Improving GPU Multitasking Efficiency Using Dynamic Resource Sharing

Abstract

As GPUs have become essential components for embedded computing systems, a shared GPU with multiple CPU cores needs to efficiently support concurrent execution of multiple different applications. Spatial multitasking, which assigns a different amount of streaming multiprocessors (SMs) to multiple applications, is one of the most common solutions for this. However, this is not a panacea for maximizing total resource utilization. It is because an SM consists of many different sub-resources such as caches, execution units and scheduling units, and the requirements of the sub-resources per kernel are not well matched to their fixed sizes inside an SM. To solve the resource requirement mismatch problem, this paper proposes a GPU Weaver, a dynamic sub-resource management system of multitasking GPUs. GPU Weaver can maximize sub-resource utilization through a shared resource controller (SRC) that is added between neighboring SMs. The SRC dynamically identifies idle sub-resources of an SM and allows them to be used by the neighboring SM when possible. Experiments show that the combination of multiple sub-resource borrowing techniques enhances the total throughput by up to 26 and 9.5 percent on average over the baseline spatial multitasking GPU.