Low communication high performance ab initio density matrix renormalization group algorithms

There has been recent interest in the deployment of ab initio density matrix renormalization group (DMRG) computations on high performance computing platforms. Here, we introduce a reformulation of the conventional distributed memory ab initio DMRG algorithm that connects it to the conceptually simp...

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Published inThe Journal of chemical physics Vol. 154; no. 22; p. 224116
Main Authors Zhai, Huanchen, Chan, Garnet Kin-Lic
Format Journal Article
LanguageEnglish
Published Melville American Institute of Physics 14.06.2021
Subjects
Algorithms
Benzene
Central processing units
CPUs
Density
Distributed memory
Electrons
High performance computing
Mathematical analysis
Microprocessors
Orbitals
Online AccessGet full text
ISSN0021-9606
1089-7690
1520-9032
1089-7690
DOI10.1063/5.0050902

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Abstract There has been recent interest in the deployment of ab initio density matrix renormalization group (DMRG) computations on high performance computing platforms. Here, we introduce a reformulation of the conventional distributed memory ab initio DMRG algorithm that connects it to the conceptually simpler and advantageous sum of the sub-Hamiltonian approach. Starting from this framework, we further explore a hierarchy of parallelism strategies that includes (i) parallelism over the sum of sub-Hamiltonians, (ii) parallelism over sites, (iii) parallelism over normal and complementary operators, (iv) parallelism over symmetry sectors, and (v) parallelism within dense matrix multiplications. We describe how to reduce processor load imbalance and the communication cost of the algorithm to achieve higher efficiencies. We illustrate the performance of our new open-source implementation on a recent benchmark ground-state calculation of benzene in an orbital space of 108 orbitals and 30 electrons, with a bond dimension of up to 6000, and a model of the FeMo cofactor with 76 orbitals and 113 electrons. The observed parallel scaling from 448 to 2800 central processing unit cores is nearly ideal.
AbstractList There has been recent interest in the deployment of ab initio density matrix renormalization group (DMRG) computations on high performance computing platforms. Here, we introduce a reformulation of the conventional distributed memory ab initio DMRG algorithm that connects it to the conceptually simpler and advantageous sum of the sub-Hamiltonian approach. Starting from this framework, we further explore a hierarchy of parallelism strategies that includes (i) parallelism over the sum of sub-Hamiltonians, (ii) parallelism over sites, (iii) parallelism over normal and complementary operators, (iv) parallelism over symmetry sectors, and (v) parallelism within dense matrix multiplications. We describe how to reduce processor load imbalance and the communication cost of the algorithm to achieve higher efficiencies. We illustrate the performance of our new open-source implementation on a recent benchmark ground-state calculation of benzene in an orbital space of 108 orbitals and 30 electrons, with a bond dimension of up to 6000, and a model of the FeMo cofactor with 76 orbitals and 113 electrons. The observed parallel scaling from 448 to 2800 central processing unit cores is nearly ideal.
Author Chan, Garnet Kin-Lic
Zhai, Huanchen
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  fullname: Chan, Garnet Kin-Lic
  organization: Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, California 91125, USA
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Snippet There has been recent interest in the deployment of ab initio density matrix renormalization group (DMRG) computations on high performance computing platforms....
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SubjectTerms Algorithms
Benzene
Central processing units
CPUs
Density
Distributed memory
Electrons
High performance computing
Mathematical analysis
Microprocessors
Orbitals
Title Low communication high performance ab initio density matrix renormalization group algorithms
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