I have a pretty simple problem, I'm mentioning the relevant part here:

```
;; All variables are declared to be of type Real
(assert (and (<= 1.0 var1-r) (< var1-r 4.0)))
;;following defines var1-r
(assert (= var1-r (+ a b)))
;;following defines var1-e
(assert (=> (and (<= 1.0 var1-r) (< var1-r 2.0)) (= var1-e 8388608.0)))
(assert (=> (and (<= 2.0 var1-r) (< var1-r 4.0)) (= var1-e 4194304.0)))
;;following defines var1
(assert (= var1 (/ (foo (* var1-r var1-e)) var1-e)))
;;Similarly for var2-r, var2-e, var2
(assert (and (<= 1.0 var2-r) (< var2-r 4.0)))
(assert (= var2-r (+ b a)))
(assert (=> (and (<= 1.0 var2-r) (< var2-r 2.0)) (= var2-e 8388608.0)))
(assert (=> (and (<= 2.0 var2-r) (< var2-r 4.0)) (= var2-e 4194304.0)))
(assert (= var2 (/ (foo (* var2-r var2-e)) var2-e)))
```

Here, `foo()`

is a simple interpreted function, eg., `foo (x) = (to_real (to_int x))`

Note that `var1`

and `var2`

are equal. Reason: `var1-r`

and `var2-r`

are equal (commutativity of Reals) and consequently `var2-e`

and `var1-e`

are equal, leading to `var1`

and `var2`

being equal. However, I am not able to prove unsatisfiability of `(not (= var1 var2))`

using z3. In fact, the same is true if `var2-r`

is defined as `(+ a b)`

. [Note that `var1`

and `var2`

being equal is actually also independent of the definition of `foo()`

].