{"title":"Exploiting Temporal-Unrolled Parallelism for Energy-Efficient SNN Acceleration","authors":"Fangxin Liu;Zongwu Wang;Wenbo Zhao;Ning Yang;Yongbiao Chen;Shiyuan Huang;Haomin Li;Tao Yang;Songwen Pei;Xiaoyao Liang;Li Jiang","doi":"10.1109/TPDS.2024.3415712","DOIUrl":null,"url":null,"abstract":"Event-driven spiking neural networks (SNNs) have demonstrated significant potential for achieving high energy and area efficiency. However, existing SNN accelerators suffer from issues such as high latency and energy consumption due to serial accumulation-comparison operations. This is mainly because SNN neurons integrate spikes, accumulate membrane potential, and generate output spikes when the potential exceeds a threshold. To address this, one approach is to leverage the sparsity of SNN spikes to reduce the number of time steps. However, this method can result in imbalanced workloads among neurons and limit the utilization of processing elements (PEs). In this paper, we present SATO, a temporal-parallel SNN accelerator that enables parallel accumulation of membrane potential for all time steps. SATO adopts a two-stage pipeline methodology, effectively decoupling neuron computations. This not only maintains accuracy but also unveils opportunities for fine-grained parallelism. By dividing the neuron computation into distinct stages, SATO enables the concurrent execution of spike accumulation for each time step, leveraging the parallel processing capabilities of modern hardware architectures. This not only enhances the overall efficiency of the accelerator but also reduces latency by exploiting parallelism at a granular level. The architecture of SATO includes a novel binary adder-search tree for generating the output spike train, effectively decoupling the chronological dependence in the accumulation-comparison operation. Furthermore, SATO employs a bucket-sort-based method to evenly distribute compressed workloads to all PEs, maximizing data locality of input spike trains. Experimental results on various SNN models demonstrate that SATO outperforms the well-known accelerator, the 8-bit version of “Eyeriss” by \n<inline-formula><tex-math>$20.7\\times$</tex-math></inline-formula>\n in terms of speedup and \n<inline-formula><tex-math>$6.0\\times$</tex-math></inline-formula>\n energy-saving, on average. Compared to the state-of-the-art SNN accelerator “SpinalFlow”, SATO can also achieve \n<inline-formula><tex-math>$4.6\\times$</tex-math></inline-formula>\n performance gain and \n<inline-formula><tex-math>$3.1\\times$</tex-math></inline-formula>\n energy reduction on average, which is quite impressive for inference.","PeriodicalId":13257,"journal":{"name":"IEEE Transactions on Parallel and Distributed Systems","volume":"35 10","pages":"1749-1764"},"PeriodicalIF":5.6000,"publicationDate":"2024-06-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"IEEE Transactions on Parallel and Distributed Systems","FirstCategoryId":"94","ListUrlMain":"https://ieeexplore.ieee.org/document/10561563/","RegionNum":2,"RegionCategory":"计算机科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"COMPUTER SCIENCE, THEORY & METHODS","Score":null,"Total":0}
引用次数: 0
Abstract
Event-driven spiking neural networks (SNNs) have demonstrated significant potential for achieving high energy and area efficiency. However, existing SNN accelerators suffer from issues such as high latency and energy consumption due to serial accumulation-comparison operations. This is mainly because SNN neurons integrate spikes, accumulate membrane potential, and generate output spikes when the potential exceeds a threshold. To address this, one approach is to leverage the sparsity of SNN spikes to reduce the number of time steps. However, this method can result in imbalanced workloads among neurons and limit the utilization of processing elements (PEs). In this paper, we present SATO, a temporal-parallel SNN accelerator that enables parallel accumulation of membrane potential for all time steps. SATO adopts a two-stage pipeline methodology, effectively decoupling neuron computations. This not only maintains accuracy but also unveils opportunities for fine-grained parallelism. By dividing the neuron computation into distinct stages, SATO enables the concurrent execution of spike accumulation for each time step, leveraging the parallel processing capabilities of modern hardware architectures. This not only enhances the overall efficiency of the accelerator but also reduces latency by exploiting parallelism at a granular level. The architecture of SATO includes a novel binary adder-search tree for generating the output spike train, effectively decoupling the chronological dependence in the accumulation-comparison operation. Furthermore, SATO employs a bucket-sort-based method to evenly distribute compressed workloads to all PEs, maximizing data locality of input spike trains. Experimental results on various SNN models demonstrate that SATO outperforms the well-known accelerator, the 8-bit version of “Eyeriss” by
$20.7\times$
in terms of speedup and
$6.0\times$
energy-saving, on average. Compared to the state-of-the-art SNN accelerator “SpinalFlow”, SATO can also achieve
$4.6\times$
performance gain and
$3.1\times$
energy reduction on average, which is quite impressive for inference.
期刊介绍:
IEEE Transactions on Parallel and Distributed Systems (TPDS) is published monthly. It publishes a range of papers, comments on previously published papers, and survey articles that deal with the parallel and distributed systems research areas of current importance to our readers. Particular areas of interest include, but are not limited to:
a) Parallel and distributed algorithms, focusing on topics such as: models of computation; numerical, combinatorial, and data-intensive parallel algorithms, scalability of algorithms and data structures for parallel and distributed systems, communication and synchronization protocols, network algorithms, scheduling, and load balancing.
b) Applications of parallel and distributed computing, including computational and data-enabled science and engineering, big data applications, parallel crowd sourcing, large-scale social network analysis, management of big data, cloud and grid computing, scientific and biomedical applications, mobile computing, and cyber-physical systems.
c) Parallel and distributed architectures, including architectures for instruction-level and thread-level parallelism; design, analysis, implementation, fault resilience and performance measurements of multiple-processor systems; multicore processors, heterogeneous many-core systems; petascale and exascale systems designs; novel big data architectures; special purpose architectures, including graphics processors, signal processors, network processors, media accelerators, and other special purpose processors and accelerators; impact of technology on architecture; network and interconnect architectures; parallel I/O and storage systems; architecture of the memory hierarchy; power-efficient and green computing architectures; dependable architectures; and performance modeling and evaluation.
d) Parallel and distributed software, including parallel and multicore programming languages and compilers, runtime systems, operating systems, Internet computing and web services, resource management including green computing, middleware for grids, clouds, and data centers, libraries, performance modeling and evaluation, parallel programming paradigms, and programming environments and tools.