forked from openkylin/z3
1325 lines
40 KiB
C++
1325 lines
40 KiB
C++
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/*++
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Copyright (c) 2015 Microsoft Corporation
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--*/
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#include<vector>
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#include"z3++.h"
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using namespace z3;
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/**
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Demonstration of how Z3 can be used to prove validity of
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De Morgan's Duality Law: {e not(x and y) <-> (not x) or ( not y) }
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*/
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void demorgan() {
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std::cout << "de-Morgan example\n";
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context c;
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expr x = c.bool_const("x");
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expr y = c.bool_const("y");
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expr conjecture = (!(x && y)) == (!x || !y);
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solver s(c);
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// adding the negation of the conjecture as a constraint.
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s.add(!conjecture);
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std::cout << s << "\n";
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std::cout << s.to_smt2() << "\n";
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switch (s.check()) {
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case unsat: std::cout << "de-Morgan is valid\n"; break;
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case sat: std::cout << "de-Morgan is not valid\n"; break;
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case unknown: std::cout << "unknown\n"; break;
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}
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}
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/**
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\brief Find a model for <tt>x >= 1 and y < x + 3</tt>.
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*/
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void find_model_example1() {
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std::cout << "find_model_example1\n";
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context c;
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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solver s(c);
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s.add(x >= 1);
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s.add(y < x + 3);
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std::cout << s.check() << "\n";
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model m = s.get_model();
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std::cout << m << "\n";
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// traversing the model
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for (unsigned i = 0; i < m.size(); i++) {
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func_decl v = m[i];
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// this problem contains only constants
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assert(v.arity() == 0);
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std::cout << v.name() << " = " << m.get_const_interp(v) << "\n";
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}
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// we can evaluate expressions in the model.
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std::cout << "x + y + 1 = " << m.eval(x + y + 1) << "\n";
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}
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/**
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\brief Prove <tt>x = y implies g(x) = g(y)</tt>, and
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disprove <tt>x = y implies g(g(x)) = g(y)</tt>.
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This function demonstrates how to create uninterpreted types and
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functions.
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*/
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void prove_example1() {
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std::cout << "prove_example1\n";
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context c;
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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sort I = c.int_sort();
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func_decl g = function("g", I, I);
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solver s(c);
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expr conjecture1 = implies(x == y, g(x) == g(y));
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std::cout << "conjecture 1\n" << conjecture1 << "\n";
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s.add(!conjecture1);
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if (s.check() == unsat)
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std::cout << "proved" << "\n";
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else
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std::cout << "failed to prove" << "\n";
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s.reset(); // remove all assertions from solver s
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expr conjecture2 = implies(x == y, g(g(x)) == g(y));
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std::cout << "conjecture 2\n" << conjecture2 << "\n";
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s.add(!conjecture2);
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if (s.check() == unsat) {
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std::cout << "proved" << "\n";
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}
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else {
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std::cout << "failed to prove" << "\n";
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model m = s.get_model();
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std::cout << "counterexample:\n" << m << "\n";
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std::cout << "g(g(x)) = " << m.eval(g(g(x))) << "\n";
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std::cout << "g(y) = " << m.eval(g(y)) << "\n";
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}
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}
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/**
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\brief Prove <tt>not(g(g(x) - g(y)) = g(z)), x + z <= y <= x implies z < 0 </tt>.
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Then, show that <tt>z < -1</tt> is not implied.
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This example demonstrates how to combine uninterpreted functions and arithmetic.
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*/
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void prove_example2() {
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std::cout << "prove_example1\n";
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context c;
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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expr z = c.int_const("z");
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sort I = c.int_sort();
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func_decl g = function("g", I, I);
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expr conjecture1 = implies(g(g(x) - g(y)) != g(z) && x + z <= y && y <= x,
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z < 0);
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solver s(c);
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s.add(!conjecture1);
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std::cout << "conjecture 1:\n" << conjecture1 << "\n";
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if (s.check() == unsat)
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std::cout << "proved" << "\n";
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else
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std::cout << "failed to prove" << "\n";
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expr conjecture2 = implies(g(g(x) - g(y)) != g(z) && x + z <= y && y <= x,
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z < -1);
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s.reset();
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s.add(!conjecture2);
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std::cout << "conjecture 2:\n" << conjecture2 << "\n";
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if (s.check() == unsat) {
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std::cout << "proved" << "\n";
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}
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else {
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std::cout << "failed to prove" << "\n";
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std::cout << "counterexample:\n" << s.get_model() << "\n";
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}
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}
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/**
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\brief Nonlinear arithmetic example 1
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*/
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void nonlinear_example1() {
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std::cout << "nonlinear example 1\n";
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config cfg;
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cfg.set("auto_config", true);
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context c(cfg);
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expr x = c.real_const("x");
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expr y = c.real_const("y");
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expr z = c.real_const("z");
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solver s(c);
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s.add(x*x + y*y == 1); // x^2 + y^2 == 1
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s.add(x*x*x + z*z*z < c.real_val("1/2")); // x^3 + z^3 < 1/2
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s.add(z != 0);
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std::cout << s.check() << "\n";
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model m = s.get_model();
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std::cout << m << "\n";
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set_param("pp.decimal", true); // set decimal notation
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std::cout << "model in decimal notation\n";
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std::cout << m << "\n";
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set_param("pp.decimal-precision", 50); // increase number of decimal places to 50.
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std::cout << "model using 50 decimal places\n";
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std::cout << m << "\n";
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set_param("pp.decimal", false); // disable decimal notation
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}
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/**
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\brief Simple function that tries to prove the given conjecture using the following steps:
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1- create a solver
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2- assert the negation of the conjecture
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3- checks if the result is unsat.
