FPGA-based Minimal Latency HEFT Scheduler for Heterogeneous Computing

2021 6th International Conference on Computer Science and Engineering (UBMK) Pub Date : 2021-09-15 DOI:10.1109/UBMK52708.2021.9558926

I. Aliyev, J. Mack, Nirmal Kumbhare, A. Akoglu, H. F. Ugurdag

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引用次数: 3

Abstract

This paper proposes a new hardware scheduler. As heterogeneous computing becomes prevalent, mapping applications on to multiple processing elements (PEs) proves to be non-trivial. Heterogeneous Earliest Finish Time (HEFT) algorithm is an already existing scheduler that aims to minimize the total execution time of an application. The paradigm of HEFT is such that it accepts an acyclic task graph as input at run-time and assigns/schedules the precompiled atomic tasks to PEs. HEFT stands out among many such schedulers not only in terms of producing shorter schedules but also in terms of its own short execution time. However, in real-time applications, the lower the latency, the better it is. To the best of our knowledge, this work is the only work that implements HEFT in hardware (on FPGA) further lowering its latency from milliseconds to as much as less than a microsecond. Porting HEFT to hardware has been challenging as data dependencies limit the amount of parallelism. Design of an efficient memory access pattern as well as an “incremental sorter” were key enablers in reducing the latency of the hardware implementation. We also integrated our FPGA-HEFT into an ARM-based SoC and validated its functionality using a realistic workload.

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基于fpga的异构计算最小延迟HEFT调度程序

本文提出了一种新的硬件调度程序。随着异构计算的流行，将应用程序映射到多个处理元素(pe)被证明是非常重要的。异构最早完成时间(HEFT)算法是一种现有的调度器，旨在最小化应用程序的总执行时间。HEFT的范例是这样的:它在运行时接受非循环任务图作为输入，并将预编译的原子任务分配/调度给pe。HEFT在许多这样的调度器中脱颖而出，不仅因为它产生更短的调度，而且因为它自己的执行时间也很短。然而，在实时应用程序中，延迟越低越好。据我们所知，这项工作是唯一在硬件(FPGA)上实现HEFT的工作，进一步将其延迟从几毫秒降低到不到一微秒。将HEFT移植到硬件是一个挑战，因为数据依赖性限制了并行性的数量。高效内存访问模式的设计以及“增量排序器”是减少硬件实现延迟的关键因素。我们还将FPGA-HEFT集成到基于arm的SoC中，并使用实际工作负载验证其功能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 6th International Conference on Computer Science and Engineering (UBMK)

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