Let me explain what I mean by a cost-sensitive fold with an example: calculating pi with arbitrary precision. We can use the Leibniz formula (not very efficient, but nice and simple) and lazy lists like this:
pi = foldr1 (+) [(fromIntegral $ 4*(-1)^i)/(fromIntegral $ 2*i+1) | i<-[0..]]
Now, obviously this computation will never complete because we must compute every value in the infinite list. But in practice, I don't need the exact value of pi, I just need it to some specified number of decimal places. I could define pi' like this:
pi' n = foldr1 (+) [(fromIntegral $ 4*(-1)^i)/(fromIntegral $ 2*i+1) | i<-[0..n]]
but it's not at all obvious what value for n I need to pass in to get the precision I want. What I need is some sort of cost-sensitive fold, that will stop folding whenever I achieve the required accuracy. Does such a fold exist?
(Note that in this case it is easy to see if we've achieved the required accuracy. Because the Leibniz formula uses a sequence that alternates sign with each term, the error will always be less than the absolute value of the next term in the sequence.)
Edit: It would be really cool to have cost-sensitive folds that could also consider computation time/power consumption. For example, I want the most accurate value of pi given that I have 1 hour of computation time and 10kW-hrs to spend. But I realize this would no longer be strictly functional.