Your search keyword '"Cheng, Xingzhou"' showing total 4 results

1. NAND-SPIN-Based Processing-in-MRAM Architecture for Convolutional Neural Network Acceleration

Author

Zhao, Yinglin, Yang, Jianlei, Li, Bing, Cheng, Xingzhou, Ye, Xucheng, Wang, Xueyan, Jia, Xiaotao, Wang, Zhaohao, Zhang, Youguang, and Zhao, Weisheng

Subjects

Computer Science - Hardware Architecture, Computer Science - Emerging Technologies

Abstract

The performance and efficiency of running large-scale datasets on traditional computing systems exhibit critical bottlenecks due to the existing "power wall" and "memory wall" problems. To resolve those problems, processing-in-memory (PIM) architectures are developed to bring computation logic in or near memory to alleviate the bandwidth limitations during data transmission. NAND-like spintronics memory (NAND-SPIN) is one kind of promising magnetoresistive random-access memory (MRAM) with low write energy and high integration density, and it can be employed to perform efficient in-memory computation operations. In this work, we propose a NAND-SPIN-based PIM architecture for efficient convolutional neural network (CNN) acceleration. A straightforward data mapping scheme is exploited to improve the parallelism while reducing data movements. Benefiting from the excellent characteristics of NAND-SPIN and in-memory processing architecture, experimental results show that the proposed approach can achieve $\sim$2.6$\times$ speedup and $\sim$1.4$\times$ improvement in energy efficiency over state-of-the-art PIM solutions., Comment: 15 pages, accepted by SCIENCE CHINA Information Sciences (SCIS) 2022

Published

2022

2. S2Engine: A Novel Systolic Architecture for Sparse Convolutional Neural Networks

Author

Yang, Jianlei, Fu, Wenzhi, Cheng, Xingzhou, Ye, Xucheng, Dai, Pengcheng, and Zhao, Weisheng

Subjects

Computer Science - Hardware Architecture, Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Machine Learning

Abstract

Convolutional neural networks (CNNs) have achieved great success in performing cognitive tasks. However, execution of CNNs requires a large amount of computing resources and generates heavy memory traffic, which imposes a severe challenge on computing system design. Through optimizing parallel executions and data reuse in convolution, systolic architecture demonstrates great advantages in accelerating CNN computations. However, regular internal data transmission path in traditional systolic architecture prevents the systolic architecture from completely leveraging the benefits introduced by neural network sparsity. Deployment of fine-grained sparsity on the existing systolic architectures is greatly hindered by the incurred computational overheads. In this work, we propose S2Engine $-$ a novel systolic architecture that can fully exploit the sparsity in CNNs with maximized data reuse. S2Engine transmits compressed data internally and allows each processing element to dynamically select an aligned data from the compressed dataflow in convolution. Compared to the naive systolic array, S2Engine achieves about $3.2\times$ and about $3.0\times$ improvements on speed and energy efficiency, respectively., Comment: 13 pages, 17 figures

Published

2021

3. SparseTrain: Exploiting Dataflow Sparsity for Efficient Convolutional Neural Networks Training

Author

Dai, Pengcheng, Yang, Jianlei, Ye, Xucheng, Cheng, Xingzhou, Luo, Junyu, Song, Linghao, Chen, Yiran, and Zhao, Weisheng

Subjects

Computer Science - Computer Vision and Pattern Recognition, Computer Science - Hardware Architecture

Abstract

Training Convolutional Neural Networks (CNNs) usually requires a large number of computational resources. In this paper, \textit{SparseTrain} is proposed to accelerate CNN training by fully exploiting the sparsity. It mainly involves three levels of innovations: activation gradients pruning algorithm, sparse training dataflow, and accelerator architecture. By applying a stochastic pruning algorithm on each layer, the sparsity of back-propagation gradients can be increased dramatically without degrading training accuracy and convergence rate. Moreover, to utilize both \textit{natural sparsity} (resulted from ReLU or Pooling layers) and \textit{artificial sparsity} (brought by pruning algorithm), a sparse-aware architecture is proposed for training acceleration. This architecture supports forward and back-propagation of CNN by adopting 1-Dimensional convolution dataflow. We have built %a simple compiler to map CNNs topology onto \textit{SparseTrain}, and a cycle-accurate architecture simulator to evaluate the performance and efficiency based on the synthesized design with $14nm$ FinFET technologies. Evaluation results on AlexNet/ResNet show that \textit{SparseTrain} could achieve about $2.7 \times$ speedup and $2.2 \times$ energy efficiency improvement on average compared with the original training process., Comment: published on DAC 2020

Published

2020

4. TCIM: Triangle Counting Acceleration With Processing-In-MRAM Architecture

Author

Wang, Xueyan, Yang, Jianlei, Zhao, Yinglin, Qi, Yingjie, Liu, Meichen, Cheng, Xingzhou, Jia, Xiaotao, Chen, Xiaoming, Qu, Gang, and Zhao, Weisheng

Subjects

Computer Science - Hardware Architecture

Abstract

Triangle counting (TC) is a fundamental problem in graph analysis and has found numerous applications, which motivates many TC acceleration solutions in the traditional computing platforms like GPU and FPGA. However, these approaches suffer from the bandwidth bottleneck because TC calculation involves a large amount of data transfers. In this paper, we propose to overcome this challenge by designing a TC accelerator utilizing the emerging processing-in-MRAM (PIM) architecture. The true innovation behind our approach is a novel method to perform TC with bitwise logic operations (such as \texttt{AND}), instead of the traditional approaches such as matrix computations. This enables the efficient in-memory implementations of TC computation, which we demonstrate in this paper with computational Spin-Transfer Torque Magnetic RAM (STT-MRAM) arrays. Furthermore, we develop customized graph slicing and mapping techniques to speed up the computation and reduce the energy consumption. We use a device-to-architecture co-simulation framework to validate our proposed TC accelerator. The results show that our data mapping strategy could reduce $99.99\%$ of the computation and $72\%$ of the memory \texttt{WRITE} operations. Compared with the existing GPU or FPGA accelerators, our in-memory accelerator achieves speedups of $9\times$ and $23.4\times$, respectively, and a $20.6\times$ energy efficiency improvement over the FPGA accelerator., Comment: published on DAC 2020

Published

2020