I'm confused and struggling to understand how two different input formats for Z3 fixedpoint engine are related. Short example: suppose I want to prove the existance of negative numbers. I declare a function that returns 1 for non-negative numbers and 0 for negative and then asking solver to fail if there are arguments for which function returns 0. But there is one restriction: I want solver to respond `sat`

when there exists at least one negative number and `unsat`

if all numbers are non-negative.

It is trivially with using `declare-rel`

and `query`

format:

```
(declare-rel f (Int Int))
(declare-rel fail ())
(declare-var n Int)
(declare-var m Int)
(rule (=> (< n 0) (f n 0)))
(rule (=> (>= n 0) (f n 1)))
(rule (=> (and (f n m) (= m 0)) fail))
(query fail)
```

But it becomes tricky while using pure SMT-LIB2 format (with `forall`

). For example, straightforward

```
(set-logic HORN)
(declare-fun f (Int Int) Bool)
(declare-fun fail () Bool)
(assert (forall ((n Int))
(=> (< n 0) (f n 0))))
(assert (forall ((n Int))
(=> (>= n 0) (f n 1))))
(assert (forall ((n Int) (m Int))
(=> (and (f n m) (= m 0)) fail)))
(assert (not fail))
(check-sat)
```

returns `unsat`

. Unsurprisingly, changing `(= m 0)`

to `(= m 1)`

results the same. We can get `sat`

only implying `fail`

from `(= m 2)`

. The problem is that I can't understand, *how to ask solver* using this format.

How I'm understanding it at the moment, while using `forall`

-form we can ask to find only ∀-solutions, i.e. the answer `sat`

means that solver managed to find interpretation (or invariant) satisfiying all assertions for **all** values, and `unsat`

means that there are no such functions. In other words, it tries to *prove*, putting the 'proof' (the invariant) into the model (obviously, when `sat`

).

On the contrary, when `query`

ing the solution in the `declare-rel`

format solver searches the solution for **some** variables, just like the constraints are under the ∃-quantifier. In other words, it gives the *counter-example*. It can only print the invariant in case of `unsat`

.

I have a couple of questions:

- Am I understanding it correct? I feel like I miss some key ideas. For example, a general idea of how to express
`(query ...)`

in terms of`(assert (forall ...))`

will be really helpfull (and will answer question 2 automaticly). - Is there a way to solve such ∃-constraints (outputting
`sat`

when counterexample was found) with pure SMT-LIB2 format? If yes then how?