In this paper, we consider a class of Forward--Backward (FB) splitting
methods that includes several variants (e.g. inertial schemes, FISTA) for
minimizing the sum of two proper convex and lower semi-continuous functions,
one of which has a Lipschitz continuous gradient, and the other is partly
smooth relatively to a smooth active manifold M. We propose a
unified framework, under which we show that, this class of FB-type algorithms
(i) correctly identifies the active manifolds in a finite number of iterations
(finite activity identification), and (ii) then enters a local linear
convergence regime, which we characterize precisely in terms of the structure
of the underlying active manifolds. For simpler problems involving polyhedral
functions, we show finite termination. We also establish and explain why FISTA
(with convergent sequences) locally oscillates and can be slower than FB. These
results may have numerous applications including in signal/image processing,
sparse recovery and machine learning. Indeed, the obtained results explain the
typical behaviour that has been observed numerically for many problems in these
fields such as the Lasso, the group Lasso, the fused Lasso and the nuclear norm
regularization to name only a few.Comment: Full length version of the previous short on