//Has to be first for StackAllocator swap overload to be taken //into account (at least using GCC 4.0.1) #include "stack_allocator.h" #include #include #if !defined (STLPORT) || defined (_STLP_USE_EXCEPTIONS) # include #endif #include "cppunit/cppunit_proxy.h" #if !defined (STLPORT) || defined(_STLP_USE_NAMESPACES) using namespace std; #endif // // TestCase class // class VectorTest : public CPPUNIT_NS::TestCase { CPPUNIT_TEST_SUITE(VectorTest); CPPUNIT_TEST(vec_test_1); CPPUNIT_TEST(vec_test_2); CPPUNIT_TEST(vec_test_3); CPPUNIT_TEST(vec_test_4); CPPUNIT_TEST(vec_test_5); CPPUNIT_TEST(vec_test_6); CPPUNIT_TEST(vec_test_7); CPPUNIT_TEST(capacity); CPPUNIT_TEST(at); CPPUNIT_TEST(pointer); CPPUNIT_TEST(auto_ref); CPPUNIT_TEST(allocator_with_state); CPPUNIT_TEST(iterators); #if defined (STLPORT) && defined (_STLP_NO_MEMBER_TEMPLATES) CPPUNIT_IGNORE; #endif CPPUNIT_TEST(optimizations_check); CPPUNIT_TEST(assign_check); CPPUNIT_STOP_IGNORE; CPPUNIT_TEST(ebo); CPPUNIT_TEST_SUITE_END(); protected: void vec_test_1(); void vec_test_2(); void vec_test_3(); void vec_test_4(); void vec_test_5(); void vec_test_6(); void vec_test_7(); void capacity(); void at(); void pointer(); void auto_ref(); void allocator_with_state(); void iterators(); void optimizations_check(); void assign_check(); void ebo(); }; CPPUNIT_TEST_SUITE_REGISTRATION(VectorTest); // // tests implementation // void VectorTest::vec_test_1() { vector v1; // Empty vector of integers. CPPUNIT_ASSERT( v1.empty() == true ); CPPUNIT_ASSERT( v1.size() == 0 ); // CPPUNIT_ASSERT( v1.max_size() == INT_MAX / sizeof(int) ); // cout << "max_size = " << v1.max_size() << endl; v1.push_back(42); // Add an integer to the vector. CPPUNIT_ASSERT( v1.size() == 1 ); CPPUNIT_ASSERT( v1[0] == 42 ); { vector > vect(10); vector >::iterator it(vect.begin()), end(vect.end()); for (; it != end; ++it) { CPPUNIT_ASSERT( (*it).empty() ); CPPUNIT_ASSERT( (*it).size() == 0 ); CPPUNIT_ASSERT( (*it).capacity() == 0 ); CPPUNIT_ASSERT( (*it).begin() == (*it).end() ); } } } void VectorTest::vec_test_2() { vector v1; // Empty vector of doubles. v1.push_back(32.1); v1.push_back(40.5); vector v2; // Another empty vector of doubles. v2.push_back(3.56); CPPUNIT_ASSERT( v1.size() == 2 ); CPPUNIT_ASSERT( v1[0] == 32.1 ); CPPUNIT_ASSERT( v1[1] == 40.5 ); CPPUNIT_ASSERT( v2.size() == 1 ); CPPUNIT_ASSERT( v2[0] == 3.56 ); size_t v1Cap = v1.capacity(); size_t v2Cap = v2.capacity(); v1.swap(v2); // Swap the vector's contents. CPPUNIT_ASSERT( v1.size() == 1 ); CPPUNIT_ASSERT( v1.capacity() == v2Cap ); CPPUNIT_ASSERT( v1[0] == 3.56 ); CPPUNIT_ASSERT( v2.size() == 2 ); CPPUNIT_ASSERT( v2.capacity() == v1Cap ); CPPUNIT_ASSERT( v2[0] == 32.1 ); CPPUNIT_ASSERT( v2[1] == 40.5 ); v2 = v1; // Assign one vector to another. CPPUNIT_ASSERT( v2.size() == 1 ); CPPUNIT_ASSERT( v2[0] == 3.56 ); } void VectorTest::vec_test_3() { typedef vector vec_type; vec_type v1; // Empty vector of characters. v1.push_back('h'); v1.push_back('i'); CPPUNIT_ASSERT( v1.size() == 2 ); CPPUNIT_ASSERT( v1[0] == 'h' ); CPPUNIT_ASSERT( v1[1] == 