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I wrote a little haskell program that just counts how many ones there are in a number (Int). When I try to execute it haskell complains about ambigous variable constraints. I know that it comes from the use of floor. I also read some of the answers on stackoverflow. But I didn't really find a way around that. Here's my code:

count_ones = count_ones' 0

count_ones' m 0 = m
count_ones' m n | n-10*n_new == 1 = count_ones' (m+1) n_new
                | otherwise         = count_ones' m n_new
                 where n_new = floor (n/10)

Any advice?

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What's the exact error message? (And have you tried giving a type signature yourself?) – huon Sep 10 '12 at 14:47
up vote 5 down vote accepted
count_ones' m n | n-10*n_new == 0.1 = count_ones' (m+1) n_new
                | otherwise         = count_ones' m n_new
                 where n_new = floor (n/10)

In the first line, you compare n - 10*n_new to the fractional literal 0.1, so the type of n and n_new must be a member of the Fractional class.

In the where clause, you bind n_new = floor (n/10), so the type of n_new must be a member of the Integral class.

Since no standard type is a member of both classes (for good reasons), the compiler can't resolve the constraint

(Fractional a, Integral a) => a

when the function is called.

If you give type signatures to your functions, the compiler can often generate more helpful error messages.

The simplest fix for your problem is to change the binding of n_new to

n_new = fromIntegral (floor $ n/10)

Considering that in the comments you said that the 0.1 was a mistake and you should have used 1 instead, you probably want to use Integral types only and the closest transcription of your code would be

count_ones' :: Integral a => Int -> a -> Int
count_ones' m 0 = m
count_ones' m n
    | n - 10*n_new == 1 = count_ones' (m+1) n_new
    | otherwise         = count_ones' m n_new
        n_new = n `div` 10

but it might be clearer to replace the condition n - 10*n_new == 1 with n `mod` 10 == 1.

However, that would require two divisions per step, which probably is less efficient. Using divMod should give you the quotient and remainder of the division with only one division instruction,

count_ones' m n = case n `divMod` 10 of
                    (q,1) -> count_ones' (m+1) q
                    (q,_) -> count_ones' m q

and if you can guarantee that you will only call the function with non-negative n, use quot and rem resp. quotRem instead of div and mod resp. divMod. The former functions use the results of the machine division instruction directly, while the latter need some post-processing to ensure that the result of mod is non-negative, so quot and friends are more efficient than div and company.

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Thanks for the quick reply. That was what I needed. Also I wanna hint a small misstake I did in the code above. The 0.1 must be a 1. – derwahre_tj Sep 10 '12 at 15:00
I wondered. Then it's more likely that you want the type to be an Integral type, and you should probably use some combination of div, mod, quot, rem rather than converting to a Fractional type for the division. – Daniel Fischer Sep 10 '12 at 15:06
If you have the time for a short suggestion code. Please feel free to send it to me. I would appreciate it! – derwahre_tj Sep 10 '12 at 15:14
Updated the answer with example code and some useful suggestions regarding efficiency. – Daniel Fischer Sep 10 '12 at 15:30
Neat. Thanks a lot! – derwahre_tj Sep 10 '12 at 15:58

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