/****************************************************************************** * Top contributors (to current version): * Mudathir Mohamed, Daniel Larraz, Mathias Preiner * * This file is part of the cvc5 project. * * Copyright (c) 2009-2025 by the authors listed in the file AUTHORS * in the top-level source directory and their institutional affiliations. * All rights reserved. See the file COPYING in the top-level source * directory for licensing information. * **************************************************************************** * * A simple demonstration of the Sygus API. * * A simple demonstration of how to use the Sygus API to synthesize max and min * functions. This is a direct translation of sygus-fun.cpp. */ import static io.github.cvc5.Kind.*; import io.github.cvc5.*; public class SygusFun { public static void main(String args[]) throws CVC5ApiException { TermManager tm = new TermManager(); Solver slv = new Solver(tm); { // required options slv.setOption("sygus", "true"); slv.setOption("incremental", "false"); // set the logic slv.setLogic("LIA"); Sort integer = tm.getIntegerSort(); Sort bool = tm.getBooleanSort(); // declare input variables for the functions-to-synthesize Term x = tm.mkVar(integer, "x"); Term y = tm.mkVar(integer, "y"); // declare the grammar non-terminals Term start = tm.mkVar(integer, "Start"); Term start_bool = tm.mkVar(bool, "StartBool"); // define the rules Term zero = tm.mkInteger(0); Term one = tm.mkInteger(1); Term plus = tm.mkTerm(ADD, start, start); Term minus = tm.mkTerm(SUB, start, start); Term ite = tm.mkTerm(ITE, start_bool, start, start); Term And = tm.mkTerm(AND, start_bool, start_bool); Term Not = tm.mkTerm(NOT, start_bool); Term leq = tm.mkTerm(LEQ, start, start); // create the grammar object Grammar g = slv.mkGrammar(new Term[] {x, y}, new Term[] {start, start_bool}); // bind each non-terminal to its rules g.addRules(start, new Term[] {zero, one, x, y, plus, minus, ite}); g.addRules(start_bool, new Term[] {And, Not, leq}); // declare the functions-to-synthesize. Optionally, provide the grammar // constraints Term max = slv.synthFun("max", new Term[] {x, y}, integer, g); Term min = slv.synthFun("min", new Term[] {x, y}, integer); // declare universal variables. Term varX = slv.declareSygusVar("x", integer); Term varY = slv.declareSygusVar("y", integer); Term max_x_y = tm.mkTerm(APPLY_UF, max, varX, varY); Term min_x_y = tm.mkTerm(APPLY_UF, min, varX, varY); // add semantic constraints // (constraint (>= (max x y) x)) slv.addSygusConstraint(tm.mkTerm(GEQ, max_x_y, varX)); // (constraint (>= (max x y) y)) slv.addSygusConstraint(tm.mkTerm(GEQ, max_x_y, varY)); // (constraint (or (= x (max x y)) // (= y (max x y)))) slv.addSygusConstraint( tm.mkTerm(OR, tm.mkTerm(EQUAL, max_x_y, varX), tm.mkTerm(EQUAL, max_x_y, varY))); // (constraint (= (+ (max x y) (min x y)) // (+ x y))) slv.addSygusConstraint( tm.mkTerm(EQUAL, tm.mkTerm(ADD, max_x_y, min_x_y), tm.mkTerm(ADD, varX, varY))); // print solutions if available if (slv.checkSynth().hasSolution()) { // Output should be equivalent to: // ( // (define-fun max ((x Int) (y Int)) Int (ite (<= x y) y x)) // (define-fun min ((x Int) (y Int)) Int (ite (<= x y) x y)) // ) Term[] terms = new Term[] {max, min}; Utils.printSynthSolutions(terms, slv.getSynthSolutions(terms)); } } Context.deletePointers(); } }