**The short answer is:** In your first function definition type inference easily infers that `x`

is of type `bool`

, while in your second definition, the bound variable `a`

is not used anywhere else and thus its type is arbitrary (`'a`

). Which is what *Additional type variable(s) in specification ...* expresses.

If you constrain the type of `a`

explicitly, e.g.,

```
fun g :: "nat ⇒ bool" where
"g _ = (True ∨ (∀a::bool. True))"
```

the function definition is accepted.

**A longer answer:** Since the definition of `g`

is not recursive you could turn it into using `definition`

instead of `fun`

. Then your first attempt does not fail completely but the result might surprise you. After

```
definition g :: "nat ⇒ bool" where
"g _ = (True ∨ (∀a. True))"
```

the type of `g`

is `'a itself => nat => bool`

instead of the intended `nat => bool`

. The reason is the same as for the failure of `fun`

before. Since `a`

is of arbitrary type, this additional type has to be recorded in the type of `g`

, which is done by introducing an additional dummy argument which just states this additional type explicitly. Here `'a itself`

is a type whose constructor `TYPE(...)`

-- taking a *type* as argument -- allows us to encode type information on the term level. E.g.,

```
TYPE('a) :: 'a itself
TYPE(bool) :: bool itself
TYPE(nat) :: nat itself
```

Then `g TYPE(nat)`

is the version of `g`

where `a`

is fixed to be of type `nat`

.

Concerning your `value`

statements, the reason for the second one to fail is not really related to the above. In the first statement the universal quantifier binds a variable of type `bool`

whose values can be enumerated explicitly and thus a result can be *computed* by considering all those values. In contrast, in your second statement the bound variable `x`

is of an arbitrary type `'a`

whose values cannot be enumerated explicitly.