Lagrangian Decomposition for Neural Network Verification
Abstract
A fundamental component of neural network verification is the computation of bounds on the values their outputs can take. Previous methods have either used off-the-shelf solvers, discarding the problem structure, or relaxed the problem even further, making the bounds unnecessarily loose. We propose a novel approach based on Lagrangian Decomposition. Our formulation admits an efficient supergradient ascent algorithm, as well as an improved proximal algorithm. Both the algorithms offer three advantages: (i) they yield bounds that are provably at least as tight as previous dual algorithms relying on Lagrangian relaxations; (ii) they are based on operations analogous to forward/backward pass of neural networks layers and are therefore easily parallelizable, amenable to GPU implementation and able to take advantage of the convolutional structure of problems; and (iii) they allow for anytime stopping while still providing valid bounds. Empirically, we show that we obtain bounds comparable with off-the-shelf solvers in a fraction of their running time, and obtain tighter bounds in the same time as previous dual algorithms. This results in an overall speed-up when employing the bounds for formal verification. Code for our algorithms is available at https://github.com/oval-group/decomposition-plnn-bounds.
Cite
@article{arxiv.2002.10410,
title = {Lagrangian Decomposition for Neural Network Verification},
author = {Rudy Bunel and Alessandro De Palma and Alban Desmaison and Krishnamurthy Dvijotham and Pushmeet Kohli and Philip H. S. Torr and M. Pawan Kumar},
journal= {arXiv preprint arXiv:2002.10410},
year = {2020}
}
Comments
UAI 2020 conference paper