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Getting started

For your first steps with KSMT, try our code examples.

To check OS compatibility, see Supported solvers and theories.

Find basic instructions to get use of KSMT:

Installation

Install KSMT via Gradle.

  1. Enable Maven Central repository in your build configuration:
repositories {
    mavenCentral()
}
  1. Add KSMT core dependency:
dependencies {
    // core 
    implementation("io.ksmt:ksmt-core:0.5.4")    
}
  1. Add one or more SMT solver dependencies:
dependencies {
    // z3 
    implementation("io.ksmt:ksmt-z3:0.5.4")
    // bitwuzla
    implementation("io.ksmt:ksmt-bitwuzla:0.5.4")
}

SMT solver specific packages are provided with solver native binaries.

Usage

Create a KSMT context that manages expressions and solvers:

val ctx = KContext()

Working with SMT formulas

Once the context is initialized, you can create expressions.

In the example below, we create an expression

a && (b >= c + 3)

over Boolean variable a and integer variables b and c:

import io.ksmt.utils.getValue

with(ctx) {
    // create symbolic variables
    val a by boolSort
    val b by intSort
    val c by intSort

    // create an expression
    val constraint = a and (b ge c + 3.expr)
}

KSMT expressions are typed, and incorrect terms (e.g., and with integer arguments) result in a compile-time error.

Note: import getValue is required when using the by keyword. Alternatively, use mkConst(name, sort).

Working with SMT solvers

To check SMT formula satisfiability, we need to instantiate an SMT solver. In this example, we use constraint from the previous step as an SMT formula. We use Z3 as an SMT solver.

with(ctx) {
    KZ3Solver(this).use { solver -> // create a Z3 SMT solver instance
        // assert expression
        solver.assert(constraint)
        
        // check assertions satisfiability with timeout
        val satisfiability = solver.check(timeout = 1.seconds)
        println(satisfiability) // SAT
        
        // obtain model
        val model = solver.model()
        
        println("$a = ${model.eval(a)}") // a = true
        println("$b = ${model.eval(b)}") // b = 0
        println("$c = ${model.eval(c)}") // c = -3
    }
}

The formula in the example above is satisfiable, so we can get a model. The model contains concrete values of the symbolic variables a, b, and c, which evaluate the formula to true.

Note: the Kotlin .use { } construction allows releasing the solver-consumed resources.

Incremental solving: API

KSMT solver API provides two approaches to incremental formula solving: using push/pop operations and using assumptions.

Incremental solving with push/pop operations

Push and pop operations in the solver allow us to work with assertions as if we deal with a stack. The push operation puts the asserted expressions onto the stack, while the pop operation removes the pushed assertions.

with(ctx) {
    // create symbolic variables
    val cond1 by boolSort
    val cond2 by boolSort
    val a by bv32Sort
    val b by bv32Sort
    val c by bv32Sort
    val goal by bv32Sort

    KZ3Solver(this).use { solver ->
        // a == 0
        solver.assert(a eq mkBv(value = 0))
        // goal == 2
        solver.assert(goal eq mkBv(value = 2))

        // push assertions onto stack
        solver.push()

        // a == goal
        solver.assert(a eq goal)

        /**
         * Formula is unsatisfiable because we have
         * a == 0 && goal == 2 && a == goal
         */
        val check0 = solver.check(timeout = 1.seconds)
        println("check0 = $check0") // UNSAT

        // pop assertions from stack; a == goal is removed
        solver.pop()

        /**
         * Formula is satisfiable now because we have
         * a == 0 && goal == 2
         */
        val check1 = solver.check(timeout = 1.seconds)
        println("check1 = $check1") // SAT

        // b == if (cond1) a + 1 else a
        solver.assert(b eq mkIte(cond1, mkBvAddExpr(a, mkBv(value = 1)), a))

        // push assertions onto stack
        solver.push()

        // b == goal
        solver.assert(b eq goal)

        /**
         * Formula is unsatisfiable because we have
         * a == 0 && goal == 2 
         *      && b == if (cond1) a + 1 else a 
         *      && goal == b
         * where all possible values for b are only 0 and 1
         */
        val check2 = solver.check(timeout = 1.seconds)
        println("check2 = $check2") // UNSAT

        // pop assertions from stack. b == goal is removed
        solver.pop()

        /**
         * Formula is satisfiable now because we have
         * a == 0 && goal == 2 
         *      && b == if (cond1) a + 1 else a
         */
        val check3 = solver.check(timeout = 1.seconds)
        println("check3 = $check3") // SAT

