/* Test BD_Shape::upper_bound_assign_if_exact(). Copyright (C) 2001-2010 Roberto Bagnara Copyright (C) 2010-2011 BUGSENG srl (http://bugseng.com) This file is part of the Parma Polyhedra Library (PPL). The PPL is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. The PPL is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111-1307, USA. For the most up-to-date information see the Parma Polyhedra Library site: http://www.cs.unipr.it/ppl/ . */ #include "ppl_test.hh" namespace { bool test01() { TBD_Shape bds_empty(0, EMPTY); TBD_Shape bds_universe(0, UNIVERSE); // Testing all combinations for 0-dim polyhedra. bool ok = true; TBD_Shape bds; // empty, empty bds = bds_empty; ok &= bds.upper_bound_assign_if_exact(bds_empty); ok &= (bds == bds_empty); print_constraints(bds, "*** empty union empty ***"); // empty, universe bds = bds_empty; ok &= bds.upper_bound_assign_if_exact(bds_universe); ok &= (bds == bds_universe); print_constraints(bds, "*** empty union universe ***"); // universe, empty bds = bds_universe; ok &= bds.upper_bound_assign_if_exact(bds_empty); ok &= (bds == bds_universe); print_constraints(bds, "*** universe union empty ***"); // universe, universe bds = bds_universe; ok &= bds.upper_bound_assign_if_exact(bds_universe); ok &= (bds == bds_universe); print_constraints(bds, "*** universe union universe ***"); return ok; } bool test02() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x >= -2); bds1.add_constraint(x <= -1); bds1.add_constraint(y >= 0); bds1.add_constraint(y <= 2); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x >= 1); bds2.add_constraint(x <= 2); bds2.add_constraint(y >= 0); bds2.add_constraint(y <= 2); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(bds1); bool ok = !bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test03() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x >= -2); bds1.add_constraint(x <= 0); bds1.add_constraint(y >= 0); bds1.add_constraint(y <= 2); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x >= 0); bds2.add_constraint(x <= 2); bds2.add_constraint(y >= 0); bds2.add_constraint(y <= 2); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(2, UNIVERSE); known_result.add_constraint(x >= -2); known_result.add_constraint(x <= 2); known_result.add_constraint(y >= 0); known_result.add_constraint(y <= 2); bool ok = bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test04() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x == 0); bds1.add_constraint(y == 0); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x >= 0); bds2.add_constraint(x <= 2); bds2.add_constraint(y >= -2); bds2.add_constraint(y <= 2); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(bds2); bool ok = bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test05() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x >= 0); bds1.add_constraint(y == 0); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x >= 0); bds2.add_constraint(y >= 2); bds2.add_constraint(y <= 4); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(bds1); bool ok = !bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test06() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x == y); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x == 0); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(bds1); bool ok = !bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test07() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x >= y); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x >= 0); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(bds1); bool ok = !bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test08() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x >= y); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x <= y); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(2, UNIVERSE); bool ok = bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test09() { Variable x(0); Variable y(1); Variable z(2); TBD_Shape bds(3, UNIVERSE); bds.add_constraint(x >= 0); bds.add_constraint(x <= 2); bds.add_constraint(y >= 0); bds.add_constraint(y <= 4); bds.add_constraint(z >= 0); bds.add_constraint(z <= 4); bds.add_constraint(x - y <= 2); bds.add_constraint(z - y <= 2); TBD_Shape bds1(bds); bds1.add_constraint(z <= 3); print_constraints(bds1, "*** bds1 ***"); TBD_Shape bds2(bds); bds2.add_constraint(x - y <= 1); bool ok = bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == bds); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test10() { Variable x(0); Variable y(1); TBD_Shape bds1(2, UNIVERSE); bds1.add_constraint(x >= 0); bds1.add_constraint(x <= 3); bds1.add_constraint(y >= 0); bds1.add_constraint(y <= 2); bds1.add_constraint(x - y <= 2); TBD_Shape bds2(2, UNIVERSE); bds2.add_constraint(x >= 3); bds2.add_constraint(x <= 6); bds2.add_constraint(y >= 0); bds2.add_constraint(y <= 2); print_constraints(bds1, "*** bds1 ***"); print_constraints(bds2, "*** bds2 ***"); TBD_Shape known_result(bds1); bool ok = !bds1.upper_bound_assign_if_exact(bds2); ok &= (bds1 == known_result); print_constraints(bds1, "*** bds1.upper_bound_assign_if_exact(bds2) ***"); return ok; } bool test11() { // const dimension_type dim = 500; const dimension_type dim = 50; Constraint_System cs; for (dimension_type i = 1; i < dim; ++i) { Variable x(i); cs.insert(x >= 0); cs.insert(x <= 4); } Variable x(0); TBD_Shape hypercube1(cs); hypercube1.add_constraint(x >= 0); hypercube1.add_constraint(x <= 4); TBD_Shape hypercube2(cs); hypercube2.add_constraint(x >= 2); hypercube2.add_constraint(x <= 6); TBD_Shape known_result(cs); known_result.add_constraint(x >= 0); known_result.add_constraint(x <= 6); bool ok = hypercube1.upper_bound_assign_if_exact(hypercube2); ok &= (hypercube1 == known_result); print_constraints(hypercube1, "*** hyp1 ***"); print_constraints(hypercube2, "*** hyp2 ***"); return ok; } } // namespace BEGIN_MAIN DO_TEST(test01); DO_TEST(test02); DO_TEST(test03); DO_TEST(test04); DO_TEST(test05); DO_TEST(test06); DO_TEST(test07); DO_TEST(test08); DO_TEST(test09); DO_TEST(test10); DO_TEST(test11); END_MAIN