# Isabelle: Evaluating formula with Quantifiers

Why does the following work:

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

But this fails

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

with

``````Additional type variable(s) in specification of "g_graph": 'a
Specification depends on extra type variables: "'a"
The error(s) above occurred in "test.g_sumC_def"
The error(s) above occurred in definition "g_sumC_def":
"g_sumC ≡ λx. THE_default undefined (g_graph TYPE('a) x)"
``````

Similarly, the following succeeds,

``````value "True ∨ (∀x. x)"
``````

but this fails

``````value "True ∨ (∀x. True)"
``````

with

``````Wellsortedness error:
Type 'a not of sort enum
Cannot derive subsort relation {} < enum
``````
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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.

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I would like to add that recording the type of x in the function definition is absolutely necessary as well, i.e. this is not some technicality that one could get rid of somehow: imagine the function had not been ´∀x.x` but, for instance, `f _ = (∀x y. x=y)`. This function would evaluate to `true` for `'a = unit`, but to false for pretty much everything else. – Manuel Eberl Sep 16 '13 at 9:15

The following fails:

``````fun f where "f _ = (∀a. True)"
``````

because the type of `a` has hidden polymorphism (i.e., there is a type variable inside your function's body that is not present in the function's type signature), which upsets the function package's internal proofs.

If you explicitly give `a` a type as so:

``````fun f where "f _ = (∀a::bool. True)"
``````

or is you give `a` a type that is also in the function's type signature, as so:

``````fun f where "f _ = (∀a::bool. True)"
``````

the function definition succeeds. Your example:

``````fun f where "f _ = (∀x. x)"
``````

succeeds, because `x` is forced to be type `bool`.

As for your `value` commands, Isabelle attempts to generate executable code for your expression, and hence needs to not only know the type of your for-all statements, but also be able to enumerate all possible values of it, so that it can test them all. Types such as `bool` work fine, but type variables like `'a` or infinite types such as `nat` are not enumerable, and hence Isabelle cannot generate code for them.

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