RMSMP:一种新颖的行混合多精度深度神经网络量化框架

Sung-En Chang, Yanyu Li, Mengshu Sun, Weiwen Jiang, Sijia Liu, Yanzhi Wang, Xue Lin
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引用次数: 6

摘要

本文提出了一种新颖的深度神经网络(DNN)量化框架,即RMSMP,采用行混合方案和多精度方法。具体来说,这是第一次在层内分配混合量化方案和多重精度-在DNN权重矩阵的行之间,以简化硬件推理中的操作,同时保持精度。此外,与以往的研究不同,本文观察到量化误差并不一定表现出分层敏感性,实际上只要每层中有一定比例的权重精度较高,量化误差就可以得到缓解。这种观察使硬件实现的分层均匀性能够保证推理加速,同时仍然享受混合方案和多个精度的行方向灵活性以提高准确性。采用高硬件信息量的策略,切实有效地推导了备选方案和精度,减少了问题的搜索空间。RMSMP量化算法通过离线确定各层不同量化方案和精度的比例,利用基于Hessian和方差的方法对每一行进行有效的方案和精度分配。在图像分类和自然语言处理(BERT)应用中进行了测试,在相同的等效精度下,RMSMP达到了目前最先进的精度性能。RMSMP在FPGA器件上实现,与4位定点基线相比,在ImageNet上ResNet-18的端到端推理时间上实现了3.65倍的加速。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
RMSMP: A Novel Deep Neural Network Quantization Framework with Row-wise Mixed Schemes and Multiple Precisions
This work proposes a novel Deep Neural Network (DNN) quantization framework, namely RMSMP, with a Row-wise Mixed-Scheme and Multi-Precision approach. Specifically, this is the first effort to assign mixed quantization schemes and multiple precisions within layers – among rows of the DNN weight matrix, for simplified operations in hardware inference, while preserving accuracy. Furthermore, this paper makes a different observation from the prior work that the quantization error does not necessarily exhibit the layer-wise sensitivity, and actually can be mitigated as long as a certain portion of the weights in every layer are in higher precisions. This observation enables layer-wise uniformality in the hardware implementation towards guaranteed inference acceleration, while still enjoying row-wise flexibility of mixed schemes and multiple precisions to boost accuracy. The candidates of schemes and precisions are derived practically and effectively with a highly hardware-informative strategy to reduce the problem search space.With the offline determined ratio of different quantization schemes and precisions for all the layers, the RMSMP quantization algorithm uses Hessian and variance based method to effectively assign schemes and precisions for each row. The proposed RMSMP is tested for the image classification and natural language processing (BERT) applications, and achieves the best accuracy performance among state-of-the-arts under the same equivalent precisions. The RMSMP is implemented on FPGA devices, achieving 3.65× speedup in the end-to-end inference time for ResNet-18 on ImageNet, comparing with the 4-bit Fixed-point baseline.
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