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*/
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void prove(expr conjecture) {
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context & c = conjecture.ctx();
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solver s(c);
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s.add(!conjecture);
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std::cout << "conjecture:\n" << conjecture << "\n";
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if (s.check() == unsat) {
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std::cout << "proved" << "\n";
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}
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else {
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std::cout << "failed to prove" << "\n";
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std::cout << "counterexample:\n" << s.get_model() << "\n";
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}
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}
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/**
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\brief Simple bit-vector example. This example disproves that x - 10 <= 0 IFF x <= 10 for (32-bit) machine integers
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*/
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void bitvector_example1() {
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std::cout << "bitvector example 1\n";
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context c;
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expr x = c.bv_const("x", 32);
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// using signed <=
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prove((x - 10 <= 0) == (x <= 10));
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// using unsigned <=
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prove(ule(x - 10, 0) == ule(x, 10));
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expr y = c.bv_const("y", 32);
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prove(implies(concat(x, y) == concat(y, x), x == y));
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}
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/**
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\brief Find x and y such that: x ^ y - 103 == x * y
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*/
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void bitvector_example2() {
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std::cout << "bitvector example 2\n";
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context c;
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expr x = c.bv_const("x", 32);
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expr y = c.bv_const("y", 32);
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solver s(c);
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// In C++, the operator == has higher precedence than ^.
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s.add((x ^ y) - 103 == x * y);
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std::cout << s << "\n";
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std::cout << s.check() << "\n";
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std::cout << s.get_model() << "\n";
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}
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/**
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\brief Mixing C and C++ APIs.
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*/
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void capi_example() {
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std::cout << "capi example\n";
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context c;
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expr x = c.bv_const("x", 32);
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expr y = c.bv_const("y", 32);
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// Invoking a C API function, and wrapping the result using an expr object.
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expr r = to_expr(c, Z3_mk_bvsrem(c, x, y));
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std::cout << "r: " << r << "\n";
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}
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/**
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\brief Demonstrate how to evaluate expressions in a model.
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*/
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void eval_example1() {
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std::cout << "eval example 1\n";
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context c;
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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solver s(c);
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/* assert x < y */
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s.add(x < y);
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/* assert x > 2 */
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s.add(x > 2);
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std::cout << s.check() << "\n";
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model m = s.get_model();
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std::cout << "Model:\n" << m << "\n";
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std::cout << "x+y = " << m.eval(x+y) << "\n";
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}
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/**
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\brief Several contexts can be used simultaneously.
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*/
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void two_contexts_example1() {
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std::cout << "two contexts example 1\n";
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context c1, c2;
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expr x = c1.int_const("x");
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expr n = x + 1;
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// We cannot mix expressions from different contexts, but we can copy
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// an expression from one context to another.
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// The following statement copies the expression n from c1 to c2.
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expr n1 = to_expr(c2, Z3_translate(c1, n, c2));
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std::cout << n1 << "\n";
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}
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/**
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\brief Demonstrates how to catch API usage errors.
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*/
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void error_example() {
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std::cout << "error example\n";
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context c;
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expr x = c.bool_const("x");
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// Error using the C API can be detected using Z3_get_error_code.
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// The next call fails because x is a constant.
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//Z3_ast arg = Z3_get_app_arg(c, x, 0);
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if (Z3_get_error_code(c) != Z3_OK) {
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std::cout << "last call failed.\n";
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}
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// The C++ layer converts API usage errors into exceptions.
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try {
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// The next call fails because x is a Boolean.
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expr n = x + 1;
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}
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catch (exception ex) {
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std::cout << "failed: " << ex << "\n";
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}
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// The functions to_expr, to_sort and to_func_decl also convert C API errors into exceptions.
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try {
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expr arg = to_expr(c, Z3_get_app_arg(c, x, 0));
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}
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catch (exception ex) {
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std::cout << "failed: " << ex << "\n";
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}
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}
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/**
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\brief Demonstrate different ways of creating rational numbers: decimal and fractional representations.
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*/
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void numeral_example() {
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std::cout << "numeral example\n";
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context c;
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expr n1 = c.real_val("1/2");
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expr n2 = c.real_val("0.5");
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expr n3 = c.real_val(1, 2);
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std::cout << n1 << " " << n2 << " " << n3 << "\n";
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prove(n1 == n2 && n1 == n3);
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n1 = c.real_val("-1/3");
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n2 = c.real_val("-0.3333333333333333333333333333333333");
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std::cout << n1 << " " << n2 << "\n";
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prove(n1 != n2);
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}
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/**
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\brief Test ite-term (if-then-else terms).
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*/
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void ite_example() {
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std::cout << "if-then-else example\n";
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context c;
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expr f = c.bool_val(false);
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expr one = c.int_val(1);
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expr zero = c.int_val(0);
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expr ite = to_expr(c, Z3_mk_ite(c, f, one, zero));
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std::cout << "term: " << ite << "\n";
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}
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void ite_example2() {
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std::cout << "if-then-else example2\n";
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context c;
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expr b = c.bool_const("b");
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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std::cout << (ite(b, x, y) > 0) << "\n";
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}
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/**
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\brief Small example using quantifiers.
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*/
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void quantifier_example() {
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std::cout << "quantifier example\n";
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context c;
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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sort I = c.int_sort();
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func_decl f = function("f", I, I, I);
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solver s(c);
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// making sure model based quantifier instantiation is enabled.
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params p(c);
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p.set("mbqi", true);
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s.set(p);
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s.add(forall(x, y, f(x, y) >= 0));
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expr a = c.int_const("a");
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s.add(f(a, a) < a);
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std::cout << s << "\n";
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std::cout << s.check() << "\n";
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std::cout << s.get_model() << "\n";
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s.add(a < 0);
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std::cout << s.check() << "\n";
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}
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/**
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\brief Unsat core example
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*/
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void unsat_core_example1() {
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std::cout << "unsat core example1\n";
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context c;
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// We use answer literals to track assertions.
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// An answer literal is essentially a fresh Boolean marker
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// that is used to track an assertion.
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// For example, if we want to track assertion F, we
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// create a fresh Boolean variable p and assert (p => F)
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// Then we provide p as an argument for the check method.