'i' ); vec_type v2(v1.begin(), v1.end()); v2[1] = 'o'; // Replace second character. CPPUNIT_ASSERT( v2.size() == 2 ); CPPUNIT_ASSERT( v2[0] == 'h' ); CPPUNIT_ASSERT( v2[1] == 'o' ); CPPUNIT_ASSERT( (v1 == v2) == false ); CPPUNIT_ASSERT( (v1 < v2) == true ); } void VectorTest::vec_test_4() { vector v(4); v[0] = 1; v[1] = 4; v[2] = 9; v[3] = 16; CPPUNIT_ASSERT( v.front() == 1 ); CPPUNIT_ASSERT( v.back() == 16 ); v.push_back(25); CPPUNIT_ASSERT( v.back() == 25 ); CPPUNIT_ASSERT( v.size() == 5 ); v.pop_back(); CPPUNIT_ASSERT( v.back() == 16 ); CPPUNIT_ASSERT( v.size() == 4 ); } void VectorTest::vec_test_5() { int array [] = { 1, 4, 9, 16 }; vector v(array, array + 4); CPPUNIT_ASSERT( v.size() == 4 ); CPPUNIT_ASSERT( v[0] == 1 ); CPPUNIT_ASSERT( v[1] == 4 ); CPPUNIT_ASSERT( v[2] == 9 ); CPPUNIT_ASSERT( v[3] == 16 ); } void VectorTest::vec_test_6() { int array [] = { 1, 4, 9, 16, 25, 36 }; vector v(array, array + 6); vector::iterator vit; CPPUNIT_ASSERT( v.size() == 6 ); CPPUNIT_ASSERT( v[0] == 1 ); CPPUNIT_ASSERT( v[1] == 4 ); CPPUNIT_ASSERT( v[2] == 9 ); CPPUNIT_ASSERT( v[3] == 16 ); CPPUNIT_ASSERT( v[4] == 25 ); CPPUNIT_ASSERT( v[5] == 36 ); vit = v.erase( v.begin() ); // Erase first element. CPPUNIT_ASSERT( *vit == 4 ); CPPUNIT_ASSERT( v.size() == 5 ); CPPUNIT_ASSERT( v[0] == 4 ); CPPUNIT_ASSERT( v[1] == 9 ); CPPUNIT_ASSERT( v[2] == 16 ); CPPUNIT_ASSERT( v[3] == 25 ); CPPUNIT_ASSERT( v[4] == 36 ); vit = v.erase(v.end() - 1); // Erase last element. CPPUNIT_ASSERT( vit == v.end() ); CPPUNIT_ASSERT( v.size() == 4 ); CPPUNIT_ASSERT( v[0] == 4 ); CPPUNIT_ASSERT( v[1] == 9 ); CPPUNIT_ASSERT( v[2] == 16 ); CPPUNIT_ASSERT( v[3] == 25 ); v.erase(v.begin() + 1, v.end() - 1); // Erase all but first and last. CPPUNIT_ASSERT( v.size() == 2 ); CPPUNIT_ASSERT( v[0] == 4 ); CPPUNIT_ASSERT( v[1] == 25 ); } void VectorTest::vec_test_7() { int array1 [] = { 1, 4, 25 }; int array2 [] = { 9, 16 }; vector v(array1, array1 + 3); vector::iterator vit; vit = v.insert(v.begin(), 0); // Insert before first element. CPPUNIT_ASSERT( *vit == 0 ); vit = v.insert(v.end(), 36); // Insert after last element. CPPUNIT_ASSERT( *vit == 36 ); CPPUNIT_ASSERT( v.size() == 5 ); CPPUNIT_ASSERT( v[0] == 0 ); CPPUNIT_ASSERT( v[1] == 1 ); CPPUNIT_ASSERT( v[2] == 4 ); CPPUNIT_ASSERT( v[3] == 25 ); CPPUNIT_ASSERT( v[4] == 36 ); // Insert contents of array2 before fourth element. v.insert(v.begin() + 3, array2, array2 + 2); CPPUNIT_ASSERT( v.size() == 7 ); CPPUNIT_ASSERT( v[0] == 0 ); CPPUNIT_ASSERT( v[1] == 1 ); CPPUNIT_ASSERT( v[2] == 4 ); CPPUNIT_ASSERT( v[3] == 9 ); CPPUNIT_ASSERT( v[4] == 16 ); CPPUNIT_ASSERT( v[5] == 25 ); CPPUNIT_ASSERT( v[6] == 36 ); v.clear(); CPPUNIT_ASSERT( v.empty() ); v.insert(v.begin(), 5, 10); CPPUNIT_ASSERT( v.size() == 5 ); CPPUNIT_ASSERT( v[0] == 10 ); CPPUNIT_ASSERT( v[1] == 10 ); CPPUNIT_ASSERT( v[2] == 10 ); CPPUNIT_ASSERT( v[3] == 10 ); CPPUNIT_ASSERT( v[4] == 10 ); /* { vector vf(2.0f, 3.0f); CPPUNIT_ASSERT( vf.size() == 2 ); CPPUNIT_ASSERT( vf.front() == 3.0f ); CPPUNIT_ASSERT( vf.back() == 3.0f ); } */ } struct TestStruct { unsigned