Random Smoothing Might be Unable to Certify ∞ Robustness for High-Dimensional Images

Abstract

We show a hardness result for random smoothing to achieve certified adversarial robustness against attacks in the p ball of radius ε when p>2. Although random smoothing has been well understood for the 2 case using the Gaussian distribution, much remains unknown concerning the existence of a noise distribution that works for the case of p>2. This has been posed as an open problem by Cohen et al. (2019) and includes many significant paradigms such as the ∞ threat model. In this work, we show that any noise distribution D over Rd that provides p robustness for all base classifiers with p>2 must satisfy Eηi2=(d1-2/pε2(1-δ)/δ2) for 99% of the features (pixels) of vector η, where ε is the robust radius and δ is the score gap between the highest-scored class and the runner-up. Therefore, for high-dimensional images with pixel values bounded in [0,255], the required noise will eventually dominate the useful information in the images, leading to trivial smoothed classifiers.