public MkArraySort ( Microsoft.Z3.Sort domain, Microsoft.Z3.Sort range ) : |
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domain | Microsoft.Z3.Sort | |
range | Microsoft.Z3.Sort | |
return |
/// <summary> /// Prove <tt>store(a1, i1, v1) = store(a2, i2, v2) implies (i1 = i3 or i2 = i3 or select(a1, i3) = select(a2, i3))</tt>. /// </summary> /// <remarks>This example demonstrates how to use the array theory.</remarks> public static void ArrayExample2(Context ctx) { Console.WriteLine("ArrayExample2"); Sort int_type = ctx.IntSort; Sort array_type = ctx.MkArraySort(int_type, int_type); ArrayExpr a1 = (ArrayExpr)ctx.MkConst("a1", array_type); ArrayExpr a2 = ctx.MkArrayConst("a2", int_type, int_type); Expr i1 = ctx.MkConst("i1", int_type); Expr i2 = ctx.MkConst("i2", int_type); Expr i3 = ctx.MkConst("i3", int_type); Expr v1 = ctx.MkConst("v1", int_type); Expr v2 = ctx.MkConst("v2", int_type); Expr st1 = ctx.MkStore(a1, i1, v1); Expr st2 = ctx.MkStore(a2, i2, v2); Expr sel1 = ctx.MkSelect(a1, i3); Expr sel2 = ctx.MkSelect(a2, i3); /* create antecedent */ BoolExpr antecedent = ctx.MkEq(st1, st2); /* create consequent: i1 = i3 or i2 = i3 or select(a1, i3) = select(a2, i3) */ BoolExpr consequent = ctx.MkOr(new BoolExpr[] { ctx.MkEq(i1, i3), ctx.MkEq(i2, i3), ctx.MkEq(sel1, sel2) }); /* prove store(a1, i1, v1) = store(a2, i2, v2) implies (i1 = i3 or i2 = i3 or select(a1, i3) = select(a2, i3)) */ BoolExpr thm = ctx.MkImplies(antecedent, consequent); Console.WriteLine("prove: store(a1, i1, v1) = store(a2, i2, v2) implies (i1 = i3 or i2 = i3 or select(a1, i3) = select(a2, i3))"); Console.WriteLine("{0}", (thm)); Prove(ctx, thm); }
/// <summary> /// Show that <code>distinct(a_0, ... , a_n)</code> is /// unsatisfiable when <code>a_i</code>'s are arrays from boolean to /// boolean and n > 4. /// </summary> /// <remarks>This example also shows how to use the <code>distinct</code> construct.</remarks> public static void ArrayExample3(Context ctx) { Console.WriteLine("ArrayExample3"); for (int n = 2; n <= 5; n++) { Console.WriteLine("n = {0}", n); Sort bool_type = ctx.MkBoolSort(); Sort array_type = ctx.MkArraySort(bool_type, bool_type); Expr[] a = new Expr[n]; /* create arrays */ for (int i = 0; i < n; i++) { a[i] = ctx.MkConst(String.Format("array_{0}", i), array_type); } /* assert distinct(a[0], ..., a[n]) */ BoolExpr d = ctx.MkDistinct(a); Console.WriteLine("{0}", (d)); /* context is satisfiable if n < 5 */ Model model = Check(ctx, d, n < 5 ? Status.SATISFIABLE : Status.UNSATISFIABLE); if (n < 5) { for (int i = 0; i < n; i++) { Console.WriteLine("{0} = {1}", a[i], model.Evaluate(a[i])); } } } }
/// <summary> /// A simple array example. /// </summary> /// <param name="ctx"></param> static void ArrayExample1(Context ctx) { Console.WriteLine("ArrayExample1"); Goal g = ctx.MkGoal(true); ArraySort asort = ctx.MkArraySort(ctx.IntSort, ctx.MkBitVecSort(32)); ArrayExpr aex = (ArrayExpr)ctx.MkConst(ctx.MkSymbol("MyArray"), asort); Expr sel = ctx.MkSelect(aex, ctx.MkInt(0)); g.Assert(ctx.MkEq(sel, ctx.MkBV(42, 32))); Symbol xs = ctx.MkSymbol("x"); IntExpr xc = (IntExpr)ctx.MkConst(xs, ctx.IntSort); Symbol fname = ctx.MkSymbol("f"); Sort[] domain = { ctx.IntSort }; FuncDecl fd = ctx.MkFuncDecl(fname, domain, ctx.IntSort); Expr[] fargs = { ctx.MkConst(xs, ctx.IntSort) }; IntExpr fapp = (IntExpr)ctx.MkApp(fd, fargs); g.Assert(ctx.MkEq(ctx.MkAdd(xc, fapp), ctx.MkInt(123))); Solver s = ctx.MkSolver(); foreach (BoolExpr a in g.Formulas) s.Assert(a); Console.WriteLine("Solver: " + s); Status q = s.Check(); Console.WriteLine("Status: " + q); if (q != Status.SATISFIABLE) throw new TestFailedException(); Console.WriteLine("Model = " + s.Model); Console.WriteLine("Interpretation of MyArray:\n" + s.Model.FuncInterp(aex.FuncDecl)); Console.WriteLine("Interpretation of x:\n" + s.Model.ConstInterp(xc)); Console.WriteLine("Interpretation of f:\n" + s.Model.FuncInterp(fd)); Console.WriteLine("Interpretation of MyArray as Term:\n" + s.Model.FuncInterp(aex.FuncDecl)); }