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// -*- C++ -*- // Copyright (C) 2009, 2010 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library 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, or (at your option) any later // version. // This library 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 library; see the file COPYING3. If not see // <http://www.gnu.org/licenses/>. #ifndef _GLIBCXX_EXCEPTION_SAFETY_H #define _GLIBCXX_EXCEPTION_SAFETY_H #include <testsuite_container_traits.h> #include <ext/throw_allocator.h> // Container requirement testing. namespace __gnu_test { // Base class for exception testing, contains utilities. struct setup_base { typedef std::size_t size_type; typedef std::uniform_int_distribution<size_type> distribution_type; typedef std::mt19937 engine_type; // Return randomly generated integer on range [0, __max_size]. static size_type generate(size_type __max_size) { // Make the generator static... const engine_type engine; const distribution_type distribution; static auto generator = std::bind(distribution, engine, std::placeholders::_1); // ... but set the range for this particular invocation here. const typename distribution_type::param_type p(0, __max_size); size_type random = generator(p); if (random < distribution.min() || random > distribution.max()) { std::string __s("setup_base::generate"); __s += "\n"; __s += "random number generated is: "; char buf[40]; __builtin_sprintf(buf, "%lu", random); __s += buf; __s += " on range ["; __builtin_sprintf(buf, "%lu", distribution.min()); __s += buf; __s += ", "; __builtin_sprintf(buf, "%lu", distribution.max()); __s += buf; __s += "]\n"; std::__throw_out_of_range(__s.c_str()); } return random; } // Given an instantiating type, return a unique value. template<typename _Tp> struct generate_unique { typedef _Tp value_type; operator value_type() { static value_type __ret; ++__ret; return __ret; } }; // Partial specialization for pair. template<typename _Tp1, typename _Tp2> struct generate_unique<std::pair<const _Tp1, _Tp2>> { typedef _Tp1 first_type; typedef _Tp2 second_type; typedef std::pair<const _Tp1, _Tp2> pair_type; operator pair_type() { static first_type _S_1; static second_type _S_2; ++_S_1; ++_S_2; return pair_type(_S_1, _S_2); } }; // Partial specialization for throw_value template<typename _Cond> struct generate_unique<__gnu_cxx::throw_value_base<_Cond>> { typedef __gnu_cxx::throw_value_base<_Cond> value_type; operator value_type() { static size_t _S_i(0); return value_type(_S_i++); } }; // Construct container of size n directly. _Tp == container type. template<typename _Tp> struct make_container_base { _Tp _M_container; make_container_base() = default; make_container_base(const size_type n): _M_container(n) { } operator _Tp&() { return _M_container; } }; // Construct container of size n, via multiple insertions. For // associated and unordered types, unique value_type elements are // necessary. template<typename _Tp, bool = traits<_Tp>::is_mapped::value> struct make_insert_container_base : public make_container_base<_Tp> { using make_container_base<_Tp>::_M_container; typedef typename _Tp::value_type value_type; make_insert_container_base(const size_type n) { for (size_type i = 0; i < n; ++i) { value_type v = generate_unique<value_type>(); _M_container.insert(v); } assert(_M_container.size() == n); } }; template<typename _Tp> struct make_insert_container_base<_Tp, false> : public make_container_base<_Tp> { using make_container_base<_Tp>::_M_container; typedef typename _Tp::value_type value_type; make_insert_container_base(const size_type n) { for (size_type i = 0; i < n; ++i) { value_type v = generate_unique<value_type>(); _M_container.insert(_M_container.end(), v); } assert(_M_container.size() == n); } }; template<typename _Tp, bool = traits<_Tp>::has_size_type_constructor::value> struct make_container_n; // Specialization for non-associative types that have a constructor with // a size argument. template<typename _Tp> struct make_container_n<_Tp, true> : public make_container_base<_Tp> { make_container_n(const size_type n) : make_container_base<_Tp>(n) { } }; template<typename _Tp> struct make_container_n<_Tp, false> : public make_insert_container_base<_Tp> { make_container_n(const size_type n) : make_insert_container_base<_Tp>(n) { } }; // Randomly size and populate a given container reference. // NB: Responsibility for turning off exceptions lies with caller. template<typename _Tp, bool = traits<_Tp>::is_allocator_aware::value> struct populate { typedef _Tp container_type; typedef typename container_type::allocator_type allocator_type; typedef typename container_type::value_type value_type; populate(_Tp& __container) { const allocator_type a = __container.get_allocator(); // Size test container. const size_type max_elements = 100; size_type n = generate(max_elements); // Construct new container. make_container_n<container_type> made(n); container_type& tmp = made; std::swap(tmp, __container); } }; // Partial specialization, empty. template<typename _Tp> struct populate<_Tp, false> { populate(_Tp&) { } }; // Compare two containers for equivalence. // Right now, that means size. // Returns true if equal, throws if not. template<typename _Tp> static bool compare(const _Tp& __control, const _Tp& __test) { // Make sure test container is in a consistent state, as // compared to the control container. // NB: Should be equivalent to __test != __control, but // computed without equivalence operators const size_type szt = std::distance(__test.begin(), __test.end()); const size_type szc = std::distance(__control.begin(), __control.end()); bool __equal_size = szt == szc; // Should test iterator validity before and after exception. bool __equal_it = std::equal(__test.begin(), __test.end(), __control.begin()); if (!__equal_size || !__equal_it) throw std::logic_error("setup_base::compare containers not equal"); return true; } }; // Containing structure holding functors. struct functor_base : public setup_base { // Abstract the erase function. template<typename _Tp> struct erase_base { typedef typename _Tp::iterator iterator; iterator (_Tp::* _F_erase_point)(iterator); iterator (_Tp::* _F_erase_range)(iterator, iterator); erase_base() : _F_erase_point(&_Tp::erase), _F_erase_range(&_Tp::erase) { } }; // Specialization, as forward_list has erase_after. template<typename _Tp1, typename _Tp2> struct erase_base<std::forward_list<_Tp1, _Tp2>> { typedef std::forward_list<_Tp1, _Tp2> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; void (container_type::* _F_erase_point)(const_iterator); void (container_type::* _F_erase_range)(const_iterator, const_iterator); erase_base() : _F_erase_point(&container_type::erase_after), _F_erase_range(&container_type::erase_after) { } }; // Specializations for the unordered containers. template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4, typename _Tp5> struct erase_base<std::unordered_map<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5>> { typedef std::unordered_map<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; iterator (container_type::* _F_erase_point)(const_iterator); iterator (container_type::* _F_erase_range)(const_iterator, const_iterator); erase_base() : _F_erase_point(&container_type::erase), _F_erase_range(&container_type::erase) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4, typename _Tp5> struct erase_base<std::unordered_multimap<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5>> { typedef std::unordered_multimap<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; iterator (container_type::* _F_erase_point)(const_iterator); iterator (container_type::* _F_erase_range)(const_iterator, const_iterator); erase_base() : _F_erase_point(&container_type::erase), _F_erase_range(&container_type::erase) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4> struct erase_base<std::unordered_set<_Tp1, _Tp2, _Tp3, _Tp4>> { typedef std::unordered_set<_Tp1, _Tp2, _Tp3, _Tp4> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; iterator (container_type::* _F_erase_point)(const_iterator); iterator (container_type::* _F_erase_range)(const_iterator, const_iterator); erase_base() : _F_erase_point(&container_type::erase), _F_erase_range(&container_type::erase) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4> struct erase_base<std::unordered_multiset<_Tp1, _Tp2, _Tp3, _Tp4>> { typedef std::unordered_multiset<_Tp1, _Tp2, _Tp3, _Tp4> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; iterator (container_type::* _F_erase_point)(const_iterator); iterator (container_type::* _F_erase_range)(const_iterator, const_iterator); erase_base() : _F_erase_point(&container_type::erase), _F_erase_range(&container_type::erase) { } }; template<typename _Tp, bool = traits<_Tp>::has_erase::value> struct erase_point : public erase_base<_Tp> { using erase_base<_Tp>::_F_erase_point; void operator()(_Tp& __container) { try { // NB: Should be equivalent to size() member function, but // computed with begin() and end(). const size_type sz = std::distance(__container.begin(), __container.end()); // NB: Lowest common denominator: use forward iterator operations. auto i = __container.begin(); std::advance(i, generate(sz)); // Makes it easier to think of this as __container.erase(i) (__container.