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expr p1 = c.bool_const("p1");
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expr p2 = c.bool_const("p2");
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expr p3 = c.bool_const("p3");
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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solver s(c);
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s.add(implies(p1, x > 10));
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s.add(implies(p1, y > x));
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s.add(implies(p2, y < 5));
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s.add(implies(p3, y > 0));
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expr assumptions[3] = { p1, p2, p3 };
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std::cout << s.check(3, assumptions) << "\n";
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expr_vector core = s.unsat_core();
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std::cout << core << "\n";
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std::cout << "size: " << core.size() << "\n";
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for (unsigned i = 0; i < core.size(); i++) {
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std::cout << core[i] << "\n";
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}
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// Trying again without p2
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expr assumptions2[2] = { p1, p3 };
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std::cout << s.check(2, assumptions2) << "\n";
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}
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/**
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\brief Unsat core example 2
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*/
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void unsat_core_example2() {
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std::cout << "unsat core example 2\n";
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context c;
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// The answer literal mechanism, described in the previous example,
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// tracks assertions. An assertion can be a complicated
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// formula containing containing the conjunction of many subformulas.
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expr p1 = c.bool_const("p1");
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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solver s(c);
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expr F = x > 10 && y > x && y < 5 && y > 0;
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s.add(implies(p1, F));
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expr assumptions[1] = { p1 };
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std::cout << s.check(1, assumptions) << "\n";
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expr_vector core = s.unsat_core();
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std::cout << core << "\n";
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std::cout << "size: " << core.size() << "\n";
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for (unsigned i = 0; i < core.size(); i++) {
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std::cout << core[i] << "\n";
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}
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// The core is not very informative, since p1 is tracking the formula F
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// that is a conjunction of subformulas.
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// Now, we use the following piece of code to break this conjunction
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// into individual subformulas. First, we flat the conjunctions by
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// using the method simplify.
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std::vector<expr> qs; // auxiliary vector used to store new answer literals.
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assert(F.is_app()); // I'm assuming F is an application.
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if (F.decl().decl_kind() == Z3_OP_AND) {
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// F is a conjunction
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std::cout << "F num. args (before simplify): " << F.num_args() << "\n";
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F = F.simplify();
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std::cout << "F num. args (after simplify): " << F.num_args() << "\n";
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for (unsigned i = 0; i < F.num_args(); i++) {
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std::cout << "Creating answer literal q" << i << " for " << F.arg(i) << "\n";
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std::stringstream qname; qname << "q" << i;
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expr qi = c.bool_const(qname.str().c_str()); // create a new answer literal
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s.add(implies(qi, F.arg(i)));
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qs.push_back(qi);
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}
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}
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// The solver s already contains p1 => F
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// To disable F, we add (not p1) as an additional assumption
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qs.push_back(!p1);
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std::cout << s.check(static_cast<unsigned>(qs.size()), &qs[0]) << "\n";
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expr_vector core2 = s.unsat_core();
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std::cout << core2 << "\n";
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std::cout << "size: " << core2.size() << "\n";
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for (unsigned i = 0; i < core2.size(); i++) {
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std::cout << core2[i] << "\n";
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}
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}
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/**
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\brief Unsat core example 3
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*/
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void unsat_core_example3() {
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// Extract unsat core using tracked assertions
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std::cout << "unsat core example 3\n";
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context c;
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expr x = c.int_const("x");
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expr y = c.int_const("y");
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solver s(c);
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// enabling unsat core tracking
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params p(c);
|
|
p.set("unsat_core", true);
|
|
s.set(p);
|
|
|
|
// The following assertion will not be tracked.
|
|
s.add(x > 0);
|
|
|
|
// The following assertion will be tracked using Boolean variable p1.
|
|
// The C++ wrapper will automatically create the Boolean variable.
|
|
s.add(y > 0, "p1");
|
|
|
|
// Asserting other tracked assertions.
|
|
s.add(x < 10, "p2");
|
|
s.add(y < 0, "p3");
|
|
|
|
std::cout << s.check() << "\n";
|
|
std::cout << s.unsat_core() << "\n";
|
|
}
|
|
|
|
void tactic_example1() {
|
|
/*
|
|
Z3 implements a methodology for orchestrating reasoning engines where "big" symbolic
|
|
reasoning steps are represented as functions known as tactics, and tactics are composed
|
|
using combinators known as tacticals. Tactics process sets of formulas called Goals.
|
|
|
|
When a tactic is applied to some goal G, four different outcomes are possible. The tactic succeeds
|
|
in showing G to be satisfiable (i.e., feasible); succeeds in showing G to be unsatisfiable (i.e., infeasible);
|
|
produces a sequence of subgoals; or fails. When reducing a goal G to a sequence of subgoals G1, ..., Gn,
|
|
we face the problem of model conversion. A model converter construct a model for G using a model for some subgoal Gi.
|
|
|
|
In this example, we create a goal g consisting of three formulas, and a tactic t composed of two built-in tactics:
|
|
simplify and solve-eqs. The tactic simplify apply transformations equivalent to the ones found in the command simplify.
|
|
The tactic solver-eqs eliminate variables using Gaussian elimination. Actually, solve-eqs is not restricted
|
|
only to linear arithmetic. It can also eliminate arbitrary variables.
|
|
Then, sequential composition combinator & applies simplify to the input goal and solve-eqs to each subgoal produced by simplify.
|
|
In this example, only one subgoal is produced.
|
|
*/
|
|
std::cout << "tactic example 1\n";
|
|
context c;
|
|
expr x = c.real_const("x");
|
|
expr y = c.real_const("y");
|
|
goal g(c);
|
|
g.add(x > 0);
|
|
g.add(y > 0);
|
|
g.add(x == y + 2);
|
|
std::cout << g << "\n";
|
|
tactic t1(c, "simplify");
|
|
tactic t2(c, "solve-eqs");
|
|
tactic t = t1 & t2;
|
|
apply_result r = t(g);
|
|
std::cout << r << "\n";
|
|
}
|
|
|
|
void tactic_example2() {
|
|
/*
|
|
In Z3, we say a clause is any constraint of the form (f_1 || ... || f_n).
|
|
The tactic split-clause will select a clause in the input goal, and split it n subgoals.
|
|
One for each subformula f_i.
