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I try to write a function, which takes a list of sublists, reverses sublists and returns concatenated, reversed sublists. Here is my attempt:

conrev :: Ord a => [[a]] -> [a]
conrev [[]] = []
conrev [[a]] = reverse [a]
conrev [(x:xs)] = reverse x ++ conrev [xs]

main = putStrLn (show (conrev [[1,2],[],[3,4]]))

I get this error:

    Could not deduce (a ~ [a])
    from the context (Ord a)
      bound by the type signature for conrev :: Ord a => [[a]] -> [a]
      at 3.hs:1:11-31
      `a' is a rigid type variable bound by
      the type signature for conrev :: Ord a => [[a]] -> [a] at 3.hs:1:11
    In the first argument of `reverse', namely `x'
    In the first argument of `(++)', namely `reverse x'
    In the expression: reverse x ++ conrev [xs]

What am I doing wrong? The second question is - could the type signature be more generic? I have to write as generic as possible.

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You don't need the Ord a => as far as I can see –  Adam Jan 8 '13 at 20:23
This way: conrev :: [[]] -> []? I get an error, Expecting one more argument to '[]' –  ciembor Jan 8 '13 at 20:31
try conrev :: [[a]] -> [a] –  Adam Jan 8 '13 at 20:33
Couldn't match expected type 'a' with actual type '[a]' 'a' is a rigid type variable bound by the type signature for conrev :: [[a]] -> [a] at 3.hs:1:11 –  ciembor Jan 8 '13 at 20:35

2 Answers 2

up vote 6 down vote accepted

In the equation

conrev [(x:xs)] = reverse x ++ conrev [xs]

you match a list containing a single element, which is a nonempty list x:xs. So, given the type

conrev :: Ord a => [[a]] -> [a]

the list x:xs must have type [a], and thus x :: a.

Now, you call reverse x, which means x must be a list, x :: [b]. And then you concatenate

reverse x :: [b]


conrev [xs] :: [a]

from which it follows that b must be the same type as a. But it was determined earlier that a ~ [b]. So altogether, the equation demands a ~ [a].

If you had not written the (unnecessary) Ord a constraint, you would have gotten the less opaque

Couldn't construct infinite type a = [a]


Your implementation would work if you removed some outer []:

conrev :: Ord a => [[a]] -> [a]
conrev [] = []
conrev [a] = reverse a
conrev (x:xs) = reverse x ++ conrev xs

but the better implementation would be

conrev = concat . map reverse
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Your second pattern doesn't match what you want, it looks like you're mistaking the structure of the type for the structure of the value.

[[a]] as a type means "A list of lists of some type a"

[[a]] as a pattern means "Match a List containing a single list which contains a single element which will be bound to the name a.

Edit: If I understand what you're trying to do the middle case is actually redundant. The third case will handle non-empty lists and the first case will handle empty lists. Making another case for the singleton list is unnecessary.

Edit 2:

There is a further problem with the implementation of the third case.

conrev :: Ord a => [[a]] -> [a]
conrev [(x:xs)] = reverse x ++ conrev [xs]

Given the type you see that x must be of type [a] and xs must be of type [[a]]. So writing conrev [xs] is passing a value of type [[[a]]] to conrev. This is where your type error is coming from. You're implicitly stating that [a] is the same type as a by calling convrev [xs].

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That's exactly what I had on my mind. I have a list of sublists with some type inside (in this case I push integers). And in a pattern match, I want to handle this case, when I have only one sublist. –  ciembor Jan 8 '13 at 20:29
Right but you're conflating the type syntax with pattern matching the value. Consider what your middle case does on the list [[1,2]], you get a pattern match error. On the case [[1]] a is bound to 1 and then you do reverse [1] which is technically correct but not useful. –  Andrew Myers Jan 8 '13 at 20:32
Hmm... OK, I removed it. But I still have a Could not deduce (a ~ [a]) problem. –  ciembor Jan 8 '13 at 20:34
ah, see my edit. There's another problem in the third case. –  Andrew Myers Jan 8 '13 at 20:39

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