// (C) Copyright Gennadiy Rozental 2001. // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // See http://www.boost.org/libs/test for the library home page. // // File : $RCSfile$ // // Version : $Revision$ // // Description : implements framework API - main driver for the test // *************************************************************************** #ifndef BOOST_TEST_FRAMEWORK_IPP_021005GER #define BOOST_TEST_FRAMEWORK_IPP_021005GER // Boost.Test #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if BOOST_TEST_SUPPORT_TOKEN_ITERATOR #include #endif #include #include #include #include #include // Boost #include #include // STL #include #include #include #include #include #include #include #ifdef BOOST_NO_CXX98_RANDOM_SHUFFLE #include #endif #ifdef BOOST_NO_STDC_NAMESPACE namespace std { using ::time; using ::srand; } #endif #include //____________________________________________________________________________// namespace boost { namespace unit_test { namespace framework { namespace impl { // ************************************************************************** // // ************** order detection helpers ************** // // ************************************************************************** // struct order_info { order_info() : depth(-1) {} int depth; std::vector dependant_siblings; }; typedef std::set tu_id_set; typedef std::map order_info_per_tu; // !! ?? unordered map //____________________________________________________________________________// static test_unit_id get_tu_parent( test_unit_id tu_id ) { return framework::get( tu_id, TUT_ANY ).p_parent_id; } //____________________________________________________________________________// static int tu_depth( test_unit_id tu_id, test_unit_id master_tu_id, order_info_per_tu& tuoi ) { if( tu_id == master_tu_id ) return 0; order_info& info = tuoi[tu_id]; if( info.depth == -1 ) info.depth = tu_depth( get_tu_parent( tu_id ), master_tu_id, tuoi ) + 1; return info.depth; } //____________________________________________________________________________// static void collect_dependant_siblings( test_unit_id from, test_unit_id to, test_unit_id master_tu_id, order_info_per_tu& tuoi ) { int from_depth = tu_depth( from, master_tu_id, tuoi ); int to_depth = tu_depth( to, master_tu_id, tuoi ); while(from_depth > to_depth) { from = get_tu_parent( from ); --from_depth; } while(from_depth < to_depth) { to = get_tu_parent( to ); --to_depth; } while(true) { test_unit_id from_parent = get_tu_parent( from ); test_unit_id to_parent = get_tu_parent( to ); if( from_parent == to_parent ) break; from = from_parent; to = to_parent; } tuoi[from].dependant_siblings.push_back( to ); } //____________________________________________________________________________// static counter_t assign_sibling_rank( test_unit_id tu_id, order_info_per_tu& tuoi ) { test_unit& tu = framework::get( tu_id, TUT_ANY ); BOOST_TEST_SETUP_ASSERT( tu.p_sibling_rank != (std::numeric_limits::max)(), "Cyclic dependency detected involving test unit \"" + tu.full_name() + "\"" ); if( tu.p_sibling_rank != 0 ) return tu.p_sibling_rank; order_info const& info = tuoi[tu_id]; // indicate in progress tu.p_sibling_rank.value = (std::numeric_limits::max)(); counter_t new_rank = 1; BOOST_TEST_FOREACH( test_unit_id, sibling_id, info.dependant_siblings ) new_rank = (std::max)(new_rank, assign_sibling_rank( sibling_id, tuoi ) + 1); return tu.p_sibling_rank.value = new_rank; } //____________________________________________________________________________// // ************************************************************************** // // ************** test_init call wrapper ************** // // ************************************************************************** // static void invoke_init_func( init_unit_test_func init_func ) { #ifdef BOOST_TEST_ALTERNATIVE_INIT_API BOOST_TEST_I_ASSRT( (*init_func)(), std::runtime_error( "test module initialization failed" ) ); #else test_suite* manual_test_units = (*init_func)( framework::master_test_suite().argc, framework::master_test_suite().argv ); if( manual_test_units ) framework::master_test_suite().add( manual_test_units ); #endif } // ************************************************************************** // // ************** name_filter ************** // // ************************************************************************** // class name_filter : public test_tree_visitor { struct component { component( const_string name ) // has to be implicit { if( name == "*" ) m_kind = SFK_ALL; else if( first_char( name ) == '*' && last_char( name ) == '*' ) { m_kind = SFK_SUBSTR; m_name = name.substr( 1, name.size()-1 ); } else if( first_char( name ) == '*' ) { m_kind = SFK_TRAILING; m_name = name.substr( 1 ); } else if( last_char( name ) == '*' ) { m_kind = SFK_LEADING; m_name = name.substr( 0, name.size()-1 ); } else { m_kind = SFK_MATCH; m_name = name; } } bool pass( test_unit const& tu ) const { const_string name( tu.p_name ); switch( m_kind ) { default: case SFK_ALL: return true; case SFK_LEADING: return name.substr( 0, m_name.size() ) == m_name; case SFK_TRAILING: return name.size() >= m_name.size() && name.substr( name.size() - m_name.size() ) == m_name; case SFK_SUBSTR: return name.find( m_name ) != const_string::npos; case SFK_MATCH: return m_name == tu.p_name.get(); } } enum kind { SFK_ALL, SFK_LEADING, SFK_TRAILING, SFK_SUBSTR, SFK_MATCH }; kind m_kind; const_string m_name; }; public: // Constructor name_filter( test_unit_id_list& targ_list, const_string filter_expr ) : m_targ_list( targ_list ), m_depth( 0 ) { #ifdef BOOST_TEST_SUPPORT_TOKEN_ITERATOR utils::string_token_iterator tit( filter_expr, (utils::dropped_delimeters = "/", utils::kept_delimeters = utils::dt_none) ); while( tit != utils::string_token_iterator() ) { m_components.push_back( std::vector( utils::string_token_iterator( *tit, (utils::dropped_delimeters = ",", utils::kept_delimeters = utils::dt_none) ), utils::string_token_iterator() ) ); ++tit; } #endif } private: bool filter_unit( test_unit const& tu ) { // skip master test suite if( m_depth == 0 ) return true; // corresponding name filters are at level m_depth-1 std::vector const& filters = m_components[m_depth-1]; // look for match using namespace boost::placeholders; return std::find_if( filters.begin(), filters.end(), bind( &component::pass, _1, boost::ref(tu) ) ) != filters.end(); } // test_tree_visitor interface virtual void visit( test_case const& tc ) { // make sure we only accept test cases if we match last component of the filter if( m_depth == m_components.size() && filter_unit( tc ) ) m_targ_list.push_back( tc.p_id ); // found a test case } virtual bool test_suite_start( test_suite const& ts ) { if( !filter_unit( ts ) ) return false; if( m_depth < m_components.size() ) { ++m_depth; return true; } m_targ_list.push_back( ts.p_id ); // found a test suite return false; } virtual void test_suite_finish( test_suite const& /*ts*/ ) { --m_depth; } // Data members typedef std::vector > components_per_level; components_per_level m_components; test_unit_id_list& m_targ_list; unsigned m_depth; }; // ************************************************************************** // // ************** label_filter ************** // // ************************************************************************** // class label_filter : public test_tree_visitor { public: label_filter( test_unit_id_list& targ_list, const_string label ) : m_targ_list( targ_list ) , m_label( label ) {} private: // test_tree_visitor interface virtual bool visit( test_unit const& tu ) { if( tu.has_label( m_label ) ) { // found a test unit; add it to list of tu to enable with children and stop recursion in case of suites m_targ_list.push_back( tu.p_id ); return false; } return true; } // Data members test_unit_id_list& m_targ_list; const_string m_label; }; // ************************************************************************** // // ************** set_run_status ************** // // ************************************************************************** // class set_run_status : public test_tree_visitor { public: explicit set_run_status( test_unit::run_status rs, test_unit_id_list* dep_collector = 0 ) : m_new_status( rs ) , m_dep_collector( dep_collector ) {} // test_tree_visitor interface virtual bool visit( test_unit const& tu ) { const_cast(tu).p_run_status.value = m_new_status == test_unit::RS_INVALID ? tu.p_default_status : m_new_status; if( m_dep_collector ) { BOOST_TEST_FOREACH( test_unit_id, dep_id, tu.p_dependencies.get() ) { test_unit const& dep = framework::get( dep_id, TUT_ANY ); if( dep.p_run_status == tu.p_run_status ) continue; BOOST_TEST_FRAMEWORK_MESSAGE( "Including test " << dep.p_type_name << ' ' << dep.full_name() << " as a dependency of test " << tu.p_type_name << ' ' << tu.full_name() ); m_dep_collector->push_back( dep_id ); } } return true; } private: // Data members test_unit::run_status m_new_status; test_unit_id_list* m_dep_collector; }; // ************************************************************************** // // ************** parse_filters ************** // // ************************************************************************** // static void add_filtered_test_units( test_unit_id master_tu_id, const_string filter, test_unit_id_list& targ ) { // Choose between two kinds of filters if( filter[0] == '@' ) { filter.trim_left( 