|
|
*/
|
|
std::cout << "tactic example 2\n";
|
|
context c;
|
|
expr x = c.real_const("x");
|
|
expr y = c.real_const("y");
|
|
goal g(c);
|
|
g.add(x < 0 || x > 0);
|
|
g.add(x == y + 1);
|
|
g.add(y < 0);
|
|
tactic t(c, "split-clause");
|
|
apply_result r = t(g);
|
|
for (unsigned i = 0; i < r.size(); i++) {
|
|
std::cout << "subgoal " << i << "\n" << r[i] << "\n";
|
|
}
|
|
}
|
|
|
|
void tactic_example3() {
|
|
/*
|
|
- The choice combinator t | s first applies t to the given goal, if it fails then returns the result of s applied to the given goal.
|
|
- repeat(t) Keep applying the given tactic until no subgoal is modified by it.
|
|
- repeat(t, n) Keep applying the given tactic until no subgoal is modified by it, or the number of iterations is greater than n.
|
|
- try_for(t, ms) Apply tactic t to the input goal, if it does not return in ms milliseconds, it fails.
|
|
- with(t, params) Apply the given tactic using the given parameters.
|
|
*/
|
|
std::cout << "tactic example 3\n";
|
|
context c;
|
|
expr x = c.real_const("x");
|
|
expr y = c.real_const("y");
|
|
expr z = c.real_const("z");
|
|
goal g(c);
|
|
g.add(x == 0 || x == 1);
|
|
g.add(y == 0 || y == 1);
|
|
g.add(z == 0 || z == 1);
|
|
g.add(x + y + z > 2);
|
|
// split all clauses
|
|
tactic split_all = repeat(tactic(c, "split-clause") | tactic(c, "skip"));
|
|
std::cout << split_all(g) << "\n";
|
|
tactic split_at_most_2 = repeat(tactic(c, "split-clause") | tactic(c, "skip"), 1);
|
|
std::cout << split_at_most_2(g) << "\n";
|
|
// In the tactic split_solver, the tactic solve-eqs discharges all but one goal.
|
|
// Note that, this tactic generates one goal: the empty goal which is trivially satisfiable (i.e., feasible)
|
|
tactic split_solve = split_all & tactic(c, "solve-eqs");
|
|
std::cout << split_solve(g) << "\n";
|
|
}
|
|
|
|
void tactic_example4() {
|
|
/*
|
|
A tactic can be converted into a solver object using the method mk_solver().
|
|
If the tactic produces the empty goal, then the associated solver returns sat.
|
|
If the tactic produces a single goal containing False, then the solver returns unsat.
|
|
Otherwise, it returns unknown.
|
|
|
|
In this example, the tactic t implements a basic bit-vector solver using equation solving,
|
|
bit-blasting, and a propositional SAT solver.
|
|
We use the combinator `with` to configure our little solver.
|
|
We also include the tactic `aig` which tries to compress Boolean formulas using And-Inverted Graphs.
|
|
*/
|
|
std::cout << "tactic example 4\n";
|
|
context c;
|
|
params p(c);
|
|
p.set("mul2concat", true);
|
|
tactic t =
|
|
with(tactic(c, "simplify"), p) &
|
|
tactic(c, "solve-eqs") &
|
|
tactic(c, "bit-blast") &
|
|
tactic(c, "aig") &
|
|
tactic(c, "sat");
|
|
solver s = t.mk_solver();
|
|
expr x = c.bv_const("x", 16);
|
|
expr y = c.bv_const("y", 16);
|
|
s.add(x*32 + y == 13);
|
|
// In C++, the operator < has higher precedence than &.
|
|
s.add((x & y) < 10);
|
|
s.add(y > -100);
|
|
std::cout << s.check() << "\n";
|
|
model m = s.get_model();
|
|
std::cout << m << "\n";
|
|
std::cout << "x*32 + y = " << m.eval(x*32 + y) << "\n";
|
|
std::cout << "x & y = " << m.eval(x & y) << "\n";
|
|
}
|
|
|
|
void tactic_example5() {
|
|
/*
|
|
The tactic smt wraps the main solver in Z3 as a tactic.
|
|
*/
|
|
std::cout << "tactic example 5\n";
|
|
context c;
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
solver s = tactic(c, "smt").mk_solver();
|
|
s.add(x > y + 1);
|
|
std::cout << s.check() << "\n";
|
|
std::cout << s.get_model() << "\n";
|
|
}
|
|
|
|
void tactic_example6() {
|
|
/*
|
|
In this example, we show how to implement a solver for integer arithmetic using SAT.
|
|
The solver is complete only for problems where every variable has a lower and upper bound.
|
|
*/
|
|
std::cout << "tactic example 6\n";
|
|
context c;
|
|
params p(c);
|
|
p.set("arith_lhs", true);
|
|
p.set("som", true); // sum-of-monomials normal form
|
|
solver s =
|
|
(with(tactic(c, "simplify"), p) &
|
|
tactic(c, "normalize-bounds") &
|
|
tactic(c, "lia2pb") &
|
|
tactic(c, "pb2bv") &
|
|
tactic(c, "bit-blast") &
|
|
tactic(c, "sat")).mk_solver();
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
expr z = c.int_const("z");
|
|
s.add(x > 0 && x < 10);
|
|
s.add(y > 0 && y < 10);
|
|
s.add(z > 0 && z < 10);
|
|
s.add(3*y + 2*x == z);
|
|
std::cout << s.check() << "\n";
|
|
std::cout << s.get_model() << "\n";
|
|
s.reset();
|
|
s.add(3*y + 2*x == z);
|
|
std::cout << s.check() << "\n";
|
|
}
|
|
|
|
void tactic_example7() {
|
|
/*
|
|
Tactics can be combined with solvers.
|
|
For example, we can apply a tactic to a goal, produced a set of subgoals,
|
|
then select one of the subgoals and solve it using a solver.
|
|
This example demonstrates how to do that, and
|
|
how to use model converters to convert a model for a subgoal into a model for the original goal.
