No, this is not a bug. The tactic `ctx-solver-simplify`

is very expensive and inherently asymmetric. That is, the order the sub-formulas are visited affect the final result. This tactic is implemented in the file `src/smt/tactic/ctx_solver_simplify_tactic.cpp`

. The code is quite readable. Note that, it uses a "SMT" solver (`m_solver`

), and makes several calls to `m_solver.check()`

while traversing the input formula. Each one of these calls can be quite expensive. For particular problem domains, we can implement a version of this tactic that is even more expensive, and avoids the asymmetry described in your question.

**EDIT:**

You may also consider the tactic `ctx-simplify`

, it is cheaper than `ctx-solver-simplify`

, but it is symmetric. The tactic `ctx-simplify`

will essentially applies rules such as:

```
A \/ F[A] ==> A \/ F[false]
x != c \/ F[x] ==> F[c]
```

Where `F[A]`

is a formula that may contain `A`

. It is cheaper than `ctx-solver-simplify`

because it does not invoke a SMT solver when it is traversing the formula. Here is an example using this tactic (also available online):

```
a, b = Bools('a b')
p = Not(a)
q = Or(a, b)
c = Bool('c')
t = Then('simplify', 'propagate-values', 'ctx-simplify')
for e in Or(c, And(p, q)), Or(c, And(q, p)):
print e, '->', t(e)
```

Regarding humand-readability, this was never a goal when implementing any tactic. Please, tell us if the tactic above is not good enough for your purposes.