I'm trying to encode an arithmetic for positive reals with a constant infinity in Z3. I successfully obtained the result in SMT2 with the following pair encoding
(declare-datatypes (T1 T2) ((Pair (mk-pair (first T1) (second T2))))) (declare-const infty (Pair Bool Real)) (assert (= infty (mk-pair true 0.))) (define-fun inf-sum ((p1 (Pair Bool Real)) (p2 (Pair Bool Real))) (Pair Bool Real) ( ite (first p1) p1 (ite (first p2) p2 (mk-pair false (+ (second p1) (second p2))) ) ) )
where a pair (true, _) encodes infinity while (false, 5.0) encodes the real 5. This works and I can solve constraints over it very fast.
I tried a similar approach with Z3py using z3 axioms over the following datatype:
MyR = Datatype('MyR') MyR.declare('inf'); MyR.declare('num',('r',RealSort())) MyR = MyR.create() inf = MyR.inf num = MyR.num r = MyR.r r1,r2,r3,r4,r5 = Consts('r1 r2 r3 r4 r5', MyR) n1,n2,n3 = Reals('n1 n2 n3') msum = Function('msum', MyR, MyR, MyR) s = Solver() s.add(ForAll(r1, msum(MyR.inf,r1)== MyR.inf)) s.add(ForAll(r1, msum(r1,MyR.inf)== MyR.inf)) s.add(ForAll([n1,n2,n3], Implies(n1+n2==n3, msum(MyR.num(n1),MyR.num(n2))== MyR.num(n3)))) s.add(msum(r2,r4)==MyR.num(Q(1,2))) print s.sexpr() print s.check()
I can't get it to work (it times out). I guess the problem is in trying to prove the consistency axioms. However I couldn't find another way to encode my arithmetic in Z3py.
Is anyone aware of what is the equivalent of the Z3 SMT2 approach of above in z3py?