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I have a tool which is implemented in Java. We have interfaced Z3 Sat Solver C-API using Java JNI. I am using Z3 version 4.1

Given this situation I do the following experiments -

Experiment 1 -

  1. I assert some Constraints in the Solver.
  2. I check the result if it is sat or unsat.

Experiment 2 -

  1. I assert a subset of same Constraints in the Solver.
  2. I push the context of the solver using Z3_solver_push() API.
  3. I assert remaining constraints.
  4. I check the result if it is sat or unsat.

The reason I am doing experiment 2 is the need to backtrack.

Now in experiment 1, I get the amount of time required for the query always less than 5 seconds consistently. I have checked so far around 20-30 times. Sometimes it is even less than 2 seconds.

Now with the experiment 2, noting the fact the constraints are exactly the same, I get the query time sometimes 5 seconds, sometimes 10 seconds, sometimes 50 seconds. I also saw the query being "Timeout" with a timeout of 60 seconds.

In order to remove some doubts, I executed the same experiments from the command line. With experiment 1, I find that the query time is always between 2.3 - 2.7 seconds. However with experiment 2, (I put a push statement manually), the time became variable as mentioned. It varied between 10-60 seconds.

I want to know if pushing the context will cause such variation in query? Ideally it should not. But is there a chance?

How can we avoid this randomness and get a stable behaviour similar to without push statement?


I have added the example constraints, which I would like to find out which tactic to use. Please note that, it cannot reproduce the problem mentioned in the experiment. However, we use multiple such constraints such as given below, which can reproduce the problem -

(set-option :produce-models true) ; enable model generation
(set-option :print-success false)
(declare-const goal1 Int)
(declare-const goal2 Int)
(declare-const goal3 Int)
(declare-const kmax Int)
(declare-const ordA0_A0 Bool)
(declare-const ordA0_B0 Bool)
(declare-const ordB0_B0 Bool)
(declare-const ordB0_A0 Bool)
(declare-const stA0 Int)
(declare-const stB0 Int)
(declare-const stPA_0 Int)
(declare-const enPA_0 Int)
(declare-const stPB_0 Int)
(declare-const enPB_0 Int)
(declare-const kstA0 Int)
(declare-const kyA_0 Int)
(declare-const kstB0 Int)
(declare-const kyB_0 Int)
(declare-const resA_0 Int)
(declare-const resB_0 Int)

(assert (if (>= stPA_0 enPA_0) (= ordA0_A0 true) (= ordA0_A0 false)))
(assert (if (>= stPB_0 enPB_0) (= ordB0_B0 true) (= ordB0_B0 false)))
(assert (if (>= stPA_0 enPB_0) (= ordB0_A0 true) (= ordB0_A0 false)))
(assert (if (>= stPB_0 enPA_0) (= ordA0_B0 true) (= ordA0_B0 false)))

(assert (and (>= stA0 0) (<= stA0 goal2)))
(assert (and (>= stB0 0) (<= stB0 goal2)))
(assert (or (= stA0 0) (= stB0 0)))
(assert (>= stB0 (+ stA0 1)))
(assert (=> (and (= resA_0 resB_0) (= ordA0_A0 false) (= ordB0_B0 false)) (or (= ordA0_B0 true) (= ordB0_A0 true))))
(assert (=> (and (= resA_0 resB_0) (or (= ordA0_A0 true) (= ordB0_B0 true))) (and (= ordA0_B0 true) (= ordB0_A0 true))))

(assert (and (>= resA_0 0) (< resA_0 goal3)))
(assert (and (>= resB_0 0) (< resB_0 goal3)))

(assert (=> (= resA_0 resB_0) (or (= ordA0_A0 false) (= ordB0_B0 false))))

(assert (= stPA_0 (- stA0 (* goal1 kstA0))))
(assert (= enPA_0 (- (+ stA0 1) (* goal1 kyA_0))))
(assert (= stPB_0 (- stB0 (* goal1 kstB0))))
(assert (= enPB_0 (- (+ stB0 2) (* goal1 kyB_0))))
(assert (= kstA0 (div stA0 goal1)))
(assert (= kyA_0 (div (+ stA0 1) goal1)))
(assert (= kstB0 (div stB0 goal1)))
(assert (= kyB_0 (div (+ stB0 2) goal1)))
(assert (= goal2 (+ stB0 1)))
(assert (>= goal1 1))
(assert (<= goal2 6))
(assert (= kmax (div 6 goal1)))
(assert (<= goal2 6))
(assert (<= goal3 5))
(assert (= goal1 3))

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1 Answer 1

up vote 3 down vote accepted

Z3 is a collection of solvers. The default solver object is a portfolio of solvers. Not every solver in the portfolio is incremental. As soon as, we use Z3_solver_push(), it will use a general purpose incremental solver. This general purpose solver may be much less efficient than the non-incremental ones. You can force Z3 to use a non-incremental solver even when Z3_solver_push() is used. However, Z3 will start from scratch for every check, and will not reuse any work from previous check queries.

The main API for creating a non-incremental solver is Z3_mk_solver_from_tactic.

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but which tactic should be used in such case? I tried using simplify tactic, and it returns UNKNOWN for that query. –  Raj May 1 '13 at 6:20
simplify is just a preprocessor, it can only decide very simple formulas. The idea is to combine tactics together using combinators. The ideal combination depends on the problem. You can find more information here: rise4fun.com/Z3Py/tutorial/strategies –  Leonardo de Moura May 1 '13 at 14:31
how to find out which combination of tactics we have to use? is it possible to determine which tactic the solver is using when querying a solver which does not have Z3_solver_push()? –  Raj May 1 '13 at 18:16

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