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The following equations are written in Miranda Syntax, but due to the similarities between Miranda and Haskell I expect Haskell programmers should understand it!

If you define the following functions:

rc v g i = g (v:i)
rn x = x
rh g = hd (g [])

f [] y = y 
f (x:xs) y = f xs (rc x y)

g [] y = y
g (x:xs) y = g xs (x:y)

How do you work out the type of the functions? I think I understand how to work it out for f,g and rn but I'm confused about the partial application part.

rn is going to be * -> * (or anything -> anything, I think it's a -> a in Haskell?)

For f and g, are the function types both [*] -> * -> *?

I'm unsure how to approach finding the types for rc and rh though. In rc, g is being partially applied to the variable i - so I'm guessing that this constrains the type of i to be [*]. What order are rc and g applied in the definition of rc? Is g applied to i, and then the resulting function used as the argument for rc? Or does rc take 3 separate parameters of v,g and i? I'm really confused.. any help would be appreciated! Thanks guys.

Sorry forgot to add that hd is the standard head function for a list and is defined as:

hd :: [*] -> *
hd (a:x) = a
hd [] = error "hd []"
share|improve this question
Is this homework? – Riccardo Mar 30 '12 at 13:07
No, i'm preparing for exams right now and it's an old exam question for a Miranda exam. – user1058210 Mar 30 '12 at 13:11
What is the type of the hd function? – Riccardo Mar 30 '12 at 13:12
Sorry forgot to add that definition - i've added it to the question now! – user1058210 Mar 30 '12 at 13:29
up vote 6 down vote accepted

The type is inferred from what is already known of types and how expressions are used in the definition.

Let's begin at the top,

rc v g i = g (v : i)

so rc :: a -> b -> c -> d and we must see what can be found out about a, b, c and d. On the right hand side, there appears (v : i), so with v :: a, we see that i :: [a], c = [a]. Then g is applied to v : i, so g :: [a] -> d, altogether,

rc :: a -> ([a] -> d) -> [a] -> d

rn x = x means that there's no constraint on the argument type of rn and its return type is the same, rn :: a -> a.

rh g = hd (g [])

Since rh's argument g is applied to an empty list on the RHS, it must have type [a] -> b, possibly more information about a or b follows. Indeed, g [] is the argument of hd on the RHS, so g [] :: [c] and g :: [a] -> [c], hence

rh :: ([a] -> [c]) -> c


f [] y = y 
f (x:xs) y = f xs (rc x y)

The first argument is a list, and if that is empty, the result is the second argument, so f :: [a] -> b -> b follows from the first equation. Now, in the second equation, on the RHS, the second argument to f is rc x y, hence rc x y must have the same type as y, we called that b. But

rc :: a -> ([a] -> d) -> [a] -> d

, so b = [a] -> d. Hence

f :: [a] -> ([a] -> d) -> [a] -> d


g [] y = y
g (x:xs) y = g xs (x:y)

from the first equation we deduce g :: [a] -> b -> b. From the second, we deduce b = [a], since we take the head of g's first argument and cons it to the second, thus

g :: [a] -> [a] -> [a]
share|improve this answer
Thanks Daniel! With the first equation, rc, we apply g to i which we have identified as type [a] - but how do we know the output of the function is type d? Isn't that just the only the output of rc, and not necessarily also the output of g? – user1058210 Mar 30 '12 at 14:29
We don't know anything about the type of g's result from the definition of rc, so whatever is the result type of the passed argument g is the result type of rc in that call. For types that can be anything, we use a type variable, whether we call it d or simon is immaterial. Here we must not call it a, because that is already used for another type (but is is legal to pass a g1 :: [b] -> b, the type d may be equal to a, but it need not, hence it gets a different denotation). I left it d because that's what was the result type in the first approximation to rc's type. – Daniel Fischer Mar 30 '12 at 14:36
If the result of rc is simply another g function, why is the output of rc not given as [a] -> d? Making the whole thing: rc :: a -> ([a] -> d) -> [a] -> ([a] -> d) – user1058210 Mar 30 '12 at 14:58
The result of rc is not another g function, it's the result of applying g to (v:i), so rc's result type is g's result type. – Daniel Fischer Mar 30 '12 at 15:04
ahhh! Got it! Thanks for being so patient! – user1058210 Mar 30 '12 at 15:08

I'm going to use the haskell syntax to write types.

rc v g i = g (v:i)

Here rc takes three parameters, so its type will be something like a -> b -> c -> d. v:i must be a list of elements of the same type as v and i, so v :: a and i :: [a]. g is applied to that list, so that g :: [a] -> d. If you put all together, you get rc :: a -> ([a] -> d) -> [a] -> d.

As you already figured out rn :: a -> a, because it is simply the identity.

I have no idea about the type of the hd function you use in rh, so I'll skip that.

f [] y = y 
f (x:xs) y = f xs (rc x y)

Here f takes two parameters, so its type will be something like a -> b -> c. From the first case we can deduce that b == c, since we return y, and that the first argument is a list. For now we know that f :: [a'] -> b -> b. In the second case notice how x and y are given in input to rc: y must be a function [a'] -> d, and rc x y :: a' -> d (that must be also the type of y, since it is passed as it second argument of f). Finally, we can say that f :: [a'] -> ([a'] -> d) -> ([a'] -> d). Since -> is right-associative, this is equivalent to [a'] -> ([a'] -> d) -> [a'] -> d.

You can reason in the same manner for the remaining ones.

share|improve this answer
hd is from the Miranda standard library. It's equivalent to head in Haskell, so its type is [a] -> a. – hammar Mar 30 '12 at 14:15
Thanks Riccardo! Could you take a look at the question I've asked Daniel as it also applies to your answer - thanks! – user1058210 Mar 30 '12 at 14:31
Pleasure. I'm sorry, I arrived late. He already explained you :) – Riccardo Mar 30 '12 at 15:13

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