Here goes a step-by-step take on this question.

Let's begin with:

```
((lenDigits . factorial) 199) <= 199
```

According to the Haskell Report...

An integer literal represents the application of the function `fromInteger`

to the appropriate value of type `Integer`

.

That means our first expression is actually:

```
((lenDigits . factorial) (fromInteger (199 :: Integer))
<= (fromInteger (199 :: Integer))
```

By itself, `fromInteger (199 :: Integer)`

has the polymorphic type `Num a => a`

. We now have to see whether this type is specialised in the context of the whole expression. Note that, until we find a reason for it not being so, we should assume that the polymorphic types of the two occurrences of `fromInteger (199 :: Integer)`

are independent (`Num a => a`

and `Num b => b`

, if you will).

`lenDigits`

is `Show a => a -> Int`

, and so the...

```
(lenDigits . factorial) (fromInteger (199 :: Integer))
```

... to the left of the `<=`

must be an `Int`

. Given that `(<=)`

is `Ord a => a -> a -> Bool`

, the `fromInteger (199 :: Integer)`

to the right of the `<=`

also has to be an `Int`

. The whole expression then becomes:

```
((lenDigits . factorial) (fromInteger (199 :: Integer)) <= (199 :: Int)
```

While the second `199`

was specialised to `Int`

, the first one is still polymorphic. In the absence of other type annotations, defaulting makes it specialise to `Integer`

when we use the expression in GHCi. Therefore, we ultimately get:

```
((lenDigits . factorial) (199 :: Integer)) <= (199 :: Int)
```

Now, on to the second expression:

```
(\i -> ((lenDigits . factorial) i) <= i) 199
```

By the same reasoning used above, `(lenDigits . factorial) i`

(to the left of `<=`

) is an `Int`

, and so `i`

(to the right of `<=`

) is also an `Int`

. That being so, we have...

```
GHCi> :t \i -> (lenDigits . factorial) i <= i
\i -> (lenDigits . factorial) i <= i :: Int -> Bool
```

... and therefore applying it to `199`

(which is actually `fromInteger (199 :: Integer)`

) specialises it to int, giving:

```
((lenDigits . factorial) (199 :: Int)) <= (199 :: Int)
```

The first `199`

is now `Int`

rather than `Integer`

. `factorial (199 :: Int)`

overflows the fixed size `Int`

type, leading to a bogus result. One way of avoiding that would be introducing an explicit `fromInteger`

in order to get something equivalent to the first scenario:

```
GHCi> :t \i -> (lenDigits . factorial) i <= fromInteger i
\i -> (lenDigits . factorial) i <= fromInteger i :: Integer -> Bool
GHCi> (\i -> (lenDigits . factorial) i <= fromInteger i) 199
False
```

`(id True, id 'a')`

is fine but`(\f -> (f True, f 'a')) id`

is an error.`id`

polymorphic?`id`

is polymorphic; and`\f -> ...`

can be polymorphic; but inside the`...`

,`f`

itself isnotpolymorphic!`\f -> (f True, f 'a')`

is already a type error without ever mentioning`id`

. This restriction is put in place to make type inference easier and to preserve the desirable property that any term that can be given a type at all has a most general type.