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We study the task of online learning in the presence of Massart noise. Specifically, instead of assuming that the online adversary chooses an arbitrary sequence of labels, we assume that the context $\boldsymbol{x}$ is selected adversarially but the label $y$ presented to the learner disagrees with the ground-truth label of $\boldsymbol{x}$ with unknown probability {\em at most} $\eta$. We focus on the fundamental class of $\gamma$-margin linear classifiers and present the first computationally efficient algorithm that achieves mistake bound $\eta T + o(T)$. We point out that the mistake bound achieved by our algorithm is qualitatively tight for computationally efficient algorithms; this follows from the fact that, even in the offline setting, achieving 0-1 error better than $\eta$ requires super-polynomial time under standard complexity assumptions.We extend our online learning model to a $k$-arm contextual bandit setting where the rewards---instead of satisfying commonly used realizability assumptions---are consistent, in expectation, with some linear ranking function with weight vector $\boldsymbol{w}^\ast$. Given a list of contexts $\boldsymbol{x}_1,\ldots \boldsymbol{x}_k$, if $\boldsymbol{w}^*\cdot \boldsymbol{x}_i > \boldsymbol{w}^* \cdot \boldsymbol{x}_j$, the expected reward of action $i$must be larger than that of $j$ by at least $\Delta$. We use our Massart online learner to design an efficient bandit algorithm that obtains expected reward at least $(1-1/k)~ \Delta T - o(T)$ bigger than choosing a random action at every round.