You say "either lists or immutable arrays", but those are actually two very different things, and in many cases algorithms naturally suited to lists would be no faster (and possibly slower) when used with mutable arrays.
For instance, consider an algorithm consisting of three parts: Constructing a list from some input, transforming the list by combining adjacent elements, then filtering the list by some criterion. A naive approach of fully generating a new list at each step would indeed be inefficient; a mutable array updated in place at each step would be an improvement. But better still is to observe that only a limited number of elements are needed simultaneously and that the linear nature of the algorithm matches the linear structure of a list, which means that all three steps can be merged together and the intermediate lists eliminated entirely. If the initial input used to construct the list and the filtered result are significantly smaller than the intermediate list, you'll save a lot of overhead by avoiding extra allocation, instead of filling a mutable array with elements that are just going to be filtered out later anyway.
Mutable arrays are most likely to be useful when making a lot of piecemeal, random-access updates to an array, with no obvious linear structure. When using Haskell's immutable arrays, in many cases this can be expressed using the
accum function in
Data.Array, which I believe is already implemented using
In short, a lot of the simple cases either have better optimizations available or are already handled.
Edit: I notice this answer was downvoted without comment and I'm curious why. Feedback is appreciated, I'd like to know if I said something dumb.