This note studies the average-case comparison-complexity of sorting n elements when there is a known distribution on inputs and the goal is to minimize the expected number of comparisons. We generalize Fredman’s algorithm which is a variant of insertion sort and provide a basically tight upper bound: If μ is a distribution on permutations on n elements, then one may sort inputs from μ with expected number of comparisons that is at most H(μ) + 2n, where H is the entropy function. The algorithm uses less comparisons for more probable inputs: For every permutation π, the algorithm sorts π by using at most log 2 ( 1 Pr μ ( π ) ) + 2 n $\log _{2}(\frac {1}{\Pr _{\mu }(\pi )})+2n$ comparisons. A lower bound on the expected number of comparisons of H(μ) always holds, and a linear dependence on n is also required.