I'm totally new to Haskell so apologies if the question is silly.
What I want to do is recursively build a list while at the same time building up an accumulated value based on the recursive calls. This is for a problem I'm doing for a Coursera course, so I won't post the exact problem but something analogous.
Say for example I wanted to take a list of ints and double each one (ignoring for the purpose of the example that I could just use
map), but I also wanted to count up how many times the number '5' appears in the list.
So to do the doubling I could do this:
foo  =  foo (x:xs) = x * 2 : foo xs
So far so easy. But how can I also maintain a count of how many times
x is a five? The best solution I've got is to use an explicit accumulator like this, which I don't like as it reverses the list, so you need to do a reverse at the end:
foo total acc  = (total, reverse acc) foo total acc (x:xs) = foo (if x == 5 then total + 1 else total) (x*2 : acc) xs
But I feel like this should be able to be handled nicer by the
State monad, which I haven't used before, but when I try to construct a function that will fit the pattern I've seen I get stuck because of the recursive call to
foo. Is there a nicer way to do this?
EDIT: I need this to work for very long lists, so any recursive calls need to be tail-recursive too. (The example I have here manages to be tail-recursive thanks to Haskell's 'tail recursion modulo cons').