|
|
*/
|
|
std::cout << "tactic example 7\n";
|
|
context c;
|
|
tactic t =
|
|
tactic(c, "simplify") &
|
|
tactic(c, "normalize-bounds") &
|
|
tactic(c, "solve-eqs");
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
expr z = c.int_const("z");
|
|
goal g(c);
|
|
g.add(x > 10);
|
|
g.add(y == x + 3);
|
|
g.add(z > y);
|
|
apply_result r = t(g);
|
|
// r contains only one subgoal
|
|
std::cout << r << "\n";
|
|
solver s(c);
|
|
goal subgoal = r[0];
|
|
for (unsigned i = 0; i < subgoal.size(); i++) {
|
|
s.add(subgoal[i]);
|
|
}
|
|
std::cout << s.check() << "\n";
|
|
model m = s.get_model();
|
|
std::cout << "model for subgoal:\n" << m << "\n";
|
|
std::cout << "model for original goal:\n" << subgoal.convert_model(m) << "\n";
|
|
}
|
|
|
|
void tactic_example8() {
|
|
/*
|
|
Probes (aka formula measures) are evaluated over goals.
|
|
Boolean expressions over them can be built using relational operators and Boolean connectives.
|
|
The tactic fail_if(cond) fails if the given goal does not satisfy the condition cond.
|
|
Many numeric and Boolean measures are available in Z3.
|
|
|
|
In this example, we build a simple tactic using fail_if.
|
|
It also shows that a probe can be applied directly to a goal.
|
|
*/
|
|
std::cout << "tactic example 8\n";
|
|
context c;
|
|
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
expr z = c.int_const("z");
|
|
|
|
goal g(c);
|
|
g.add(x + y + z > 0);
|
|
|
|
probe p(c, "num-consts");
|
|
std::cout << "num-consts: " << p(g) << "\n";
|
|
|
|
tactic t = fail_if(p > 2);
|
|
try {
|
|
t(g);
|
|
}
|
|
catch (exception) {
|
|
std::cout << "tactic failed...\n";
|
|
}
|
|
std::cout << "trying again...\n";
|
|
g.reset();
|
|
g.add(x + y > 0);
|
|
std::cout << t(g) << "\n";
|
|
}
|
|
|
|
void tactic_example9() {
|
|
/*
|
|
The combinator (tactical) cond(p, t1, t2) is a shorthand for:
|
|
|
|
(fail_if(p) & t1) | t2
|
|
|
|
The combinator when(p, t) is a shorthand for:
|
|
|
|
cond(p, t, tactic(c, "skip"))
|
|
|
|
The tactic skip just returns the input goal.
|
|
This example demonstrates how to use the cond combinator.
|
|
*/
|
|
std::cout << "tactic example 9\n";
|
|
context c;
|
|
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
expr z = c.int_const("z");
|
|
|
|
goal g(c);
|
|
g.add(x*x - y*y >= 0);
|
|
|
|
probe p(c, "num-consts");
|
|
tactic t = cond(p > 2, tactic(c, "simplify"), tactic(c, "factor"));
|
|
std::cout << t(g) << "\n";
|
|
|
|
g.reset();
|
|
g.add(x + x + y + z >= 0);
|
|
g.add(x*x - y*y >= 0);
|
|
std::cout << t(g) << "\n";
|
|
}
|
|
|
|
void tactic_qe() {
|
|
std::cout << "tactic example using quantifier elimination\n";
|
|
context c;
|
|
|
|
// Create a solver using "qe" and "smt" tactics
|
|
solver s =
|
|
(tactic(c, "qe") &
|
|
tactic(c, "smt")).mk_solver();
|
|
|
|
expr a = c.int_const("a");
|
|
expr b = c.int_const("b");
|
|
expr x = c.int_const("x");
|
|
expr f = implies(x <= a, x < b);
|
|
|
|
expr qf = forall(x, f);
|
|
|
|
std::cout << qf << "\n";
|
|
|
|
s.add(qf);
|
|
std::cout << s.check() << "\n";
|
|
std::cout << s.get_model() << "\n";
|
|
}
|
|
|
|
void visit(std::vector<bool>& visited, expr const & e) {
|
|
if (visited.size() <= e.id()) {
|
|
visited.resize(e.id()+1, false);
|
|
}
|
|
if (visited[e.id()]) {
|
|
return;
|
|
}
|
|
visited[e.id()] = true;
|
|
|
|
if (e.is_app()) {
|
|
unsigned num = e.num_args();
|
|
for (unsigned i = 0; i < num; i++) {
|
|
visit(visited, e.arg(i));
|
|
}
|
|
// do something
|
|
// Example: print the visited expression
|
|
func_decl f = e.decl();
|
|
std::cout << "application of " << f.name() << ": " << e << "\n";
|
|
}
|
|
else if (e.is_quantifier()) {
|
|
visit(visited, e.body());
|
|
// do something
|
|
}
|
|
else {
|
|
assert(e.is_var());
|
|
// do something
|
|
}
|
|
}
|
|
|
|
void tst_visit() {
|
|
std::cout << "visit example\n";
|
|
context c;
|
|
|
|
// only one of the occurrences of x*x is visited
|
|
// because they are the same subterms
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
expr z = c.int_const("z");
|
|
expr f = x*x + x*x - y*y >= 0;
|
|
std::vector<bool> visited;
|
|
visit(visited, f);
|
|
}
|
|
|
|
void tst_numeral() {
|
|
std::cout << "numeral example\n";
|
|
context c;
|
|
expr x = c.real_val("1/3");
|
|
double d = 0;
|
|
if (!x.is_numeral(d)) {
|
|
std::cout << x << " is not recognized as a numeral\n";
|
|
return;
|
|
}
|
|
std::cout << x << " is " << d << "\n";
|
|
}
|
|
|
|
void incremental_example1() {
|
|
std::cout << "incremental example1\n";
|
|
context c;
|
|
expr x = c.int_const("x");
|
|
solver s(c);
|
|
s.add(x > 0);
|
|
std::cout << s.check() << "\n";
|
|
// We can add more formulas to the solver
|
|
s.add(x < 0);
|
|
// and, invoke s.check() again...
|
|
std::cout << s.check() << "\n";
|
|
}
|
|
|
|
void incremental_example2() {
|
|
// In this example, we show how push() and pop() can be used
|
|
// to remove formulas added to the solver.
