Aside from the other answers, which provide ways to fix your function, you may want to consider writing this in a more compositional style. Specifically, look for ways you could write a function by building up other, standard functions. Suppose you have a function that will remove everything that isn't equal to the test letter from a list.
myFilter :: Char -> [Char] -> [Char
myFilter = ...
myFilter, you'd be left with a list with only the element you're checking for. At this point, you can just use
length to get the length of the list:
countLetter :: Char -> [Char] -> Int
countLetter a b = length $ myFilter a b
So now you just need to define
myFilter, which can be done with the standard Prelude function
myFilter a b = filter (==a) b
For a function this small, creating our own definition is hardly worth it, as you can just write
countLetter a b = length $ filter (== a) b
Now, define this in ghci to see what type it finds for the function
Prelude> let countLetter a b = length $ filter (== a) b
Prelude> :t countLetter
countLetter :: Eq a => a -> [a] -> Int
Char in sight! The implementation doesn't depend on the elements being letters, only that they can be compared for equality (this is true of your approach also). So ghci reflects that in the calculated type. But you can see that this is exactly the type you want by substituting
Many functional programmers tend to find this approach, i.e. building functions by composing smaller parts, particularly easy to reason about, so it can be quite common. Especially when working with lists, you might want to see if you can write an implementation using so-called higher-order functions, such as
filter, or a fold, instead of using recursion. Sometimes recursion is the clearest way, but I expect you will frequently find function composition to be a better approach.