//============================================================================= /** * @file Unbounded_Set_Test.cpp * * This test illustrates the use of ACE_Unbounded_Set. * No command line arguments are needed to run the test. * * @author Rudolf Weber * @author ace/tests integration */ //============================================================================= #include "test_config.h" #include #include #include struct MyNode { unsigned k; MyNode () : k (0) {} MyNode (int pk) : k (pk) {} MyNode (const MyNode& o) : k (o.k) {} bool operator== (const MyNode& o) const { return (k == o.k); } }; size_t count_const_set (const ACE_Unbounded_Set& cubs) { size_t number_of_elements = 0; for (ACE_Unbounded_Set::const_iterator ci (cubs); !ci.done(); ci++) number_of_elements++; return number_of_elements; } int run_main (int, ACE_TCHAR *[]) { int r; int retval = 0; unsigned k; MyNode node (1); ACE_START_TEST (ACE_TEXT ("Unbounded_Set_Test")); ACE_Unbounded_Set ubs; if (ubs.size () != 0) { ACE_ERROR ((LM_ERROR, "Error: ubs.size () != 0\n")); retval = -1; } if (!ubs.is_empty ()) { ACE_ERROR ((LM_ERROR, "Error: !ubs.is_empty ()\n")); retval = -1; } // Insert a value. Immediately remove it. r = ubs.insert (node); if (r != 0) { ACE_ERROR ((LM_ERROR, "Error: r != 0\n")); retval = -1; } if (ubs.size () != 1) { ACE_ERROR ((LM_ERROR, "Error: ubs.size () != 1\n")); retval = -1; } r = ubs.remove (node); if (r != 0) { ACE_ERROR ((LM_ERROR, "Error: r != 0\n")); retval = -1; } if (ubs.size () != 0) { ACE_ERROR ((LM_ERROR, "Error: ubs.size () != 0\n")); retval = -1; } // Insert several different values. for (node.k = 1; node.k <= 5; node.k++) { r = ubs.insert (node); if (r != 0) { ACE_ERROR ((LM_ERROR, "Error: r != 0\n")); retval = -1; } if (ubs.size () != node.k) { ACE_ERROR ((LM_ERROR, "Error: ubs.size () != node.k\n")); retval = -1; } } // Test assigment of sets. // To do that, we also test some of the iterator methods. typedef ACE_Unbounded_Set MySet; MySet ubs2 = ubs; // Test a typedef of a set. if (ubs2.size() != ubs.size()) { ACE_ERROR ((LM_ERROR, "Error: ubs2.size() != ubs.size()\n")); retval = -1; } { MySet::ITERATOR it1 (ubs); MySet::iterator it2 (ubs2); for (k = 1; k <= 5; k++) { if (it1.done ()) { ACE_ERROR ((LM_ERROR, "Error: it1.done ()\n")); retval = -1; } if (it2.done ()) { ACE_ERROR ((LM_ERROR, "Error: it2.done ()\n")); retval = -1; } MyNode n1 = *it1; MyNode n2 = *it2; if (!(n1 == n2)) { ACE_ERROR ((LM_ERROR, "Error: !(n1 == n2)\n")); retval = -1; } it1.advance (); it2.advance (); } if (!it1.done ()) { ACE_ERROR ((LM_ERROR, "Error: !it1.done ()\n")); retval = -1; } if (!it2.done ()) { ACE_ERROR ((LM_ERROR, "Error: !it2.done ()\n")); retval = -1; } // Verify that a set may be emptied while an iterator on the set is // in-scope but inactive: ubs.reset (); // Restore original set from ubs2 ubs = ubs2; } // Selective deletion of elements and element retrieval. { MySet::iterator it (ubs2); int deleted = 0; while (! it.done ()) { MyNode n = *it; it.advance (); /* Being friendly here: Move the iterator on so that element removal does not interfere with the current iterator position. The less friendly case, removal under the current iterator position, is below. */ if (n.k % 2 == 1) { r = ubs2.remove (n); deleted++; } } if (ubs2.size () + deleted != ubs.size()) { ACE_ERROR ((LM_ERROR, "Error: ubs2.size () + deleted != ubs.size()\n")); retval = -1; } MyNode node2 (2); if (ubs2.find (node2) != 0) { ACE_ERROR ((LM_ERROR, "Error: ubs2.find (node2) != 0\n")); retval = -1; } MyNode node3 (3); if (ubs2.find (node3) == 0) { ACE_ERROR ((LM_ERROR, "Error: ubs2.find (node3) == 0\n")); retval = -1; } ubs2.insert (node3); } size_t s = count_const_set (ubs); if (s != ubs.size ()) { ACE_ERROR ((LM_ERROR, "Error: s != ubs.size ()\n")); retval = -1; } ACE_Unbounded_Set ubs_insert; MyNode node4 (4); if (ubs_insert.insert (node4) != 0) { ACE_ERROR ((LM_ERROR, "Error: insert node4 failed\n")); retval = -1; } if (ubs_insert.insert (node4) != 1) { ACE_ERROR ((LM_ERROR, "Error: insert node4 didn't return 1\n")); retval = -1; } // Test iterating through a set and deleting elements. { ACE_Unbounded_Set ubs3; MyNode *n = 0; for (int i = 0; i < 10; ++i) { n = new MyNode (i); ubs3.insert (n); } MyNode **i_n = 0; ACE_Unbounded_Set_Iterator ubs3_iter (ubs3.begin ()); for (; ubs3_iter.next (i_n); ++ubs3_iter) delete *i_n; } ACE_END_TEST; return retval; }