We study black-box model stealing attacks where the attacker can query a machine learning model only through publicly available APIs. Specifically, our aim is to design a black-box model extraction attack that uses minimal number of queries to create an informative and distributionally equivalent replica of the target model. First, we define distributionally equivalent and max-information model extraction attacks. Then, we reduce both the attacks into a variational optimisation problem. The attacker solves this problem to select the most informative queries that simultaneously maximise the entropy and reduce the mismatch between the target and the stolen models. This leads us to an active sampling-based query selection algorithm, Marich. We evaluate Marich on different text and image data sets, and different models, including BERT and ResNet18. Marich is able to extract models that achieve $69-96\%$ of true model's accuracy and uses $1,070 - 6,950$ samples from the publicly available query datasets, which are different from the private training datasets. Models extracted by Marich yield prediction distributions, which are $\sim2-4\times$ closer to the target's distribution in comparison to the existing active sampling-based algorithms. The extracted models also lead to $85-95\%$ accuracy under membership inference attacks. Experimental results validate that Marich is query-efficient, and also capable of performing task-accurate, high-fidelity, and informative model extraction.