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?

`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`(.)`

is simply the composition, i.e.`(f . g) x = f ( g x )`

. – Riccardo Feb 29 '12 at 15:03