Scalable Parallel Factorizations of SDD Matrices and Efficient Sampling for Gaussian Graphical Models

TL;DR

This paper introduces a nearly optimal parallel algorithm for factorizing SDD matrices, enabling efficient sampling of Gaussian graphical models with nearly linear work and minimal randomness, advancing computational statistical inference.

Contribution

The paper presents the first nearly linear work parallel algorithm for factorizing SDD matrices and sampling Gaussian fields, improving efficiency and randomness requirements.

Findings

Nearly linear work in matrix non-zero entries

Polylogarithmic parallel depth

Optimal randomness for Gaussian sampling

Abstract

Motivated by a sampling problem basic to computational statistical inference, we develop a nearly optimal algorithm for a fundamental problem in spectral graph theory and numerical analysis. Given an $n\times n$ SDDM matrix ${\bf \mathbf{M}}$, and a constant $-1 \leq p \leq 1$, our algorithm gives efficient access to a sparse $n\times n$ linear operator $\tilde{\mathbf{C}}$ such that $${\mathbf{M}}^{p} \approx \tilde{\mathbf{C}} \tilde{\mathbf{C}}^\top.$$ The solution is based on factoring ${\bf \mathbf{M}}$ into a product of simple and sparse matrices using squaring and spectral sparsification. For ${\mathbf{M}}$ with $m$ non-zero entries, our algorithm takes work nearly-linear in $m$, and polylogarithmic depth on a parallel machine with $m$ processors. This gives the first sampling algorithm that only requires nearly linear work and $n$ i.i.d. random univariate Gaussian samples to generate i.i.d. random samples for $n$-dimensional Gaussian random fields with SDDM precision matrices. For sampling this natural subclass of Gaussian random fields, it is optimal in the randomness and nearly optimal in the work and parallel complexity. In addition, our sampling algorithm can be directly extended to Gaussian random fields with SDD precision matrices.