# What is the type signature of this Haskell function?

I wrote a function to check whether a number is prime or not:

prime n = prime' n 2 (floor (sqrt n))
where prime' n c u | n mod c == 0 = False
| c > u = True
| otherwise = prime' n (c+1) u


I can't figure out what the type signature of this function should be. At first I thought it should be this:

prime :: Integral a => a -> Bool


But then I get errors when compiling because sqrt expects a Floating a and floor expects a RealFrac a instead of an Integral a. When I remove the type signature, it compiles, but the function does not work:

*Euler> :t prime
prime :: (Integral a, RealFrac a, Floating a) => a -> Bool
*Euler> prime 5

<interactive>:1:0:
Ambiguous type variable t' in the constraints:
Floating t' arising from a use of prime' at <interactive>:1:0-6
RealFrac t' arising from a use of prime' at <interactive>:1:0-6
Integral t' arising from a use of prime' at <interactive>:1:0-6
Probable fix: add a type signature that fixes these type variable(s)


How can I make this function work?

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Hah, prime', read that aloud. ;-) –  Martijn May 6 '11 at 9:24
read it as prime-apostrophe first, then i realized prime-prime :) –  Vixen Jul 17 '12 at 12:56

The problem is that you use sqrt on n, which forces n to be a floating-point number; and you also use mod on n, which forces n to be an integer. Intuitively, from looking at your code, n should be an integer, so you can't directly call sqrt on it. Instead, you can use something like fromIntegral to convert it from an integer into another numeric type.

prime :: (Integral a) => a -> Bool
prime n = prime' n 2 (floor (sqrt (fromIntegral n)))
where prime' n c u | n mod c == 0 = False
| c > u = True
| otherwise = prime' n (c+1) u

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Just to go over one last bit that the other answers haven't covered...

*Euler> :t prime
prime :: (Integral a, RealFrac a, Floating a) => a -> Bool


The typechecker has inferred that prime can take an argument of type a as long as a is an instance of the Integral, RealFrac, and Floating classes all at once.

*Euler> prime 5

<interactive>:1:0:
Ambiguous type variable t' in the constraints:
Floating t' arising from a use of prime' at <interactive>:1:0-6
RealFrac t' arising from a use of prime' at <interactive>:1:0-6
Integral t' arising from a use of prime' at <interactive>:1:0-6
Probable fix: add a type signature that fixes these type variable(s)


When you ask it to prime 5, however, it complains that none of the default types of 5 can satisfy those conditions.

It's quite possible that you could write your own

instance (Integral a, RealFrac b, Floating b) => Integral (Either a b) where ...
instance (Integral a, RealFrac b, Floating b) => RealFrac (Either a b) where ...
instance (Integral a, RealFrac b, Floating b) => Floating (Either a b) where ...


(and you'd also have to add Num, Ord, Real, Fractional, etc. instances), and then prime 5 would be acceptable, since there would exist a 5 :: Either Integer Float which does satisfy the type conditions.

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Alternatively, you could change the upper-bound test:

prime n = prime' n 2
where prime' n c | n mod c == 0 = False
| c * c > n = True
| otherwise = prime' n (c+1)


Btw, you don't need n as an argument to prime' since it is constant through all calls.

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Further micro-optimization: prime n = prime' 2 4 where prime' c s | n mod c == 0 = False | s > n = True | otherwise = prime' (succ c) (s+c+c+1): that is, avoiding multiplication by using "n^2 = 1 + 3 + .. + (2*n-1)". It's probably not worth it though :) –  ephemient May 21 '09 at 16:34
You can change (sqrt n) to (sqrt (fromInteger n)) to make the function work as expected. This is needed because the type of sqrt is:
sqrt :: (Floating a) => a -> a

sqrt (2 :: Int)