更少的内存意味着更小的 GPU:使用压缩激活的反向传播

Daniel Barley, Holger Fröning
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摘要

深度神经网络(DNN)的规模不断扩大,导致对计算资源的需求也同样快速增长。最近的许多架构,尤其是大型语言模型,都必须使用配备数千个加速器(如 GPU 或 TPU)的超级计算机进行训练。除了大量浮点运算外,DNN 的内存占用也呈爆炸式增长。与此形成鲜明对比的是,GPU 体系结构的内存不足是众所周知的。即使是像某些 EfficientNet 变体这样相对较小的架构,也无法在单个消费级 GPU 上以合理的小批量规模进行训练。在训练过程中,必须存储中间输入激活,直到反向传播梯度计算为止。因此,在这项工作中,我们考虑使用池化技术压缩后向通路的激活图,这样可以减少内存占用和数据移动量。前向计算仍未压缩。我们以常见的视觉架构 ResNet 为例,通过经验展示了收敛性,并研究了对特征检测的影响。通过这种方法,我们能够将峰值内存消耗减少 29%,但代价是需要更长的训练时间,同时与未压缩的基线相比,预测准确率得以保持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Less Memory Means smaller GPUs: Backpropagation with Compressed Activations
The ever-growing scale of deep neural networks (DNNs) has lead to an equally rapid growth in computational resource requirements. Many recent architectures, most prominently Large Language Models, have to be trained using supercomputers with thousands of accelerators, such as GPUs or TPUs. Next to the vast number of floating point operations the memory footprint of DNNs is also exploding. In contrast, GPU architectures are notoriously short on memory. Even comparatively small architectures like some EfficientNet variants cannot be trained on a single consumer-grade GPU at reasonable mini-batch sizes. During training, intermediate input activations have to be stored until backpropagation for gradient calculation. These make up the vast majority of the memory footprint. In this work we therefore consider compressing activation maps for the backward pass using pooling, which can reduce both the memory footprint and amount of data movement. The forward computation remains uncompressed. We empirically show convergence and study effects on feature detection at the example of the common vision architecture ResNet. With this approach we are able to reduce the peak memory consumption by 29% at the cost of a longer training schedule, while maintaining prediction accuracy compared to an uncompressed baseline.
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