*_F_erase_point)(i); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct erase_point<_Tp, false> { void operator()(_Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::has_erase::value> struct erase_range : public erase_base<_Tp> { using erase_base<_Tp>::_F_erase_range; void operator()(_Tp& __container) { try { const size_type sz = std::distance(__container.begin(), __container.end()); size_type s1 = generate(sz); size_type s2 = generate(sz); auto i1 = __container.begin(); auto i2 = __container.begin(); std::advance(i1, std::min(s1, s2)); std::advance(i2, std::max(s1, s2)); // Makes it easier to think of this as __container.erase(i1, i2). (__container.*_F_erase_range)(i1, i2); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct erase_range<_Tp, false> { void operator()(_Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::has_push_pop::value> struct pop_front { void operator()(_Tp& __container) { try { __container.pop_front(); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct pop_front<_Tp, false> { void operator()(_Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::has_push_pop::value && traits<_Tp>::is_reversible::value> struct pop_back { void operator()(_Tp& __container) { try { __container.pop_back(); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct pop_back<_Tp, false> { void operator()(_Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::has_push_pop::value> struct push_front { typedef _Tp container_type; typedef typename container_type::value_type value_type; void operator()(_Tp& __test) { try { const value_type cv = generate_unique<value_type>(); __test.push_front(cv); } catch(const __gnu_cxx::forced_error&) { throw; } } // Assumes containers start out equivalent. void operator()(_Tp& __control, _Tp& __test) { try { const value_type cv = generate_unique<value_type>(); __test.push_front(cv); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct push_front<_Tp, false> { void operator()(_Tp&) { } void operator()(_Tp&, _Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::has_push_pop::value && traits<_Tp>::is_reversible::value> struct push_back { typedef _Tp container_type; typedef typename container_type::value_type value_type; void operator()(_Tp& __test) { try { const value_type cv = generate_unique<value_type>(); __test.push_back(cv); } catch(const __gnu_cxx::forced_error&) { throw; } } // Assumes containers start out equivalent. void operator()(_Tp& __control, _Tp& __test) { try { const value_type cv = generate_unique<value_type>(); __test.push_back(cv); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct push_back<_Tp, false> { void operator()(_Tp&) { } void operator()(_Tp&, _Tp&) { } }; // Abstract the insert function into two parts: // 1, insert_base_functions == holds function pointer // 2, insert_base == links function pointer to class insert method template<typename _Tp> struct insert_base { typedef typename _Tp::iterator iterator; typedef typename _Tp::value_type value_type; iterator (_Tp::* _F_insert_point)(iterator, const value_type&); insert_base() : _F_insert_point(&_Tp::insert) { } }; // Specialization, as string insertion has a different signature. template<typename _Tp1, typename _Tp2, typename _Tp3> struct insert_base<std::basic_string<_Tp1, _Tp2, _Tp3>> { typedef std::basic_string<_Tp1, _Tp2, _Tp3> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(iterator, value_type); insert_base() : _F_insert_point(&container_type::insert) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, template <typename, typename, typename> class _Tp4> struct insert_base<__gnu_cxx::__versa_string<_Tp1, _Tp2, _Tp3, _Tp4>> { typedef __gnu_cxx::__versa_string<_Tp1, _Tp2, _Tp3, _Tp4> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(iterator, value_type); insert_base() : _F_insert_point(&container_type::insert) { } }; // Specialization, as forward_list