int a[3]; }; void VectorTest::capacity() { { vector v; CPPUNIT_ASSERT( v.capacity() == 0 ); v.push_back(42); CPPUNIT_ASSERT( v.capacity() >= 1 ); v.reserve(5000); CPPUNIT_ASSERT( v.capacity() >= 5000 ); } { //Test that used to generate an assertion when using __debug_alloc. vector va; va.reserve(1); va.reserve(2); } } void VectorTest::at() { vector v; vector const& cv = v; v.push_back(10); CPPUNIT_ASSERT( v.at(0) == 10 ); v.at(0) = 20; CPPUNIT_ASSERT( cv.at(0) == 20 ); #if !defined (STLPORT) || defined (_STLP_USE_EXCEPTIONS) try { v.at(1) = 20; CPPUNIT_FAIL; } catch (out_of_range const&) { } catch (...) { CPPUNIT_FAIL; } #endif } void VectorTest::pointer() { vector v1; vector v2 = v1; vector v3; v3.insert( v3.end(), v1.begin(), v1.end() ); } void VectorTest::auto_ref() { vector ref; for (int i = 0; i < 5; ++i) { ref.push_back(i); } vector > v_v_int(1, ref); v_v_int.push_back(v_v_int[0]); v_v_int.push_back(ref); v_v_int.push_back(v_v_int[0]); v_v_int.push_back(v_v_int[0]); v_v_int.push_back(ref); vector >::iterator vvit(v_v_int.begin()), vvitEnd(v_v_int.end()); for (; vvit != vvitEnd; ++vvit) { CPPUNIT_ASSERT( *vvit == ref ); } /* * Forbidden by the Standard: v_v_int.insert(v_v_int.end(), v_v_int.begin(), v_v_int.end()); for (vvit = v_v_int.begin(), vvitEnd = v_v_int.end(); vvit != vvitEnd; ++vvit) { CPPUNIT_ASSERT( *vvit == ref ); } */ } void VectorTest::allocator_with_state() { char buf1[1024]; StackAllocator stack1(buf1, buf1 + sizeof(buf1)); char buf2[1024]; StackAllocator stack2(buf2, buf2 + sizeof(buf2)); { typedef vector > VectorInt; VectorInt vint1(10, 0, stack1); VectorInt vint1Cpy(vint1); VectorInt vint2(10, 1, stack2); VectorInt vint2Cpy(vint2); vint1.swap(vint2); CPPUNIT_ASSERT( vint1.get_allocator().swaped() ); CPPUNIT_ASSERT( vint2.get_allocator().swaped() ); CPPUNIT_ASSERT( vint1 == vint2Cpy ); CPPUNIT_ASSERT( vint2 == vint1Cpy ); CPPUNIT_ASSERT( vint1.get_allocator() == stack2 ); CPPUNIT_ASSERT( vint2.get_allocator() == stack1 ); } CPPUNIT_ASSERT( stack1.ok() ); CPPUNIT_ASSERT( stack2.ok() ); } struct Point { int x, y; }; struct PointEx : public Point { PointEx() : builtFromBase(false) {} PointEx(const Point&) : builtFromBase(true) {} bool builtFromBase; }; #if defined (STLPORT) # if defined (_STLP_USE_NAMESPACES) namespace std { # endif _STLP_TEMPLATE_NULL struct __type_traits { typedef __false_type has_trivial_default_constructor; typedef __true_type has_trivial_copy_constructor; typedef __true_type has_trivial_assignment_operator; typedef __true_type has_trivial_destructor; typedef __true_type is_POD_type; }; # if defined (_STLP_USE_NAMESPACES) } # endif #endif //This test check that vector implementation do not over optimize //operation as PointEx copy constructor is trivial void VectorTest::optimizations_check() { #if !defined (STLPORT) || !defined (_STLP_NO_MEMBER_TEMPLATES) vector v1(1); CPPUNIT_ASSERT( v1.size() == 1 ); vector v2(v1.begin(), v1.end()); CPPUNIT_ASSERT( v2.size() == 1 ); CPPUNIT_ASSERT( v2[0].builtFromBase == true ); #endif } void VectorTest::assign_check() { #if !defined (STLPORT) || !defined (_STLP_NO_MEMBER_TEMPLATES) vector v(3,1); int array[] = { 1, 2, 3, 4, 5 }; v.assign( array, array + 5 ); CPPUNIT_CHECK( v[4] == 5 ); CPPUNIT_CHECK( v[0] == 1 ); CPPUNIT_CHECK( v[1] == 2 ); #endif } void VectorTest::iterators() { vector vint(10, 0); vector const& crvint = vint; CPPUNIT_ASSERT( vint.begin() == vint.begin() ); CPPUNIT_ASSERT( crvint.begin() == vint.begin() ); CPPUNIT_ASSERT( vint.begin() == crvint.begin() ); CPPUNIT_ASSERT( crvint.begin() == crvint.begin() ); CPPUNIT_ASSERT( vint.begin() != vint.end() ); CPPUNIT_ASSERT( crvint.begin() != vint.end() ); CPPUNIT_ASSERT( vint.begin() != crvint.end() ); CPPUNIT_ASSERT( crvint.begin() != crvint.end() ); CPPUNIT_ASSERT( vint.rbegin() == vint.rbegin() ); // Not Standard: //CPPUNIT_ASSERT( vint.rbegin() == crvint.rbegin() ); //CPPUNIT_ASSERT( crvint.rbegin() == vint.rbegin() ); CPPUNIT_ASSERT( crvint.rbegin() == crvint.rbegin() ); CPPUNIT_ASSERT( vint.rbegin() != vint.rend() ); // Not Standard: //CPPUNIT_ASSERT( vint.rbegin() != crvint.rend() ); //CPPUNIT_ASSERT( crvint.rbegin() != vint.rend() ); CPPUNIT_ASSERT( crvint.rbegin() != crvint.rend() ); } #if !defined (STLPORT) || \ !defined (_STLP_USE_PTR_SPECIALIZATIONS) || defined (_STLP_CLASS_PARTIAL_SPECIALIZATION) /* Simple compilation test: Check that nested types like iterator * can be access even if type used to instanciate container is not * yet completely defined. */ class IncompleteClass { vector instances; typedef vector::iterator it; }; #endif #if defined (STLPORT) # define NOTHROW _STLP_NOTHROW #else # define NOTHROW throw() #endif /* This allocator implementation purpose is simply to break some * internal STLport mecanism specific to the STLport own allocator * implementation. */ template struct NotSTLportAllocator : public allocator<_Tp> { #if !defined (STLPORT) || defined (_STLP_MEMBER_TEMPLATE_CLASSES) template struct rebind { typedef NotSTLportAllocator<_Tp1> other; }; #endif NotSTLportAllocator() NOTHROW {} #if !defined (STLPORT) || defined (_STLP_MEMBER_TEMPLATES) template NotSTLportAllocator(const NotSTLportAllocator<_Tp1>&) NOTHROW {} #endif NotSTLportAllocator(const NotSTLportAllocator<_Tp>&) NOTHROW {} ~NotSTLportAllocator() NOTHROW {} }; /* This test check a potential issue with empty base class * optimization. Some compilers (VC6) do not implement it * correctly resulting ina wrong behavior. */ void VectorTest::ebo() { // We use heap memory as test failure can corrupt vector internal // representation making executable crash on vector destructor invocation. // We prefer a simple memory leak, internal corruption should be reveal // by size or capacity checks. typedef vector > V; V *pv1 = new V(1, 1); V *pv2 = new V(10, 2); size_t v1Capacity = pv1->capacity(); size_t v2Capacity = pv2->capacity(); pv1->swap(*pv2); CPPUNIT_ASSERT( pv1->size() == 10 ); CPPUNIT_ASSERT( pv1->capacity() == v2Capacity ); CPPUNIT_ASSERT( (*pv1)[5] == 2 ); CPPUNIT_ASSERT( pv2->size() == 1 ); CPPUNIT_ASSERT( pv2->capacity() == v1Capacity ); CPPUNIT_ASSERT( (*pv2)[0] == 1 ); delete pv2; delete pv1; }