I'm trying to proof the following with Z3 SMT Solver: `((x*x) + x) = ((~x * ~x) + ~x)`

.
This is correct, because of overflow semantic in the c programming language.

Now I have written the following smt-lib code:

```
(declare-fun a () Int)
(define-fun myadd ((x Int) (y Int)) Int (mod (+ x y) 4294967296) )
(define-fun mynot ((x Int)) Int (- 4294967295 (mod x 4294967296)) )
(define-fun mymul ((x Int) (y Int)) Int (mod (* x y) 4294967296) )
(define-fun myfun1 ((x Int)) Int (myadd (mynot x) (mymul (mynot x) (mynot x))) )
(define-fun myfun2 ((x Int)) Int (myadd x (mymul x x)) )
(simplify (myfun1 0))
(simplify (myfun2 0))
(assert (= (myfun1 a) (myfun2 a)))
(check-sat)
(exit)
```

The output from z3 is:

```
0
0
unsat
```

Now my question: Why is the result "unsat"? The simplify command in my code shows that it is possible to get a valid allocation so that myfun1 and myfun2 have the same result.

Is something wrong with my code or is this a bug in z3?

Please can anybody help me. Thx

`(mod (+ a b))`

or`(mod (* a b))`

. – Leonardo de Moura Jan 29 '12 at 3:04