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
'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
g TYPE(nat) is the version of
a is fixed to be of type
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.