# How can i manually determine the most general types for the following functions?

Currently I am learning Haskell. We have to determine the most general types for given functions, but I do not get it yet. How does the interpreter determine the most general type of the function, especially lambda expressions? What is a secure way to determine the most general type manually?

tx2 = (\x y z -> y.z.z)

tx2::a->(a->b)->(a->a)->b -- my guess

tx2 :: a -> (b -> c) -> (b -> b) -> b -> c -- interpreter solution

If the first variable (a) is applied to expression z, then z must take a as an input parameter, but it consumes b instead in (b->b). y consumes b and generates c, so the final result must be c. But why is b (as intermediate result?) contained in the type? And if so, why is it not a -> (b -> c) -> (b -> b) -> b-> b -> c ?

tm2 = (\i -> [sum,product]!!i)

tm2:: Int->[(Integer->Integer->Integer)]->(Integer->Integer->Integer) -- my guess

\i -> [sum,product] !! i :: Num a => Int -> [a] -> a -- interpreter with direct input
tm2 :: Int -> [Integer] -> Integer -- interpreter with :info tm2

So the interpreter has more detailed information about the type if tm2 is in coded in the script, right? So the type in the second line is the result of the expression. Why are only Integers accepted in line 2, not Float for example?

tp2 = (\x -> \y -> (x.y.x))

tp2::(a->b)->((a->b)->a)->a -- my guess

tp2 :: (a -> b) -> (b -> a) -> a -> b -- interpreter solution

Why do I have to include the intermediate result a here in the type? Why is \y not represented using (a->b)->a like in tf2 below?

tf2 = (\x -> \y -> (x (y x), x, y))

tf2::(a->b)->((a->b)->a)->(a,a->b,(a->b)->a) -- solution

tg2 = (\x y z a -> y(z(z(a))));

tg2::a->(b->c)->(b->b)->b->c -- solution

Here we do not need any intermediate results? We write down the types of the params and then the type of the result?

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That's a lot of questions! That doesn't make it easy to answer, so I won't - but from your last examples (tp2 and tf2) you seem to be assuming that x.y.x and x (y x) are the same, but they're not! Also, I suspect you've made a typo in tx2... –  yatima2975 Feb 29 '12 at 13:54
Ahh so you mean that (.) :: (a -> b) -> (c -> a) -> c -> b is a specified operation which has something like an intermediate result, while an expression like x (y x) is of type a -> a . Thx, this is already the answer to one problem. –  Blackbam Feb 29 '12 at 14:03
@Blackbam: actually (.) is simply the composition, i.e. (f . g) x = f ( g x ). –  Riccardo Feb 29 '12 at 15:03
So (x.y.x) a would be the same as x(y(x a))) ? But this still does not explain the typing here.. –  Blackbam Feb 29 '12 at 15:22
Yes, it is. See my answer for an explanation. –  Riccardo Feb 29 '12 at 15:32

tx2 = (\x y z -> y.z.z)

tx2 takes three arguments (for the sake of discussion, I ignore currying), ignores the first and composes the second and twice the third. So the first argument can have any type, the second and third must have function type, say

y :: ay -> ry
z :: az -> rz

Now the result of the first application of z becomes the argument of the second application of z, so the result type of z, rz must be the argument type of z, az, let us call that b, so

z :: b -> b

Then the result of the z application becomes the argument of y, so the argument type of y must be the same type as the result type of z, but the result type of y is completely unconstrained by the expression, hence

y :: b -> c

and y . z . z :: b -> c, thus

tx2 :: a -> (b -> c) -> (b -> b) -> (b -> c)

Then the next,

tm2 = (\i -> [sum,product]!!i)

Now, sum and product are functions from the Prelude, both have the type Num a => [a] -> a, thus

Prelude> :t [sum,product]
[sum,product] :: Num a => [[a] -> a]

Since (!!) :: [e] -> Int -> e, given a list xs of type [e], the expression \i -> xs !! i has type Int -> e. Thus the inferred type of tm2 = \i -> [sum,product] !! i is

tm2 :: Num a => Int -> ([a] -> a)

But, tm2 is bound by a simple pattern binding without type signature, so the monomorphism restriction kicks in, and the type of tm2 has to be monomorphised. By the defaulting rules, a Num a constraint is resolved by instantiating the type variable a with Integer (unless an explicit default declaration says otherwise), so you get

Prelude> let tm2 = \i -> [sum,product] !! i
Prelude> :t tm2
tm2 :: Int -> [Integer] -> Integer

unless you disable the monomorphism restriction (:set -XNoMonomorphismRestriction).

tp2 = (\x -> \y -> (x.y.x))

The result of the first application of x becomes the argument of y, hence the result type of x must be the same as the argument type of y. Then the result of the application of y becomes the argument of the second application of x, so the result type of y must be the argument type of ´x`, altogether

tp2 :: (a -> b) -> (b -> a) -> (a -> b)

Then in

tf2 = (\x -> \y -> (x (y x), x, y))

the only interesting part is the first component of the result, x (y x), so x is applied to the result of an application of y, hence x must have a function type

x :: a -> b

and y must have result type a. But y is applied to x, so its argument type must be the type of x,

y :: (a -> b) -> a

and

tf2 :: (a -> b) -> ((a -> b) -> a) -> (b, a -> b, (a -> b) -> a)

Finally

tg2 = (\x y z a -> y(z(z(a))))

which is, by the way, exactly the same as tx2, only eta-expanded by providing one more argument in the lambda. Therefore the derivation of the type is the same too.

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