insertion has a different signature. template<typename _Tp1, typename _Tp2> struct insert_base<std::forward_list<_Tp1, _Tp2>> { typedef std::forward_list<_Tp1, _Tp2> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(const_iterator, const value_type&); insert_base() : _F_insert_point(&container_type::insert_after) { } }; // Likewise for the unordered containers. template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4, typename _Tp5> struct insert_base<std::unordered_map<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5>> { typedef std::unordered_map<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(const_iterator, const value_type&); insert_base() : _F_insert_point(&container_type::insert) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4, typename _Tp5> struct insert_base<std::unordered_multimap<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5>> { typedef std::unordered_multimap<_Tp1, _Tp2, _Tp3, _Tp4, _Tp5> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(const_iterator, const value_type&); insert_base() : _F_insert_point(&container_type::insert) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4> struct insert_base<std::unordered_set<_Tp1, _Tp2, _Tp3, _Tp4>> { typedef std::unordered_set<_Tp1, _Tp2, _Tp3, _Tp4> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(const_iterator, const value_type&); insert_base() : _F_insert_point(&container_type::insert) { } }; template<typename _Tp1, typename _Tp2, typename _Tp3, typename _Tp4> struct insert_base<std::unordered_multiset<_Tp1, _Tp2, _Tp3, _Tp4>> { typedef std::unordered_multiset<_Tp1, _Tp2, _Tp3, _Tp4> container_type; typedef typename container_type::iterator iterator; typedef typename container_type::const_iterator const_iterator; typedef typename container_type::value_type value_type; iterator (container_type::* _F_insert_point)(const_iterator, const value_type&); insert_base() : _F_insert_point(&container_type::insert) { } }; template<typename _Tp, bool = traits<_Tp>::has_insert::value> struct insert_point : public insert_base<_Tp> { typedef _Tp container_type; typedef typename container_type::value_type value_type; using insert_base<_Tp>::_F_insert_point; void operator()(_Tp& __test) { try { const value_type cv = generate_unique<value_type>(); const size_type sz = std::distance(__test.begin(), __test.end()); size_type s = generate(sz); auto i = __test.begin(); std::advance(i, s); (__test.*_F_insert_point)(i, cv); } catch(const __gnu_cxx::forced_error&) { throw; } } // Assumes containers start out equivalent. void operator()(_Tp& __control, _Tp& __test) { try { const value_type cv = generate_unique<value_type>(); const size_type sz = std::distance(__test.begin(), __test.end()); size_type s = generate(sz); auto i = __test.begin(); std::advance(i, s); (__test.*_F_insert_point)(i, cv); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct insert_point<_Tp, false> { void operator()(_Tp&) { } void operator()(_Tp&, _Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::is_associative::value || traits<_Tp>::is_unordered::value> struct clear { void operator()(_Tp& __container) { try { __container.clear(); } catch(const __gnu_cxx::forced_error&) { throw; } } }; // Specialization, empty. template<typename _Tp> struct clear<_Tp, false> { void operator()(_Tp&) { } }; template<typename _Tp, bool = traits<_Tp>::is_unordered::value> struct rehash { void operator()(_Tp& __test) { try { size_type s = generate(__test.bucket_count()); __test.rehash(s); } catch(const __gnu_cxx::forced_error&) { throw; } } void operator()(_Tp& __control, _Tp& __test) { try { size_type s = generate(__test.bucket_count()); __test.rehash(s); } catch(const __gnu_cxx::forced_error&) { // Also check hash status. bool fail(false); if (__control.load_factor() != __test.load_factor()) fail = true; if (__control.max_load_factor() != __test.max_load_factor()) fail = true; if (__control.bucket_count() != __test.bucket_count()) fail = true; if (__control.max_bucket_count() != __test.max_bucket_count()) fail = true; if (fail) { char buf[40]; std::string __s("setup_base::rehash " "containers not equal"); __s += "\n"; __s += "\n"; __s += "\t\t\tcontrol : test"; __s += "\n"; __s += "load_factor\t\t"; __builtin_sprintf(buf, "%lu", __control.load_factor()); __s += buf; __s += " : "; __builtin_sprintf(buf, "%lu", __test.load_factor()); __s += buf; __s += "\n"; __s += "max_load_factor\t\t"; __builtin_sprintf(buf, "%lu", __control.max_load_factor()); __s += buf; __s += " : "; __builtin_sprintf(buf, "%lu", __test.max_load_factor()); __s += buf; __s += "\n"; __s += "bucket_count\t\t"; __builtin_sprintf(buf, "%lu", __control.bucket_count()); __s += buf; __s += " : "; __builtin_sprintf(buf, "%lu", __test.bucket_count()); __s += buf; __s += "\n"; __s += "max_bucket_count\t"; __builtin_sprintf(buf, "%lu", __control.max_bucket_count()); __s += buf; __s += " : "; __builtin_sprintf(buf, "%lu", __test.max_bucket_count()); __s += buf; __s += "\n"; std::__throw_logic_error(__s.c_str()); } } } }; // Specialization, empty. template<typename _Tp> struct rehash<_Tp, false> { void operator()(_Tp&) { } void operator()(_Tp&, _Tp&) { } }; template<typename _Tp> struct swap { _Tp _M_other; void operator()(_Tp& __container) { try { __container.swap(_M_other); } catch(const __gnu_cxx::forced_error&) { throw; } } }; template<typename _Tp> struct iterator_operations { typedef _Tp container_type; typedef typename container_type::iterator iterator; void operator()(_Tp& __container) { try { // Any will do. iterator i = __container.begin(); iterator __attribute__((unused)) icopy(i); iterator __attribute__((unused)) iassign = i; } catch(const __gnu_cxx::forced_error&) { throw; } } }; template<typename _Tp> struct const_iterator_operations { typedef _Tp container_type; typedef typename container_type::const_iterator const_iterator; void operator()(_Tp& __container) { try { // Any will do. const_iterator i = __container.begin(); const_iterator __attribute__((unused)) icopy(i); const_iterator __attribute__((unused)) iassign = i; } catch(const __gnu_cxx::forced_error&) { throw; } } }; }; // Base class for exception tests. template<typename _Tp> struct test_base: public functor_base { typedef _Tp container_type; typedef functor_base base_type; typedef populate<container_type> populate; typedef make_container_n<container_type> make_container_n; typedef clear<container_type> clear; typedef erase_point<container_type> erase_point; typedef erase_range<container_type> erase_range; typedef insert_point<container_type> insert_point; typedef pop_front<container_type> pop_front; typedef pop_back<container_type> pop_back; typedef push_front<container_type> push_front; typedef push_back<container_type> push_back; typedef rehash<container_type> rehash; typedef swap<container_type> swap; typedef iterator_operations<container_type> iterator_ops; typedef const_iterator_operations<container_type> const_iterator_ops; using base_type::compare; // Functor objects. clear _M_clear; erase_point _M_erasep; erase_range _M_eraser; insert_point _M_insertp; pop_front _M_popf; pop_back _M_popb; push_front _M_pushf; push_back _M_pushb; rehash _M_rehash; swap _M_swap; iterator_ops _M_iops; const_iterator_ops _M_ciops; }; // Run through all member functions for basic exception safety // guarantee: no resource leaks when exceptions are thrown. // // Types of resources checked: memory. // // For each member function, use throw_value and throw_allocator as // value_type and allocator_type to force potential exception safety // errors. // // NB: Assumes // _Tp::value_type is __gnu_cxx::throw_value_* // _Tp::allocator_type is __gnu_cxx::throw_allocator_* // And that the _Cond template parameter for them both is // __gnu_cxx::limit_condition. template<typename _Tp> struct basic_safety : public test_base<_Tp> { typedef _Tp container_type; typedef test_base<container_type> base_type; typedef typename base_type::populate populate; typedef std::function<void(container_type&)> function_type; typedef __gnu_cxx::limit_condition condition_type; using base_type::generate; container_type _M_container; std::vector<function_type> _M_functions; basic_safety() { run(); } void run() { // Setup. condition_type::never_adjustor off; // Construct containers. populate p1(_M_container); populate p2(base_type::_M_swap._M_other); // Construct list of member functions to exercise. _M_functions.push_back(function_type(base_type::_M_iops)); _M_functions.push_back(function_type(base_type::_M_ciops)); _M_functions.push_back(function_type(base_type::_M_erasep)); _M_functions.push_back(function_type(base_type::_M_eraser)); _M_functions.push_back(function_type(base_type::_M_insertp)); _M_functions.push_back(function_type(base_type::_M_popf)); _M_functions.push_back(function_type(base_type::_M_popb)); _M_functions.push_back(function_type(base_type::_M_pushf)); _M_functions.push_back(function_type(base_type::_M_pushb)); _M_functions.push_back(function_type(base_type::_M_rehash)); _M_functions.push_back(function_type(base_type::_M_swap)); // Last. _M_functions.push_back(function_type(base_type::_M_clear)); // Run