Exploiting Sparsity in Pruned Neural Networks to Optimize Large Model Training

Siddharth Singh, A. Bhatele
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引用次数: 3

Abstract

Parallel training of neural networks at scale is challenging due to significant overheads arising from communication. Recently, deep learning researchers have developed a variety of pruning algorithms that are capable of pruning (i.e. setting to zero) 80-90% of the parameters in a neural network to yield sparse subnetworks that equal the accuracy of the unpruned parent network. In this work, we propose a novel approach that exploits these sparse subnetworks to optimize the memory utilization and communication in two popular algorithms for parallel deep learning namely – data and inter-layer parallelism. We integrate our approach into AxoNN, a highly scalable framework for parallel deep learning that relies on data and inter-layer parallelism, and demonstrate the reduction in communication time and memory utilization. On 512 NVIDIA V100 GPUs, our optimizations reduce the memory consumption of a 2.7 billion parameter model by 74%, and the total communication time by 40%, thus providing an overall speedup of 34% over AxoNN, 32% over DeepSpeed-3D and 46% over Sputnik, a sparse matrix computation baseline.
利用精简神经网络的稀疏性优化大型模型训练
大规模的神经网络并行训练是具有挑战性的,因为通信带来了巨大的开销。最近,深度学习研究人员开发了各种修剪算法,这些算法能够修剪(即设置为零)神经网络中80-90%的参数,从而产生与未修剪的父网络相同精度的稀疏子网络。在这项工作中,我们提出了一种新的方法,利用这些稀疏子网来优化并行深度学习的两种流行算法中的内存利用和通信,即数据并行和层间并行。我们将我们的方法集成到AxoNN中,AxoNN是一个高度可扩展的并行深度学习框架,依赖于数据和层间并行,并证明了通信时间和内存利用率的减少。在512个NVIDIA V100 gpu上,我们的优化将27亿个参数模型的内存消耗减少了74%,总通信时间减少了40%,从而提供了比AxoNN 34%的总体加速,比DeepSpeed-3D 32%,比Sputnik 46%,一个稀疏矩阵计算基线。
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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