|
|
std::cout << "incremental example2\n";
|
|
context c;
|
|
expr x = c.int_const("x");
|
|
solver s(c);
|
|
s.add(x > 0);
|
|
std::cout << s.check() << "\n";
|
|
// push() creates a backtracking point (aka a snapshot).
|
|
s.push();
|
|
// We can add more formulas to the solver
|
|
s.add(x < 0);
|
|
// and, invoke s.check() again...
|
|
std::cout << s.check() << "\n";
|
|
// pop() will remove all formulas added between this pop() and the matching push()
|
|
s.pop();
|
|
// The context is satisfiable again
|
|
std::cout << s.check() << "\n";
|
|
// and contains only x > 0
|
|
std::cout << s << "\n";
|
|
}
|
|
|
|
void incremental_example3() {
|
|
// In this example, we show how to use assumptions to "remove"
|
|
// formulas added to a solver. Actually, we disable them.
|
|
std::cout << "incremental example3\n";
|
|
context c;
|
|
expr x = c.int_const("x");
|
|
solver s(c);
|
|
s.add(x > 0);
|
|
std::cout << s.check() << "\n";
|
|
// Now, suppose we want to add x < 0 to the solver, but we also want
|
|
// to be able to disable it later.
|
|
// To do that, we create an auxiliary Boolean variable
|
|
expr b = c.bool_const("b");
|
|
// and, assert (b implies x < 0)
|
|
s.add(implies(b, x < 0));
|
|
// Now, we check whether s is satisfiable under the assumption "b" is true.
|
|
expr_vector a1(c);
|
|
a1.push_back(b);
|
|
std::cout << s.check(a1) << "\n";
|
|
// To "disable" (x > 0), we may just ask with the assumption "not b" or not provide any assumption.
|
|
std::cout << s.check() << "\n";
|
|
expr_vector a2(c);
|
|
a2.push_back(!b);
|
|
std::cout << s.check(a2) << "\n";
|
|
}
|
|
|
|
void enum_sort_example() {
|
|
std::cout << "enumeration sort example\n";
|
|
context ctx;
|
|
const char * enum_names[] = { "a", "b", "c" };
|
|
func_decl_vector enum_consts(ctx);
|
|
func_decl_vector enum_testers(ctx);
|
|
sort s = ctx.enumeration_sort("enumT", 3, enum_names, enum_consts, enum_testers);
|
|
// enum_consts[0] is a func_decl of arity 0.
|
|
// we convert it to an expression using the operator()
|
|
expr a = enum_consts[0]();
|
|
expr b = enum_consts[1]();
|
|
expr x = ctx.constant("x", s);
|
|
expr test = (x==a) && (x==b);
|
|
std::cout << "1: " << test << std::endl;
|
|
tactic qe(ctx, "ctx-solver-simplify");
|
|
goal g(ctx);
|
|
g.add(test);
|
|
expr res(ctx);
|
|
apply_result result_of_elimination = qe.apply(g);
|
|
goal result_goal = result_of_elimination[0];
|
|
std::cout << "2: " << result_goal.as_expr() << std::endl;
|
|
}
|
|
|
|
void tuple_example() {
|
|
std::cout << "tuple example\n";
|
|
context ctx;
|
|
const char * names[] = { "first", "second" };
|
|
sort sorts[2] = { ctx.int_sort(), ctx.bool_sort() };
|
|
func_decl_vector projs(ctx);
|
|
func_decl pair = ctx.tuple_sort("pair", 2, names, sorts, projs);
|
|
sorts[1] = pair.range();
|
|
func_decl pair2 = ctx.tuple_sort("pair2", 2, names, sorts, projs);
|
|
|
|
std::cout << pair2 << "\n";
|
|
}
|
|
|
|
void expr_vector_example() {
|
|
std::cout << "expr_vector example\n";
|
|
context c;
|
|
const unsigned N = 10;
|
|
|
|
expr_vector x(c);
|
|
|
|
for (unsigned i = 0; i < N; i++) {
|
|
std::stringstream x_name;
|
|
x_name << "x_" << i;
|
|
x.push_back(c.int_const(x_name.str().c_str()));
|
|
}
|
|
|
|
solver s(c);
|
|
for (unsigned i = 0; i < N; i++) {
|
|
s.add(x[i] >= 1);
|
|
}
|
|
|
|
std::cout << s << "\n" << "solving...\n" << s.check() << "\n";
|
|
model m = s.get_model();
|
|
std::cout << "solution\n" << m;
|
|
}
|
|
|
|
void exists_expr_vector_example() {
|
|
std::cout << "exists expr_vector example\n";
|
|
context c;
|
|
const unsigned N = 10;
|
|
|
|
expr_vector xs(c);
|
|
expr x(c);
|
|
expr b(c);
|
|
b = c.bool_val(true);
|
|
|
|
for (unsigned i = 0; i < N; i++) {
|
|
std::stringstream x_name;
|
|
x_name << "x_" << i;
|
|
x = c.int_const(x_name.str().c_str());
|
|
xs.push_back(x);
|
|
b = b && x >= 0;
|
|
}
|
|
|
|
expr ex(c);
|
|
ex = exists(xs, b);
|
|
std::cout << ex << std::endl;
|
|
}
|
|
|
|
void substitute_example() {
|
|
std::cout << "substitute example\n";
|
|
context c;
|
|
expr x(c);
|
|
x = c.int_const("x");
|
|
expr f(c);
|
|
f = (x == 2) || (x == 1);
|
|
std::cout << f << std::endl;
|
|
|
|
expr two(c), three(c);
|
|
two = c.int_val(2);
|
|
three = c.int_val(3);
|
|
Z3_ast from[] = { two };
|
|
Z3_ast to[] = { three };
|
|
expr new_f(c);
|
|
new_f = to_expr(c, Z3_substitute(c, f, 1, from, to));
|
|
|
|
std::cout << new_f << std::endl;
|
|
}
|
|
|
|
void opt_example() {