        // c == if (cond2) b + 1 else b
        solver.assert(c eq mkIte(cond2, mkBvAddExpr(b, mkBv(value = 1)), b))

        // push assertions stack
        solver.push()

        // c == goal
        solver.assert(c eq goal)

        /**
         * Formula is satisfiable because we have
         * a == 0 && goal == 2 
         *      && b == if (cond1) a + 1 else a
         *      && c == if (cond2) b + 1 else b 
         *      && goal == c
         * where all possible values for b are 0 and 1
         * and for c we have 0, 1 and 2
         */
        val check4 = solver.check(timeout = 1.seconds)
        println("check4 = $check4") // SAT
    }
}

Incremental solving with assumptions

Assumption mechanism allows us to assert an expression for a single check without actually adding it to assertions. The following example shows how to implement the previous example using assumptions instead of push and pop operations.

with(ctx) {
    // create symbolic variables
    val cond1 by boolSort
    val cond2 by boolSort
    val a by bv32Sort
    val b by bv32Sort
    val c by bv32Sort
    val goal by bv32Sort

    KZ3Solver(this).use { solver ->
        // a == 0
        solver.assert(a eq mkBv(value = 0))
        // goal == 2
        solver.assert(goal eq mkBv(value = 2))

        /**
         * Formula is unsatisfiable because we have
         * a == 0 && goal == 2 && a == goal
         * Expression a == goal is assumed for current check
         */
        val check0 = solver.checkWithAssumptions(
            assumptions = listOf(a eq goal),
            timeout = 1.seconds
        )
        println("check0 = $check0") // UNSAT

        /**
         * Formula is satisfiable because we have
         * a == 0 && goal == 2
         */
        val check1 = solver.check(timeout = 1.seconds)
        println("check1 = $check1") // SAT

        // b == if (cond1) a + 1 else a
        solver.assert(b eq mkIte(cond1, mkBvAddExpr(a, mkBv(value = 1)), a))

        /**
         * Formula is unsatisfiable because we have
         * a == 0 && goal == 2
         *      && b == if (cond1) a + 1 else a
         *      && goal == b
         * where all possible values for b are only 0 and 1
         * Expression goal == b is assumed for current check
         */
        val check2 = solver.checkWithAssumptions(
            assumptions = listOf(b eq goal),
            timeout = 1.seconds
        )
        println("check2 = $check2") // UNSAT

        /**
         * Formula is satisfiable now because we have
         * a == 0 && goal == 2
         *      && b == if (cond1) a + 1 else a
         */
        val check3 = solver.check(timeout = 1.seconds)
        println("check3 = $check3") // SAT

        // c == if (cond2) b + 1 else b
        solver.assert(c eq mkIte(cond2, mkBvAddExpr(b, mkBv(value = 1)), b))

        /**
         * Formula is satisfiable because we have
         * a == 0 && goal == 2
         *      && b == if (cond1) a + 1 else a
         *      && c == if (cond2) b + 1 else b
         *      && goal == c
         * where all possible values for b are 0 and 1
         * and for c we have 0, 1 and 2
         * Expression goal == c is assumed for current check
         */
        val check4 = solver.checkWithAssumptions(
            assumptions = listOf(c eq goal),
            timeout = 1.seconds
        )
        println("check4 = $check4") // SAT
    }
}

Solver unsatisfiable cores

If the asserted SMT formula is unsatisfiable, we can extract the unsatisfiable core. The unsatisfiable core is a subset of inconsistent assertions and assumptions.

with(ctx) {
    // create symbolic variables
    val a by boolSort
    val b by boolSort
    val c by boolSort

    val e1 = (a and b) or c
    val e2 = !(a and b)
    val e3 = !c

    KZ3Solver(this).use { solver ->
        // simply assert e1
        solver.assert(e1)

        /**
         * Assert and track e2
         * e2 will appear in unsat core
         * */
        solver.assertAndTrack(e2)

        /**
         * Check satisfiability with e3 assumed.
         * Formula is unsatisfiable because e1 is inconsistent with e2 and e3
         * */
        val check = solver.checkWithAssumptions(assumptions = listOf(e3))
        println("check = $check")

        // retrieve unsat core
        val core = solver.unsatCore()
        println("unsat core = $core") // [(not (and b a)), (not c)]

        // simply asserted expression cannot be in unsat core
        println("e1 in core = ${e1 in core}") // false

        // an expression added with `assertAndTrack` appears in unsat core as is
        println("e2 in core = ${e2 in core}") // true

        // the assumed expression appears in unsat core as is
        println("e3 in core = ${e3 in core}") // true
    }
}