A Retraction-free Method for Nonsmooth Minimax Optimization over a Compact Manifold

Abstract

We study the minimax problem x∈ M y fr(x,y):=f(x,y)-h(y), where M is a compact submanifold, f is continuously differentiable in (x, y), h is a closed, weakly-convex (possibly non-smooth) function and we assume that the regularized coupling function -fr(x,·) is either μ-PL for some μ>0 or concave (μ = 0) for any fixed x in the vicinity of M. To address the nonconvexity due to the manifold constraint, we use an exact penalty for the constraint x ∈ M, and enforcing a convex constraint x∈ X for some X ⊃ M, onto which projections can be computed efficiently. Building upon this new formulation for the manifold minimax problem in question, a single-loop smoothed manifold gradient descent-ascent (sm-MGDA) algorithm is proposed. Theoretically, any limit point of sm-MGDA sequence is a stationary point of the manifold minimax problem and sm-MGDA can generate an O(ε)-stationary point of the original problem with O(1/ε2) and O(1/ε4) complexity for μ > 0 and μ = 0 scenarios, respectively. Moreover, for the μ = 0 setting, through adopting Tikhonov regularization of the dual, one can improve the complexity to O(1/ε3) at the expense of asymptotic stationarity. The key component, common in the analysis of all cases, is to connect ε-stationary points between the penalized problem and the original problem by showing that the constraint x ∈ X becomes inactive and the penalty term tends to 0 along any convergent subsequence. To our knowledge, sm-MGDA is the first retraction-free algorithm for minimax problems over compact submanifolds, and this is a very desirable algorithmic property since through avoiding retractions, one can get away with matrix orthogonalization subroutines required for computing retractions to manifolds arising in practice, which are not GPU friendly.

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