I want to put a first-order theory into Z3, an SMT solver developed by Microsoft. This theory contains two objects *obj1* and *obj2*, a function *move* that takes an object and returns an action, and a one-placed predicate *occurs* that takes an action as argument. The theory contains the formula *occurs(move(obj1))*, and I want to make sure that this is the only way in which the *occurs* predicate is true. I do this by giving a definition of *occurs*:

```
forall (A) (occurs(A) <-> (A = move(obj1)))
```

This means that *occurs(move(obj1))* can be inferred from the theory, but *occurs(move(obj2))* cannot. To prove this, I have translated this into Z3 as follows:

```
(declare-datatypes () (( Obj obj1 obj2 )))
(declare-sort Action 0)
(declare-fun occurs (Action) Bool)
(declare-fun move (Obj) Action)
(assert (forall ((A Action)) (
= (occurs A) (= A (move obj1))
)))
(check-sat)
(get-value ((occurs (move obj1))))
(get-value ((occurs (move obj2))))
```

The problem is that this gives the following output:

```
sat
(((occurs (move obj1)) true))
(((occurs (move obj2)) true))
```

Which I do not understand, because the definition of *occurs* provides all the necessary and sufficient condition for the predicate to be true, so I would think that *occurs(move(obj2))* cannot be true in any model. What am I doing wrong?

**Update**
Thanks to de Moura I have been able to find a solution for my problem. What I need to do is to provide *unique names axioms* for the actions, which in my case is the `move`

function. I need to state that `move`

will never return the same element of sort `Action`

when it has two different arguments. This could be done in several ways, but I found this the most concise version:

```
(assert (forall ((o1 Obj) (o2 Obj))
(=> (not (= o1 o2)) (not (= (move o1) (move o2))))))
```