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We study the problem of online learning and online regret minimization when samples are drawn from a general unknown \emph{non-stationary} process. We introduce the concept of a \emph{dynamic changing process} with cost $K$, where the \emph{conditional} marginals of the process can vary arbitrarily, but that the number of different conditional marginals is bounded by $K$ over $T$ rounds. For such processes we prove a tight (upto $\sqrt{\log T}$ factor) bound $O(\sqrt{KT\cdot\vch\log T})$ for the \emph{expected worst case} regret of any finite VC-dimensional class $\mathcal{H}$ under absolute loss (i.e., the expected miss-classification loss). We then improve this bound for general mixable losses, by establishing a tight (up to $\log^3 T$ factor) regret bound $O(K\cdot\vch\log^3 T)$. We extend these results to general \emph{smooth adversary} processes with \emph{unknown} reference measure by showing a sub-linear regret bound for $1$-dimensional threshold functions under a general bounded convex loss. Our results can be viewed as a first step towards regret analysis with non-stationary samples in the \emph{distribution blind} (universal) regime. This also brings a new viewpoint that shifts the study of complexity of the hypothesis classes to the study of the complexity of processes generating data.