TY - JOUR
T1 - GPU-acceleration of the ELPA2 distributed eigensolver for dense symmetric and hermitian eigenproblems
AU - Yu, Victor Wen zhe
AU - Moussa, Jonathan
AU - Kůs, Pavel
AU - Marek, Andreas
AU - Messmer, Peter
AU - Yoon, Mina
AU - Lederer, Hermann
AU - Blum, Volker
N1 - Publisher Copyright:
© 2020 Elsevier B.V.
PY - 2021/5
Y1 - 2021/5
N2 - The solution of eigenproblems is often a key computational bottleneck that limits the tractable system size of numerical algorithms, among them electronic structure theory in chemistry and in condensed matter physics. Large eigenproblems can easily exceed the capacity of a single compute node, thus must be solved on distributed-memory parallel computers. We here present GPU-oriented optimizations of the ELPA two-stage tridiagonalization eigensolver (ELPA2). On top of cuBLAS-based GPU offloading, we add a CUDA kernel to speed up the back-transformation of eigenvectors, which can be the computationally most expensive part of the two-stage tridiagonalization algorithm. We benchmark the performance of this GPU-accelerated eigensolver on two hybrid CPU–GPU architectures, namely a compute cluster based on Intel Xeon Gold CPUs and NVIDIA Volta GPUs, and the Summit supercomputer based on IBM POWER9 CPUs and NVIDIA Volta GPUs. Consistent with previous benchmarks on CPU-only architectures, the GPU-accelerated two-stage solver exhibits a parallel performance superior to the one-stage counterpart. Finally, we demonstrate the performance of the GPU-accelerated eigensolver developed in this work for routine semi-local KS-DFT calculations comprising thousands of atoms.
AB - The solution of eigenproblems is often a key computational bottleneck that limits the tractable system size of numerical algorithms, among them electronic structure theory in chemistry and in condensed matter physics. Large eigenproblems can easily exceed the capacity of a single compute node, thus must be solved on distributed-memory parallel computers. We here present GPU-oriented optimizations of the ELPA two-stage tridiagonalization eigensolver (ELPA2). On top of cuBLAS-based GPU offloading, we add a CUDA kernel to speed up the back-transformation of eigenvectors, which can be the computationally most expensive part of the two-stage tridiagonalization algorithm. We benchmark the performance of this GPU-accelerated eigensolver on two hybrid CPU–GPU architectures, namely a compute cluster based on Intel Xeon Gold CPUs and NVIDIA Volta GPUs, and the Summit supercomputer based on IBM POWER9 CPUs and NVIDIA Volta GPUs. Consistent with previous benchmarks on CPU-only architectures, the GPU-accelerated two-stage solver exhibits a parallel performance superior to the one-stage counterpart. Finally, we demonstrate the performance of the GPU-accelerated eigensolver developed in this work for routine semi-local KS-DFT calculations comprising thousands of atoms.
KW - CUDA
KW - Dense linear algebra
KW - Eigensolver
KW - GPU
KW - High-performance computing
KW - Parallel computing
UR - http://www.scopus.com/inward/record.url?scp=85099623870&partnerID=8YFLogxK
U2 - 10.1016/j.cpc.2020.107808
DO - 10.1016/j.cpc.2020.107808
M3 - Article
AN - SCOPUS:85099623870
SN - 0010-4655
VL - 262
JO - Computer Physics Communications
JF - Computer Physics Communications
M1 - 107808
ER -