|
|
context c;
|
|
optimize opt(c);
|
|
params p(c);
|
|
p.set("priority",c.str_symbol("pareto"));
|
|
opt.set(p);
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
opt.add(10 >= x && x >= 0);
|
|
opt.add(10 >= y && y >= 0);
|
|
opt.add(x + y <= 11);
|
|
optimize::handle h1 = opt.maximize(x);
|
|
optimize::handle h2 = opt.maximize(y);
|
|
while (true) {
|
|
if (sat == opt.check()) {
|
|
std::cout << x << ": " << opt.lower(h1) << " " << y << ": " << opt.lower(h2) << "\n";
|
|
}
|
|
else {
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
void extract_example() {
|
|
std::cout << "extract example\n";
|
|
context c;
|
|
expr x(c);
|
|
x = c.constant("x", c.bv_sort(32));
|
|
expr y = x.extract(21, 10);
|
|
std::cout << y << " " << y.hi() << " " << y.lo() << "\n";
|
|
}
|
|
|
|
void sudoku_example() {
|
|
std::cout << "sudoku example\n";
|
|
|
|
context c;
|
|
|
|
// 9x9 matrix of integer variables
|
|
expr_vector x(c);
|
|
for (unsigned i = 0; i < 9; ++i)
|
|
for (unsigned j = 0; j < 9; ++j) {
|
|
std::stringstream x_name;
|
|
|
|
x_name << "x_" << i << '_' << j;
|
|
x.push_back(c.int_const(x_name.str().c_str()));
|
|
}
|
|
|
|
solver s(c);
|
|
|
|
// each cell contains a value in {1, ..., 9}
|
|
for (unsigned i = 0; i < 9; ++i)
|
|
for (unsigned j = 0; j < 9; ++j) {
|
|
s.add(x[i * 9 + j] >= 1 && x[i * 9 + j] <= 9);
|
|
}
|
|
|
|
// each row contains a digit at most once
|
|
for (unsigned i = 0; i < 9; ++i) {
|
|
expr_vector t(c);
|
|
for (unsigned j = 0; j < 9; ++j)
|
|
t.push_back(x[i * 9 + j]);
|
|
s.add(distinct(t));
|
|
}
|
|
|
|
// each column contains a digit at most once
|
|
for (unsigned j = 0; j < 9; ++j) {
|
|
expr_vector t(c);
|
|
for (unsigned i = 0; i < 9; ++i)
|
|
t.push_back(x[i * 9 + j]);
|
|
s.add(distinct(t));
|
|
}
|
|
|
|
// each 3x3 square contains a digit at most once
|
|
for (unsigned i0 = 0; i0 < 3; i0++) {
|
|
for (unsigned j0 = 0; j0 < 3; j0++) {
|
|
expr_vector t(c);
|
|
for (unsigned i = 0; i < 3; i++)
|
|
for (unsigned j = 0; j < 3; j++)
|
|
t.push_back(x[(i0 * 3 + i) * 9 + j0 * 3 + j]);
|
|
s.add(distinct(t));
|
|
}
|
|
}
|
|
|
|
// sudoku instance, we use '0' for empty cells
|
|
int instance[9][9] = {{0,0,0,0,9,4,0,3,0},
|
|
{0,0,0,5,1,0,0,0,7},
|
|
{0,8,9,0,0,0,0,4,0},
|
|
{0,0,0,0,0,0,2,0,8},
|
|
{0,6,0,2,0,1,0,5,0},
|
|
{1,0,2,0,0,0,0,0,0},
|
|
{0,7,0,0,0,0,5,2,0},
|
|
{9,0,0,0,6,5,0,0,0},
|
|
{0,4,0,9,7,0,0,0,0}};
|
|
|
|
for (unsigned i = 0; i < 9; i++)
|
|
for (unsigned j = 0; j < 9; j++)
|
|
if (instance[i][j] != 0)
|
|
s.add(x[i * 9 + j] == instance[i][j]);
|
|
|
|
std::cout << s.check() << std::endl;
|
|
std::cout << s << std::endl;
|
|
|
|
model m = s.get_model();
|
|
for (unsigned i = 0; i < 9; ++i) {
|
|
for (unsigned j = 0; j < 9; ++j)
|
|
std::cout << m.eval(x[i * 9 + j]);
|
|
std::cout << '\n';
|
|
}
|
|
}
|
|
|
|
void param_descrs_example() {
|
|
std::cout << "parameter description example\n";
|
|
context c;
|
|
param_descrs p = param_descrs::simplify_param_descrs(c);
|
|
std::cout << p << "\n";
|
|
unsigned sz = p.size();
|
|
for (unsigned i = 0; i < sz; ++i) {
|
|
symbol nm = p.name(i);
|
|
char const* kind = "other";
|
|
Z3_param_kind k = p.kind(nm);
|
|
if (k == Z3_PK_UINT) kind = "uint";
|
|
if (k == Z3_PK_BOOL) kind = "bool";
|
|
std::cout << nm << ": " << p.documentation(nm) << " kind: " << kind << "\n";
|
|
}
|
|
}
|
|
|
|
void consequence_example() {
|
|
std::cout << "consequence example\n";
|
|
context c;
|
|
expr A = c.bool_const("a");
|
|
expr B = c.bool_const("b");
|
|
expr C = c.bool_const("c");
|
|
solver s(c);
|
|
s.add(implies(A, B));
|
|
s.add(implies(B, C));
|
|
expr_vector assumptions(c), vars(c), consequences(c);
|
|
assumptions.push_back(!C);
|
|
vars.push_back(A);
|
|
vars.push_back(B);
|
|
vars.push_back(C);
|
|
std::cout << s.consequences(assumptions, vars, consequences) << "\n";
|
|
std::cout << consequences << "\n";
|
|
}
|
|
|
|
static void parse_example() {
|
|
std::cout << "parse example\n";
|
|
context c;
|
|
sort_vector sorts(c);
|
|
func_decl_vector decls(c);
|
|
sort B = c.bool_sort();
|
|
decls.push_back(c.function("a", 0, 0, B));
|
|
expr_vector a = c.parse_string("(assert a)", sorts, decls);
|
|
std::cout << a << "\n";
|
|
|
|
// expr b = c.parse_string("(benchmark tst :extrafuns ((x Int) (y Int)) :formula (> x y) :formula (> x 0))");
|
|
}
|
|
|
|
static void parse_string() {
|
|
std::cout << "parse string\n";
|
|
z3::context c;
|
|
z3::solver s(c);
|
|
