{"title":"High Performance Householder QR Factorization on Emerging GPU Architectures Using Tensor Cores","authors":"Yuhan Leng;Gaoyuan Zou;Hansheng Wang;Panruo Wu;Shaoshuai Zhang","doi":"10.1109/TPDS.2024.3522776","DOIUrl":null,"url":null,"abstract":"Since 2017, NVIDIA GPUs have been equipped with specialized units known as Tensor Cores, which demonstrate remarkable efficiency in processing matrix multiplications (GEMMs). Beyond GEMMs, researchers have explored the potential applications of Tensor Cores in matrix factorization, such as QR factorization. However, the inside GEMMs in QR factorization are typically tall and skinny. Compared to compute-bound square GEMMs, these tall and skinny GEMMs are memory bound, leading to suboptimal performance on Tensor Cores. To solve this problem, we indicate the recursive QR factorization can convert the tall and skinny GEMMs to relatively square and large GEMMs, resulting in better performance on Tensor Cores. Besides, we extend the FP16 Tensor-Cores-based QR factorization to accommodate FP32 and FP64 on FP16 and INT8 Tensor Cores, respectively. Additionally, to address the issue of orthogonality loss in the preceding Tensor Cores-based QR factorization, we transition from the Gram-Schmidt to the Householder algorithm while preserving high performance. According to our experimental evaluation conducted on NVIDIA's A100 and GeForce RTX 3090 GPU, the precision levels of FP64, FP32, and FP16 are up to 6.22x, 8.67x, and 4.03x faster, respectively, than the current state-of-the-art implementations.","PeriodicalId":13257,"journal":{"name":"IEEE Transactions on Parallel and Distributed Systems","volume":"36 3","pages":"422-436"},"PeriodicalIF":5.6000,"publicationDate":"2024-12-25","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/10816084/","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
Since 2017, NVIDIA GPUs have been equipped with specialized units known as Tensor Cores, which demonstrate remarkable efficiency in processing matrix multiplications (GEMMs). Beyond GEMMs, researchers have explored the potential applications of Tensor Cores in matrix factorization, such as QR factorization. However, the inside GEMMs in QR factorization are typically tall and skinny. Compared to compute-bound square GEMMs, these tall and skinny GEMMs are memory bound, leading to suboptimal performance on Tensor Cores. To solve this problem, we indicate the recursive QR factorization can convert the tall and skinny GEMMs to relatively square and large GEMMs, resulting in better performance on Tensor Cores. Besides, we extend the FP16 Tensor-Cores-based QR factorization to accommodate FP32 and FP64 on FP16 and INT8 Tensor Cores, respectively. Additionally, to address the issue of orthogonality loss in the preceding Tensor Cores-based QR factorization, we transition from the Gram-Schmidt to the Householder algorithm while preserving high performance. According to our experimental evaluation conducted on NVIDIA's A100 and GeForce RTX 3090 GPU, the precision levels of FP64, FP32, and FP16 are up to 6.22x, 8.67x, and 4.03x faster, respectively, than the current state-of-the-art implementations.
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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.
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