The difficulty probably comes from confusing type variables and how
you reason about type unification. The trick is to consider, as
others have said, that (->) is right-associative, meaning you can
line things up like this (making new type variables for each
signature to avoid confusion):

```
(.) :: (b -> c ) -> (a -> b ) -> a -> c
concatMap :: (q -> [r]) -> ([q] -> [r])
replicate :: (Int -> (s -> [s])
```

This essentially gives us some constraints we need to resolve.
Let's say that "a ~ b" means "a is the same type as b" or
equivalently "a can be substituted with b."

From just the above, we can infer the following facts:

```
a ~ Int
b ~ (q -> [r]) ~ (s -> [s])
c ~ ([q] -> [r])
```

But the two equivalences for b tell us that

```
(q -> [r]) ~ (s -> [s])
```

which entails that

```
q ~ s and [r] ~ [s]
```

So then we rewrite c as:

```
c ~ ([q] -> [r]) ==> ([s] -> [s]))
```

Plugging the substitutions for a and c back into the original
type of (.) with the two functions applied yields

```
a -> c ~ Int -> ([s] -> [s])
```

which of course is now in the form that ghci reports: `Int -> [b] -> [b]`

.

`a -> [a]`

matches`a -> [b]`

? – sepp2k Aug 3 '12 at 21:32`a`

s and`b`

s part is pretty clear (I think) – artemave Aug 3 '12 at 22:31