operations. State-of-the-art systems lack efficient performance and resource management techniques necessary to either maximize total system throughput or minimize end-to-end workload latency. In this work, we propose HaX-CoNN, a novel scheme that characterizes and maps layers in concurrently executing DNN inference workloads to a diverse set of accelerators within an SoC. Our scheme uniquely takes per-layer execution characteristics, shared memory (SM) contention, and inter-accelerator transitions into account to find optimal schedules. We evaluate HaX-CoNN on NVIDIA Orin, NVIDIA Xavier, and Qualcomm Snapdragon 865 SoCs. Our experimental results indicate that HaX-CoNN can minimize memory contention by up to 45% and improve total latency and throughput by up to 32% and 29%, respectively, compared to the state-of-the-art.