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Is there a way to tell Z3 that a logical axiom might be applicable in a situation? For example, P(x) ==> \exists x P(x) is always valid. But if P is complicated enough, then Z3 can get confused and say unknown.

(declare-const size Int)
(declare-const h (Array Int Int))
(assert  (forall ((j Int) (k Int)) (=> (and (<= 0 k) (< k size) (<= 0 j) (< j size) (not (= k j))) (not (= (select h j) (select h k))))))
(assert (not (exists ((g (Array Int Int))) (forall ((j Int) (k Int)) (=> (and (<= 0 k) (< k size) (<= 0 j) (< j size) (not (= k j))) (not (= (select g j) (select g k))))))))
(check-sat)

The first assertion says that h is an array that maps distinct integers from 0..size-1 to distinct integers. And the second assertion says that such an array cannot exist. Can simple valid axioms such as P(x) ==> \exists x P(x) be provided in SMT files to help Z3? It might be that I have misunderstood what is happening in this example. But according to my limited understanding, Z3 might succeed in proving that the formula is unsat if it instantiates the axiom I mentioned.

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Do you (de)activate MBQI? What about AUTO_CONFIG? –  Malte Schwerhoff Apr 18 '13 at 9:51
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1 Answer

up vote 0 down vote accepted

This seems to be a triggering problem, i.e., Z3 does not instantiate the existentially quantified axiom (and probably also not the universally quantified one). Have a look at the following simplified example:

(set-option :AUTO_CONFIG false)
(set-option :SMT.MBQI false)

(declare-fun f (Int) Bool)

(assert (forall ((x Int))
  (=> (<= 0 x) (f x))
))

(assert (not (exists ((x Int))
  (=> (<= 0 x) (f x))
)))

; (assert (f -10))

(check-sat)

Z3 (version 4.3.2, 64 bit, build hashcode 96f4606a7f2d) reports unknown, but if you uncomment the last assertion, that it reports unsat. I thus assume that the pattern that Z3 infers for both axioms is :pattern ((f x)), which means, that f x must syntactically occur before the axioms can be instantiated.

You can read more about quantifier patterns in the z3 guide.

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Thanks! This clears things. I believe if I want to do reasoning with quantified formulas, never instantiating them, then I will have this trouble. –  Rahul Sharma Apr 23 '13 at 17:53
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