# Inferring function type from function definition Haskell

So I was taking a test about Haskell and one question said:

let the function be

``````lolo g x = ys
where ys = [x] ++ filter (curry g x) ys
``````

then determine the type of the function called lolo. The options are:

``````a) (a,b) -> Bool -> b -> [(a,b)]
b) (b -> b -> b) -> Bool -> [b]
c) ((b,b) -> Bool) -> b -> [b]
d) (a -> b -> Bool) -> b -> [c]
``````

Can somebody please explain which one it is and why? I'm really confused about this one... things I do not understand are:

1) the curry function can only be applied to functions right? not datatypes that may be tuples? then you can infer that g is a function in this context? what if g and x are both functions? is it possible to use curry with nth arguments? I've only seen curry used with 1 argument.

2) the other thing I don't understand very much is the recursion in the definition of ys. so ys is defined by ys, but I don't see the base case in this scenario. Will it ever end? maybe it's the filter function that makes the recursion end.

3) also in curry g x = curry (g x) right? (this is a question about precedence in application of functions)

Thanks a lot

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similar question: stackoverflow.com/questions/23315823/…. – Will Ness Apr 27 '14 at 22:40

1) The first argument to `curry` has to be a function, it is what is known as a higher order function, it takes a function and returns a new one. While its type is printed out in GHCi as

``````curry :: ((a, b) -> c) -> a -> b -> c
``````

It is more clearly represented (IMO) as

``````curry :: ((a, b) -> c) -> (a -> b -> c)
``````

Which makes it more obvious that it takes a function and returns a new function. Technically, you could say that `curry` takes 3 arguments, one of type `(a, b) -> c`, one of type `a`, and one of type `b`. It just takes a function that normally accepts a tuple of arguments and converts it into a function that takes 2 arguments.

2) The computation for `ys` will never end, don't bother trying to call `length` on it, you'll just run the computation forever. This isn't a problem, though, you can work with infinite lists and non-terminating lists just fine (non-terminating being a list where it takes forever to compute the next element, not just one that has infinite elements). You can still use functions like `take` and `drop` on it, though.

3) Does `curry g x == curry (g x)`? No! When you see an expression like `a b c d e`, all of `b`, `c`, `d`, and `e` are arguments to `a`. If you instead saw `a b c (d e)`, then `e` is applied to `d`, and that result is applied to `a b c`. Consider `filter even [1..10]`, this is certainly not the same as `filter (even [1..10])`, since it wouldn't even compile! (`even :: Integral a => a -> Bool`).

When solving this sort of problem, first look at what functions are used in the expression that you already know the types of:

``````(++)   :: [a] -> [a] -> [a]
filter :: (b -> Bool) -> [b] -> [b]
curry  :: ((c, d) -> e) -> c -> d -> e
``````

I've used different type variables in each so that there will be less confusion when trying to line up the types. You can get these types by loading up GHCi, then typing

``````> :type (++)
(++) :: [a] -> [a] -> [a]
> -- Or just use :t
> :t filter
filter :: (a -> Bool) -> [a] -> [a]
> :t curry
curry :: ((a, b) -> c) -> a -> b -> c
``````

As you can see, I've changed `filter` to use `b` instead of `a`, and `curry` to use `c`, `d`, and `e`. This doesn't change the meaning any more than `f x = x + 1` versus `f y = y + 1`, it'll just make it easier to talk about.

Now that we've broken down our function into its subcomponents, we can work from the "top" down. By top, I mean the last function that gets called, namely `(++)`. You can picture this function by a tree like

``````    (++)
/    \
[x]     filter
/      \
curry     ys
/     \
g       x
``````

So we can clearly see that `(++)` is at the top. Using that, we can infer that `[x]` has the type `[a]`, which means that `x ~ a` (the tilde is the type equality symbol) and consequently `ys ~ [a]`, since `ys = [x] ++ something`. Now that we know the type of `x`, we can start filling out the rest of the expression. Next, we work down to `filter (curry g x) ys`. Since it is the second argument to `(++)`, we can infer that this subexpression also has the type `[a]`. If we look at the type of `filter`:

``````filter :: (b -> Bool) -> [b] -> [b]
``````

The final result is a list of type `[b]`. Since it's being applied to `[x] ++`, we can infer that `filter (curry g x) ys :: [a]`. This means that `[b] ~ [a] => b ~ a`. For reference, this makes `filter`'s type

``````filter :: (a -> Bool) -> [a] -> [a]
``````

This now places a constraint on `curry g x`, it must fit into `filter`'s first argument which has the type `a -> Bool`. Looking at `curry`'s type again:

``````curry :: ((c, d) -> e) -> c -> d -> e
``````

This means that `e ~ Bool`, and `d ~ a`. If we plug those back in

``````curry :: ((c, a) -> Bool) -> c -> a -> Bool
``````

Ignoring `g` for now, we look at the type of `x`, which we figured out is `a`. Since `x` is the second argument to `curry`, that means that `x` matches with the argument of type `c`, implying that `c ~ a`. Substituting this into what we just computed we get

``````curry :: ((a, a) -> Bool) -> a -> a -> Bool
``````

With

``````               curry g x     :: a -> Bool
filter (curry g x)    :: [a] -> [a]
filter (curry g x) ys :: [a]
[x] ++ filter (curry g x) ys :: [a]
``````

From this we can directly infer that `lolo`'s type signature ends with `[a]`, so

``````lolo :: ??? -> [a]
``````

I'll leave you to do the remaining few steps to figure out what `???` is.

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Great visualization of the tree structure of a program. It's an essential concept that I think many of us take for granted. – luqui Apr 27 '14 at 23:12