New Two-Level L1 Data Cache Bypassing Technique for High Performance GPUs

J. Inf. Process. Syst. Pub Date : 2021-02-09 DOI:10.3745/JIPS.01.0062

Gwang Bok Kim, C. Kim

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Abstract

On-chip caches of graphics processing units (GPUs) have contributed to improved GPU performance by reducing long memory access latency. However, cache efficiency remains low despite the facts that recent GPUs have considerably mitigated the bottleneck problem of L1 data cache. Although the cache miss rate is a reasonable metric for cache efficiency, it is not necessarily proportional to GPU performance. In this study, we introduce a second key determinant to overcome the problem of predicting the performance gains from L1 data cache based on the assumption that miss rate only is not accurate. The proposed technique estimates the benefits of the cache by measuring the balance between cache efficiency and throughput. The throughput of the cache is predicted based on the warp occupancy information in the warp pool. Then, the warp occupancy is used for a second bypass phase when workloads show an ambiguous miss rate. In our proposed architecture, the L1 data cache is turned off for a long period when the warp occupancy is not high. Our two-level bypassing technique can be applied to recent GPU models and improves the performance by 6% on average compared to the architecture without bypassing. Moreover, it outperforms the conventional bottleneck-based bypassing techniques.

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一种新的高性能gpu双级L1数据缓存绕过技术

图形处理单元(GPU)的片上缓存通过减少长内存访问延迟来提高GPU性能。然而，尽管最近的gpu已经大大缓解了L1数据缓存的瓶颈问题，但缓存效率仍然很低。虽然缓存缺失率是缓存效率的合理指标，但它不一定与GPU性能成正比。在本研究中，我们引入了第二个关键决定因素，以克服基于仅缺失率不准确的假设来预测L1数据缓存的性能增益的问题。提出的技术通过测量缓存效率和吞吐量之间的平衡来估计缓存的好处。缓存的吞吐量是基于warp池中的warp占用信息来预测的。然后，当工作负载显示不明确的遗漏率时，曲速占用用于第二个旁路阶段。在我们提出的体系结构中，当warp占用率不高时，L1数据缓存将关闭很长一段时间。我们的两级旁路技术可以应用于最新的GPU模型，与没有旁路的架构相比，性能平均提高了6%。此外，它优于传统的基于瓶颈的旁路技术。

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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J. Inf. Process. Syst.

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