tests. auto i = _M_functions.begin(); for (auto i = _M_functions.begin(); i != _M_functions.end(); ++i) { function_type& f = *i; run_steps_to_limit(f); } } template<typename _Funct> void run_steps_to_limit(const _Funct& __f) { size_t i(1); bool exit(false); auto a = _M_container.get_allocator(); do { // Use the current step as an allocator label. a.set_label(i); try { condition_type::limit_adjustor limit(i); __f(_M_container); // If we get here, done. exit = true; } catch(const __gnu_cxx::forced_error&) { // Check this step for allocations. // NB: Will throw std::logic_error if allocations. a.check_allocated(i); // Check memory allocated with operator new. ++i; } } while (!exit); // Log count info. std::cout << __f.target_type().name() << std::endl; std::cout << "end count " << i << std::endl; } }; // Run through all member functions with a no throw requirement, sudden death. // all: member functions erase, pop_back, pop_front, swap // iterator copy ctor, assignment operator // unordered and associative: clear // NB: Assumes _Tp::allocator_type is __gnu_cxx::throw_allocator_random. template<typename _Tp> struct generation_prohibited : public test_base<_Tp> { typedef _Tp container_type; typedef test_base<container_type> base_type; typedef typename base_type::populate populate; typedef __gnu_cxx::random_condition condition_type; container_type _M_container; generation_prohibited() { run(); } void run() { // Furthermore, assumes that the test functor will throw // forced_exception via throw_allocator, that all errors are // propagated and in error. Sudden death! // Setup. { condition_type::never_adjustor off; populate p1(_M_container); populate p2(base_type::_M_swap._M_other); } // Run tests. { condition_type::always_adjustor on; // NB: Vector and deque are special, erase can throw if the copy // constructor or assignment operator of value_type throws. if (!traits<container_type>::has_throwing_erase::value) { _M_erasep(_M_container); _M_eraser(_M_container); } _M_popf(_M_container); _M_popb(_M_container); _M_iops(_M_container); _M_ciops(_M_container); _M_swap(_M_container); // Last. _M_clear(_M_container); } } }; // Test strong exception guarantee. // Run through all member functions with a roll-back, consistent // coherent requirement. // all: member functions insert of a single element, push_back, push_front // unordered: rehash template<typename _Tp> struct propagation_consistent : public test_base<_Tp> { typedef _Tp container_type; typedef test_base<container_type> base_type; typedef typename base_type::populate populate; typedef std::function<void(container_type&)> function_type; typedef __gnu_cxx::limit_condition condition_type; using base_type::compare; container_type _M_container_test; container_type _M_container_control; std::vector<function_type> _M_functions; propagation_consistent() { run(); } void sync() { _M_container_test = _M_container_control; } // Run test. void run() { // Setup. condition_type::never_adjustor off; // Construct containers. populate p(_M_container_control); sync(); // Construct list of member functions to exercise. _M_functions.push_back(function_type(base_type::_M_pushf)); _M_functions.push_back(function_type(base_type::_M_pushb)); _M_functions.push_back(function_type(base_type::_M_insertp)); _M_functions.push_back(function_type(base_type::_M_rehash)); // Run tests. auto i = _M_functions.begin(); for (auto i = _M_functions.begin(); i != _M_functions.end(); ++i) { function_type& f = *i; run_steps_to_limit(f); } } template<typename _Funct> void run_steps_to_limit(const _Funct& __f) { size_t i(1); bool exit(false); do { sync(); try { condition_type::limit_adjustor limit(i); __f(_M_container_test); // If we get here, done. exit = true; } catch(const __gnu_cxx::forced_error&) { compare(_M_container_control, _M_container_test); ++i; } } while (!exit); // Log count info. std::cout << __f.target_type().name() << std::endl; std::cout << "end count " << i << std::endl; } }; } // namespace __gnu_test #endif
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