s.from_string("(declare-const x Int)(assert (> x 10))");
|
|
std::cout << s.check() << "\n";
|
|
}
|
|
|
|
void mk_model_example() {
|
|
context c;
|
|
|
|
// construct empty model
|
|
model m(c);
|
|
|
|
// create constants "a", "b" and get their func_decl
|
|
expr a = c.int_const("a");
|
|
expr b = c.int_const("b");
|
|
func_decl a_decl = a.decl();
|
|
func_decl b_decl = b.decl();
|
|
|
|
// create numerals to be used in model
|
|
expr zero_numeral = c.int_val(0);
|
|
expr one_numeral = c.int_val(1);
|
|
|
|
// add assignment to model
|
|
m.add_const_interp(a_decl, zero_numeral);
|
|
m.add_const_interp(b_decl, one_numeral);
|
|
|
|
// evaluate a + b < 2 in the model
|
|
std::cout << m.eval(a + b < 2)<< std::endl;
|
|
}
|
|
|
|
void recfun_example() {
|
|
std::cout << "recfun example\n";
|
|
context c;
|
|
expr x = c.int_const("x");
|
|
expr y = c.int_const("y");
|
|
expr b = c.bool_const("b");
|
|
sort I = c.int_sort();
|
|
sort B = c.bool_sort();
|
|
func_decl f = recfun("f", I, B, I);
|
|
expr_vector args(c);
|
|
args.push_back(x); args.push_back(b);
|
|
c.recdef(f, args, ite(b, x, f(x + 1, !b)));
|
|
prove(f(x,c.bool_val(false)) > x);
|
|
}
|
|
|
|
static void string_values() {
|
|
context c;
|
|
expr s = c.string_val("abc\n\n\0\0", 7);
|
|
std::cout << s << "\n";
|
|
std::string s1 = s.get_string();
|
|
std::cout << s1 << "\n";
|
|
}
|
|
|
|
expr MakeStringConstant(context* context, std::string value) {
|
|
return context->string_val(value.c_str());
|
|
}
|
|
|
|
expr MakeStringFunction(context* c, std::string s) {
|
|
sort sort = c->string_sort();
|
|
symbol name = c->str_symbol(s.c_str());
|
|
return c->constant(name, sort);
|
|
}
|
|
|
|
static void string_issue_2298() {
|
|
context c;
|
|
solver s(c);
|
|
s.push();
|
|
expr func1 = MakeStringFunction(&c, "func1");
|
|
expr func2 = MakeStringFunction(&c, "func2");
|
|
|
|
expr abc = MakeStringConstant(&c, "abc");
|
|
expr cde = MakeStringConstant(&c, "cde");
|
|
|
|
expr length = func1.length();
|
|
expr five = c.int_val(5);
|
|
|
|
s.add(func2 == abc || func1 == cde);
|
|
s.add(func2 == abc || func2 == cde);
|
|
s.add(length <= five);
|
|
|
|
s.check();
|
|
s.pop();
|
|
}
|
|
|
|
int main() {
|
|
|
|
try {
|
|
demorgan(); std::cout << "\n";
|
|
find_model_example1(); std::cout << "\n";
|
|
prove_example1(); std::cout << "\n";
|
|
prove_example2(); std::cout << "\n";
|
|
nonlinear_example1(); std::cout << "\n";
|
|
bitvector_example1(); std::cout << "\n";
|
|
bitvector_example2(); std::cout << "\n";
|
|
capi_example(); std::cout << "\n";
|
|
eval_example1(); std::cout << "\n";
|
|
two_contexts_example1(); std::cout << "\n";
|
|
error_example(); std::cout << "\n";
|
|
numeral_example(); std::cout << "\n";
|
|
ite_example(); std::cout << "\n";
|
|
ite_example2(); std::cout << "\n";
|
|
quantifier_example(); std::cout << "\n";
|
|
unsat_core_example1(); std::cout << "\n";
|
|
unsat_core_example2(); std::cout << "\n";
|
|
unsat_core_example3(); std::cout << "\n";
|
|
tactic_example1(); std::cout << "\n";
|
|
tactic_example2(); std::cout << "\n";
|
|
tactic_example3(); std::cout << "\n";
|
|
tactic_example4(); std::cout << "\n";
|
|
tactic_example5(); std::cout << "\n";
|
|
tactic_example6(); std::cout << "\n";
|
|
tactic_example7(); std::cout << "\n";
|
|
tactic_example8(); std::cout << "\n";
|
|
tactic_example9(); std::cout << "\n";
|
|
tactic_qe(); std::cout << "\n";
|
|
tst_visit(); std::cout << "\n";
|
|
tst_numeral(); std::cout << "\n";
|
|
incremental_example1(); std::cout << "\n";
|
|
incremental_example2(); std::cout << "\n";
|
|
incremental_example3(); std::cout << "\n";
|
|
enum_sort_example(); std::cout << "\n";
|
|
tuple_example(); std::cout << "\n";
|
|
expr_vector_example(); std::cout << "\n";
|
|
exists_expr_vector_example(); std::cout << "\n";
|
|
substitute_example(); std::cout << "\n";
|
|
opt_example(); std::cout << "\n";
|
|
extract_example(); std::cout << "\n";
|
|
param_descrs_example(); std::cout << "\n";
|
|
sudoku_example(); std::cout << "\n";
|
|
consequence_example(); std::cout << "\n";
|
|
parse_example(); std::cout << "\n";
|
|
parse_string(); std::cout << "\n";
|
|
mk_model_example(); std::cout << "\n";
|
|
recfun_example(); std::cout << "\n";
|
|
string_values(); std::cout << "\n";
|
|
string_issue_2298(); std::cout << "\n";
|
|
std::cout << "done\n";
|
|
}
|
|
catch (exception & ex) {
|
|
std::cout << "unexpected error: " << ex << "\n";
|
|
}
|
|
return 0;
|
|
}
|