1 ); label_filter lf( targ, filter ); traverse_test_tree( master_tu_id, lf, true ); } else { name_filter nf( targ, filter ); traverse_test_tree( master_tu_id, nf, true ); } } //____________________________________________________________________________// static bool parse_filters( test_unit_id master_tu_id, test_unit_id_list& tu_to_enable, test_unit_id_list& tu_to_disable ) { // 10. collect tu to enable and disable based on filters bool had_selector_filter = false; std::vector const& filters = runtime_config::get >( runtime_config::btrt_run_filters ); BOOST_TEST_FOREACH( const_string, filter, filters ) { BOOST_TEST_SETUP_ASSERT( !filter.is_empty(), "Invalid filter specification" ); // each --run_test command may also be separated by a ':' (environment variable) utils::string_token_iterator t_filter_it( filter, (utils::dropped_delimeters = ":", utils::kept_delimeters = utils::dt_none) ); while( t_filter_it != utils::string_token_iterator() ) { const_string filter_token = *t_filter_it; enum { SELECTOR, ENABLER, DISABLER } filter_type = SELECTOR; // 11. Deduce filter type if( filter_token[0] == '!' || filter_token[0] == '+' ) { filter_type = filter_token[0] == '+' ? ENABLER : DISABLER; filter_token.trim_left( 1 ); BOOST_TEST_SETUP_ASSERT( !filter_token.is_empty(), "Invalid filter specification" ); } had_selector_filter |= filter_type == SELECTOR; // 12. Add test units to corresponding list switch( filter_type ) { case SELECTOR: case ENABLER: add_filtered_test_units( master_tu_id, filter_token, tu_to_enable ); break; case DISABLER: add_filtered_test_units( master_tu_id, filter_token, tu_to_disable ); break; } ++t_filter_it; } } return had_selector_filter; } //____________________________________________________________________________// #ifdef BOOST_NO_CXX98_RANDOM_SHUFFLE // a poor man's implementation of random_shuffle template< class RandomIt, class RandomFunc > void random_shuffle( RandomIt first, RandomIt last, RandomFunc &r ) { typedef typename std::iterator_traits::difference_type difference_type; difference_type n = last - first; for (difference_type i = n-1; i > 0; --i) { difference_type j = r(i+1); if (j != i) { using std::swap; swap(first[i], first[j]); } } } #endif // A simple handle for registering the global fixtures to the master test suite // without deleting an existing static object (the global fixture itself) when the program // terminates (shared_ptr). class global_fixture_handle : public test_unit_fixture { public: global_fixture_handle(test_unit_fixture* fixture) : m_global_fixture(fixture) {} ~global_fixture_handle() {} virtual void setup() { m_global_fixture->setup(); } virtual void teardown() { m_global_fixture->teardown(); } private: test_unit_fixture* m_global_fixture; }; } // namespace impl // ************************************************************************** // // ************** framework::state ************** // // ************************************************************************** // unsigned long int const TIMEOUT_EXCEEDED = static_cast( -1 ); class state { public: state() : m_master_test_suite( 0 ) , m_curr_test_unit( INV_TEST_UNIT_ID ) , m_next_test_case_id( MIN_TEST_CASE_ID ) , m_next_test_suite_id( MIN_TEST_SUITE_ID ) , m_test_in_progress( false ) , m_context_idx( 0 ) , m_log_sinks( ) , m_report_sink( std::cerr ) { } ~state() { clear(); } void clear() { while( !m_test_units.empty() ) { test_unit_store::value_type const& tu = *m_test_units.begin(); test_unit const* tu_ptr = tu.second; // the delete will erase this element from map if( ut_detail::test_id_2_unit_type( tu.second->p_id ) == TUT_SUITE ) delete static_cast(tu_ptr); else delete static_cast(tu_ptr); } } void set_tu_id( test_unit& tu, test_unit_id id ) { tu.p_id.value = id; } ////////////////////////////////////////////////////////////////// // Validates the dependency graph and deduces the sibling dependency rank for each child void deduce_siblings_order( test_unit_id tu_id, test_unit_id master_tu_id, impl::order_info_per_tu& tuoi ) { test_unit& tu = framework::get( tu_id, TUT_ANY ); // collect all sibling dependancy from tu own list BOOST_TEST_FOREACH( test_unit_id, dep_id, tu.p_dependencies.get() ) collect_dependant_siblings( tu_id, dep_id, master_tu_id, tuoi ); if( tu.p_type != TUT_SUITE ) return; test_suite& ts = static_cast(tu); // recursive call to children first BOOST_TEST_FOREACH( test_unit_id, chld_id, ts.m_children ) deduce_siblings_order( chld_id, master_tu_id, tuoi ); ts.m_ranked_children.clear(); BOOST_TEST_FOREACH( test_unit_id, chld_id, ts.m_children ) { counter_t rank = assign_sibling_rank( chld_id, tuoi ); ts.m_ranked_children.insert( std::make_pair( rank, chld_id ) ); } } ////////////////////////////////////////////////////////////////// // Finalize default run status: // 1) inherit run status from parent where applicable // 2) if any of test units in test suite enabled enable it as well bool finalize_default_run_status( test_unit_id tu_id, test_unit::run_status parent_status ) { test_unit& tu = framework::get( tu_id, TUT_ANY ); if( tu.p_default_status == test_suite::RS_INHERIT ) tu.p_default_status.value = parent_status; // go through list of children if( tu.p_type == TUT_SUITE ) { bool has_enabled_child = false; BOOST_TEST_FOREACH( test_unit_id, chld_id, static_cast(tu).m_children ) has_enabled_child |= finalize_default_run_status( chld_id, tu.p_default_status ); tu.p_default_status.value = has_enabled_child ? test_suite::RS_ENABLED : test_suite::RS_DISABLED; } return tu.p_default_status == test_suite::RS_ENABLED; } ////////////////////////////////////////////////////////////////// bool finalize_run_status( test_unit_id tu_id ) { test_unit& tu = framework::get( tu_id, TUT_ANY ); // go through list of children if( tu.p_type == TUT_SUITE ) { bool has_enabled_child = false; BOOST_TEST_FOREACH( test_unit_id, chld_id, static_cast(tu).m_children) has_enabled_child |= finalize_run_status( chld_id ); tu.p_run_status.value = has_enabled_child ? test_suite::RS_ENABLED : test_suite::RS_DISABLED; } return tu.is_enabled(); } ////////////////////////////////////////////////////////////////// void deduce_run_status( test_unit_id master_tu_id ) { using namespace framework::impl; test_unit_id_list tu_to_enable; test_unit_id_list tu_to_disable; // 10. If there are any filters supplied, figure out lists of test units to enable/disable bool had_selector_filter = !runtime_config::get >( runtime_config::btrt_run_filters ).empty() && parse_filters( master_tu_id, tu_to_enable, tu_to_disable ); // 20. Set the stage: either use default run status or disable all test units set_run_status initial_setter( had_selector_filter ? test_unit::RS_DISABLED : test_unit::RS_INVALID ); traverse_test_tree( master_tu_id, initial_setter, true ); // 30. Apply all selectors and enablers. while( !tu_to_enable.empty() ) { test_unit& tu = framework::get( tu_to_enable.back(), TUT_ANY ); tu_to_enable.pop_back(); // 35. Ignore test units which are already enabled if( tu.is_enabled() ) continue; // set new status and add all dependencies into tu_to_enable set_run_status enabler( test_unit::RS_ENABLED, &tu_to_enable ); traverse_test_tree( tu.p_id, enabler, true ); // Add the dependencies of the parent suites, see trac #13149 test_unit_id parent_id = tu.p_parent_id; while( parent_id != INV_TEST_UNIT_ID && parent_id != master_tu_id ) { // we do not use the traverse_test_tree as otherwise it would enable the sibblings and subtree // of the test case we want to enable (we need to enable the parent suites and their dependencies only) // the parent_id needs to be enabled in order to be properly parsed by finalize_run_status, the visit // does the job test_unit& tu_parent = framework::get( parent_id, TUT_ANY ); enabler.visit( tu_parent ); parent_id = tu_parent.p_parent_id; } } // 40. Apply all disablers while( !tu_to_disable.empty() ) { test_unit const& tu = framework::get( tu_to_disable.back(), TUT_ANY ); tu_to_disable.pop_back(); // 35. Ignore test units which already disabled if( !tu.is_enabled() ) continue; set_run_status disabler( test_unit::RS_DISABLED ); traverse_test_tree( tu.p_id, disabler, true ); } // 50. Make sure parents of enabled test units are also enabled finalize_run_status( master_tu_id ); } ////////////////////////////////////////////////////////////////// typedef unit_test_monitor_t::error_level execution_result; // Random generator using the std::rand function (seeded prior to the call) struct random_generator_helper { size_t operator()(size_t i) const { return std::rand() % i; } }; // Executes the test tree with the root at specified test unit execution_result execute_test_tree( test_unit_id tu_id, unsigned long int timeout_microseconds = 0, random_generator_helper const * const p_random_generator = 0) { test_unit const& tu = framework::get( tu_id, TUT_ANY ); execution_result result = unit_test_monitor_t::test_ok; if( !tu.is_enabled() ) return result; // 10. Check preconditions, including zero time left for execution and // successful execution of all dependencies if( timeout_microseconds == TIMEOUT_EXCEEDED ) { // notify all observers about skipped test unit BOOST_TEST_FOREACH( test_observer*, to, m_observers ) to->test_unit_skipped( tu, "timeout for the test unit is exceeded" ); return unit_test_monitor_t::os_timeout; } else if( timeout_microseconds == 0 || (tu.p_timeout > 0 && timeout_microseconds > (tu.p_timeout * 1000000) ) ) // deduce timeout for this test unit timeout_microseconds = tu.p_timeout * 1000000; test_tools::assertion_result const precondition_res = tu.check_preconditions(); if( !precondition_res ) { // notify all observers about skipped test unit BOOST_TEST_FOREACH( test_observer*, to, m_observers ) to->test_unit_skipped( tu, precondition_res.message() ); // It is not an error to skip the test if any of the parent tests // have failed. This one should be reported as skipped as if it was // disabled return unit_test_monitor_t::test_ok; } // 20. Notify all observers about the start of the test unit BOOST_TEST_FOREACH( test_observer*, to, m_observers ) to->test_unit_start( tu ); // 30. Execute setup fixtures if any; any failure here leads to test unit abortion BOOST_TEST_FOREACH( test_unit_fixture_ptr, F, tu.p_fixtures.get() ) { ut_detail::test_unit_id_restore restore_current_test_unit(m_curr_test_unit, tu.p_id); result = unit_test_monitor.execute_and_translate( boost::bind( &test_unit_fixture::setup, F ) ); if( result != unit_test_monitor_t::test_ok ) break; test_results const& test_rslt = unit_test::results_collector.results( m_curr_test_unit ); if( test_rslt.aborted() ) { result = unit_test_monitor_t::test_setup_failure; break; } } // This is the time we are going to spend executing the test unit (in microseconds // as expected by test_observer::test_unit_finish) unsigned long elapsed_microseconds = 0; if( result == unit_test_monitor_t::test_ok ) { // 40. We are going to time the execution boost::unit_test::timer::timer tu_timer; // we pass the random generator const random_generator_helper& rand_gen = p_random_generator ? *p_random_generator : random_generator_helper(); if( tu.p_type == TUT_SUITE ) { test_suite const& ts = static_cast( tu ); if( runtime_config::get( runtime_config::btrt_random_seed ) == 0 ) { typedef std::pair value_type; BOOST_TEST_FOREACH( value_type, chld, ts.m_ranked_children ) { // tu_timer.elapsed() returns nanosec, timeout and child_timeout in microsec unsigned long int chld_timeout = child_timeout( timeout_microseconds, static_cast( microsecond_wall_time(tu_timer.elapsed()) )); result = (std::min)( result, execute_test_tree( chld.second, chld_timeout, &rand_gen ) ); if( unit_test_monitor.is_critical_error( result ) ) break; // we check for the time elapsed. If this is too high, we fail the current suite and return from here elapsed_microseconds = static_cast( microsecond_wall_time(tu_timer.elapsed()) ); if( (timeout_microseconds > 0) && (elapsed_microseconds > timeout_microseconds) && (timeout_microseconds != TIMEOUT_EXCEEDED ) ) { BOOST_TEST_FOREACH( test_observer*, to, m_observers ) { to->test_unit_timed_out(tu); } result = (std::min)( result, unit_test_monitor_t::os_timeout ); timeout_microseconds = TIMEOUT_EXCEEDED; //break; // we continue to explore the children, such that we can at least update their // status to skipped } } } else { // Go through ranges of children with the same dependency rank and shuffle them // independently. Execute each subtree in this order test_unit_id_list children_with_the_same_rank; typedef test_suite::children_per_rank::const_iterator it_type; it_type it = ts.m_ranked_children.begin(); while( it != ts.m_ranked_children.end() ) { children_with_the_same_rank.clear(); std::pair range = ts.m_ranked_children.equal_range( it->first ); it = range.first; while( it != range.second ) { children_with_the_same_rank.push_back( it->second ); it++; } #ifdef BOOST_NO_CXX98_RANDOM_SHUFFLE impl::random_shuffle( children_with_the_same_rank.begin(), children_with_the_same_rank.end(), rand_gen ); #else std::random_shuffle( children_with_the_same_rank.begin(), children_with_the_same_rank.end(), rand_gen ); #endif BOOST_TEST_FOREACH( test_unit_id, chld, children_with_the_same_rank ) { unsigned long int chld_timeout = child_timeout( timeout_microseconds, static_cast(microsecond_wall_time(tu_timer.elapsed())) ); result = (std::min)( result, execute_test_tree( chld, chld_timeout, &rand_gen ) ); if( unit_test_monitor.is_critical_error( result ) ) break; // we check for the time elapsed. If this is too high, we fail the current suite and return from here elapsed_microseconds = static_cast( microsecond_wall_time(tu_timer.elapsed()) ); if( (timeout_microseconds > 0) && (elapsed_microseconds > timeout_microseconds) && (timeout_microseconds != TIMEOUT_EXCEEDED ) ) { BOOST_TEST_FOREACH( test_observer*, to, m_observers ) { to->test_unit_timed_out(tu); } result = (std::min)( result, unit_test_monitor_t::os_timeout ); timeout_microseconds = TIMEOUT_EXCEEDED; //break; // we continue to explore the children, such that we can at least update their // status to skipped } } } } } else { // TUT_CASE test_case const& tc = static_cast( tu ); // setup contexts m_context_idx = 0; // setup current test case ut_detail::test_unit_id_restore restore_current_test_unit(m_curr_test_unit, tc.p_id); // execute the test case body, transforms the time out to seconds result = unit_test_monitor.execute_and_translate( tc.p_test_func, timeout_microseconds ); elapsed_microseconds = static_cast( microsecond_wall_time(tu_timer.elapsed()) ); // cleanup leftover context m_context.clear(); // restore state (scope exit) and abort if necessary } } // if run error is critical skip teardown, who knows what the state of the program at this point if( !unit_test_monitor.is_critical_error( result ) ) { // execute teardown fixtures if any in reverse order BOOST_TEST_REVERSE_FOREACH( test_unit_fixture_ptr, F, tu.p_fixtures.get() ) { ut_detail::test_unit_id_restore restore_current_test_unit(m_curr_test_unit, tu.p_id); result = (std::min)( result, unit_test_monitor.execute_and_translate( boost::bind( &test_unit_fixture::teardown, F ), 0 ) ); if( unit_test_monitor.is_critical_error( result ) ) break; } } // notify all observers about abortion if( unit_test_monitor.is_critical_error( result ) ) { BOOST_TEST_FOREACH( test_observer*, to, m_observers ) to->test_aborted(); } // notify all observers about completion BOOST_TEST_REVERSE_FOREACH( test_observer*, to, m_observers ) to->test_unit_finish( tu, elapsed_microseconds ); return result; } ////////////////////////////////////////////////////////////////// unsigned long int child_timeout( unsigned long tu_timeout_microseconds, unsigned long elpsed_microsec ) { if( tu_timeout_microseconds == 0UL || tu_timeout_microseconds == TIMEOUT_EXCEEDED) return tu_timeout_microseconds; return tu_timeout_microseconds > elpsed_microsec ? tu_timeout_microseconds - elpsed_microsec : TIMEOUT_EXCEEDED; } struct priority_order { bool operator()( test_observer* lhs, test_observer* rhs ) const { return (lhs->priority() < rhs->priority()) || ((lhs->priority() == rhs->priority()) && (lhs < rhs)); } }; // Data members typedef std::map test_unit_store; typedef std::set observer_store; struct context_frame { context_frame( std::string const& d, int id, bool sticky ) : descr( d ) , frame_id( id ) , is_sticky( sticky ) {} std::string descr; int frame_id; bool is_sticky; }; typedef std::vector context_data; master_test_suite_t* m_master_test_suite; std::vector m_auto_test_suites; test_unit_id m_curr_test_unit; test_unit_store m_test_units; test_unit_id m_next_test_case_id; test_unit_id m_next_test_suite_id; bool m_test_in_progress; observer_store m_observers; context_data m_context; int m_context_idx; std::set m_global_fixtures; boost::execution_monitor m_aux_em; std::map m_log_sinks; runtime_config::stream_holder m_report_sink; }; //____________________________________________________________________________// namespace impl { namespace { #if defined(__CYGWIN__) framework::state& s_frk_state() { static framework::state* the_inst = 0; if(!the_inst) the_inst = new framework::state; return *the_inst; } #else framework::state& s_frk_state() { static framework::state the_inst; return the_inst; } #endif } // local namespace void setup_for_execution( test_unit const& tu ) { s_frk_state().deduce_run_status( tu.p_id ); } struct sum_to_first_only { sum_to_first_only() : is_first(true) {} template T operator()(T const& l_, U const& r_) { if(is_first) { is_first = false; return l_ + r_.first; } return l_ + ", " + r_.first; } bool is_first; }; void shutdown_loggers_and_reports() { s_frk_state().m_log_sinks.clear(); s_frk_state().m_report_sink.setup( "stderr" ); } void unregister_global_fixture_and_configuration() { // we make a copy as the set will change in the iteration std::set gfixture_copy(s_frk_state().m_global_fixtures); BOOST_TEST_FOREACH( global_fixture*, tuf, gfixture_copy ) { tuf->unregister_from_framework(); } s_frk_state().m_global_fixtures.clear(); state::observer_store gobserver_copy(s_frk_state().m_observers); BOOST_TEST_FOREACH( test_observer*, to, gobserver_copy ) { framework::deregister_observer( *to ); } s_frk_state().m_observers.clear(); } void setup_loggers() { BOOST_TEST_I_TRY { #ifdef BOOST_TEST_SUPPORT_TOKEN_ITERATOR bool has_combined_logger = runtime_config::has( runtime_config::btrt_combined_logger ) && !runtime_config::get< std::vector >( runtime_config::btrt_combined_logger ).empty(); #else bool has_combined_logger = false; #endif if( !has_combined_logger ) { unit_test_log.set_threshold_level( runtime_config::get( runtime_config::btrt_log_level ) ); const output_format format = runtime_config::get( runtime_config::btrt_log_format ); unit_test_log.set_format( format ); runtime_config::stream_holder& stream_logger = s_frk_state().m_log_sinks[format]; if( runtime_config::has( runtime_config::btrt_log_sink ) ) { // we remove all streams in this case, so we do not specify the format boost::function< void () > log_cleaner = boost::bind( &unit_test_log_t::set_stream, &unit_test_log, boost::ref(std::cout) ); stream_logger.setup( runtime_config::get( runtime_config::btrt_log_sink ), log_cleaner ); } unit_test_log.set_stream( stream_logger.ref() ); } else { const std::vector& v_output_format = runtime_config::get< std::vector >( runtime_config::btrt_combined_logger ) ; static const std::pair all_log_levels[] = { std::make_pair( "all" , log_successful_tests ), std::make_pair( "success" , log_successful_tests ), std::make_pair( "test_suite" , log_test_units ), std::make_pair( "unit_scope" , log_test_units ), std::make_pair( "message" , log_messages ), std::make_pair( "warning" , log_warnings ), std::make_pair( "error" , log_all_errors ), std::make_pair( "cpp_exception" , log_cpp_exception_errors ), std::make_pair( "system_error" , log_system_errors ), std::make_pair( "fatal_error" , log_fatal_errors ), std::make_pair( "nothing" , log_nothing ) }; static const std::pair all_formats[] = { std::make_pair( "HRF" , OF_CLF ), std::make_pair( "CLF" , OF_CLF ), std::make_pair( "XML" , OF_XML ), std::make_pair( "JUNIT", OF_JUNIT ) }; bool is_first = true; BOOST_TEST_FOREACH( const_string, current_multi_config, v_output_format ) { #ifdef BOOST_TEST_SUPPORT_TOKEN_ITERATOR // ':' may be used for file names: C:/tmp/mylogsink.xml // we merge the tokens that start with / or \ with the previous one. std::vector v_processed_tokens; { utils::string_token_iterator current_config( current_multi_config, (utils::dropped_delimeters = ":", utils::kept_delimeters = utils::dt_none) ); for( ; current_config != utils::string_token_iterator() ; ++current_config) { std::string str_copy(current_config->begin(), current_config->end()); if( ( str_copy[0] == '\\' || str_copy[0] == '/' ) && v_processed_tokens.size() > 0) { v_processed_tokens.back() += ":" + str_copy; // ':' has been eaten up } else { v_processed_tokens.push_back(str_copy); } } } BOOST_TEST_FOREACH( std::string const&, current_config, v_processed_tokens ) { utils::string_token_iterator current_format_specs( current_config, (utils::keep_empty_tokens, utils::dropped_delimeters = ",", utils::kept_delimeters = utils::dt_none) ); output_format format = OF_INVALID ; // default if( current_format_specs != utils::string_token_iterator() && current_format_specs->size() ) { for(size_t elem=0; elem < sizeof(all_formats)/sizeof(all_formats[0]); elem++) { if(const_string(all_formats[elem].first) == *current_format_specs) { format = all_formats[elem].second; break; } } } BOOST_TEST_I_ASSRT( format != OF_INVALID, boost::runtime::access_to_missing_argument() << "Unable to determine the logger type from '" << current_config << "'. Possible choices are: " << std::accumulate(all_formats, all_formats + sizeof(all_formats)/sizeof(all_formats[0]), std::string(""), sum_to_first_only()) ); // activates this format if( is_first ) { unit_test_log.set_format( format ); } else { unit_test_log.add_format( format ); } is_first = false; unit_test_log_formatter * const formatter = unit_test_log.get_formatter(format); BOOST_TEST_SETUP_ASSERT( formatter, "Logger setup error" ); log_level formatter_log_level = invalid_log_level; ++current_format_specs ; if( !current_format_specs->size() ) { formatter_log_level = formatter->get_log_level(); // default log level given by the formatter } else if( current_format_specs != utils::string_token_iterator() ) { for(size_t elem=0; elem < sizeof(all_log_levels)/sizeof(all_log_levels[0]); elem++) { if(const_string(all_log_levels[elem].first) == *current_format_specs) { formatter_log_level = all_log_levels[elem].second; break; } } } BOOST_TEST_I_ASSRT( formatter_log_level != invalid_log_level, boost::runtime::access_to_missing_argument() << "Unable to determine the log level from '" << current_config << "'. Possible choices are: " << std::accumulate(all_log_levels, all_log_levels + sizeof(all_log_levels)/sizeof(all_log_levels[0]), std::string(""), sum_to_first_only()) ); unit_test_log.set_threshold_level( format, formatter_log_level ); runtime_config::stream_holder& stream_logger = s_frk_state().m_log_sinks[format]; boost::function< void () > log_cleaner = boost::bind( &unit_test_log_t::set_stream, &unit_test_log, format, boost::ref(std::cout) ); if( ++current_format_specs != utils::string_token_iterator() && current_format_specs->size() ) { stream_logger.setup( *current_format_specs, log_cleaner ); } else { stream_logger.setup( formatter->get_default_stream_description(), log_cleaner ); } unit_test_log.set_stream( format, stream_logger.ref() ); } #endif } // for each logger } // if/else new logger API } // BOOST_TEST_I_TRY BOOST_TEST_I_CATCH( boost::runtime::init_error, ex ) { BOOST_TEST_SETUP_ASSERT( false, ex.msg ); } BOOST_TEST_I_CATCH( boost::runtime::input_error, ex ) { std::cerr << ex.msg << "\n\n"; BOOST_TEST_I_THROW( framework::nothing_to_test( boost::exit_exception_failure ) ); } } //____________________________________________________________________________// } // namespace impl //____________________________________________________________________________// // ************************************************************************** // // ************** framework::init ************** // // ************************************************************************** // void init( init_unit_test_func init_func, int argc, char* argv[] ) { using namespace impl; // 10. Set up runtime parameters runtime_config::init( argc, argv ); // 20. Set the desired log level, format and sink impl::setup_loggers(); // 30. Set the desired report level, format and sink results_reporter::set_level( runtime_config::get( runtime_config::btrt_report_level ) ); results_reporter::set_format( runtime_config::get( runtime_config::btrt_report_format ) ); if( runtime_config::has( runtime_config::btrt_report_sink ) ) { boost::function< void () > report_cleaner = boost::bind( &results_reporter::set_stream, boost::ref(std::cerr) ); s_frk_state().m_report_sink.setup( runtime_config::get( runtime_config::btrt_report_sink ), report_cleaner ); } results_reporter::set_stream( s_frk_state().m_report_sink.ref() ); // 40. Register default test observers register_observer( results_collector ); register_observer( unit_test_log ); register_observer( framework_init_observer ); if( runtime_config::get( runtime_config::btrt_show_progress ) ) { progress_monitor.set_stream( std::cout ); // defaults to stdout register_observer( progress_monitor ); } // 50. Set up memory leak detection unsigned long detect_mem_leak = runtime_config::get( runtime_config::btrt_detect_mem_leaks ); if( detect_mem_leak > 0 ) { debug::detect_memory_leaks( true, runtime_config::get( runtime_config::btrt_report_mem_leaks ) ); debug::break_memory_alloc( (long)detect_mem_leak ); } // 60. Initialize master unit test suite master_test_suite().argc = argc; master_test_suite().argv = argv; // 70. Invoke test module initialization routine BOOST_TEST_I_TRY { s_frk_state().m_aux_em.vexecute( boost::bind( &impl::invoke_init_func, init_func ) ); } BOOST_TEST_I_CATCH( execution_exception, ex ) { BOOST_TEST_SETUP_ASSERT( false, ex.what() ); } } //____________________________________________________________________________// void finalize_setup_phase( test_unit_id master_tu_id ) { if( master_tu_id == INV_TEST_UNIT_ID ) master_tu_id = master_test_suite().p_id; // 10. Apply all decorators to the auto test units // 10. checks for consistency (duplicate names, etc) class apply_decorators : public test_tree_visitor { private: // test_tree_visitor interface virtual bool test_suite_start( test_suite const& ts) { const_cast(ts).generate(); const_cast(ts).check_for_duplicate_test_cases(); return test_tree_visitor::test_suite_start(ts); } virtual bool visit( test_unit const& tu ) { BOOST_TEST_FOREACH( decorator::base_ptr, d, tu.p_decorators.get() ) d->apply( const_cast(tu) ); return true; } } ad; traverse_test_tree( master_tu_id, ad, true ); // 20. Finalize setup phase impl::order_info_per_tu tuoi; impl::s_frk_state().deduce_siblings_order( master_tu_id, master_tu_id, tuoi ); impl::s_frk_state().finalize_default_run_status( master_tu_id, test_unit::RS_INVALID ); } // ************************************************************************** // // ************** test_in_progress ************** // // ************************************************************************** // bool test_in_progress() { return impl::s_frk_state().m_test_in_progress; } //____________________________________________________________________________// // ************************************************************************** // // ************** framework::shutdown ************** // // ************************************************************************** // void shutdown() { // shuts down the loggers singleton to avoid any further reference to the // framework during the destruction of those impl::shutdown_loggers_and_reports(); // unregisters any global fixture and configuration object impl::unregister_global_fixture_and_configuration(); // eliminating some fake memory leak reports. See for more details: // http://connect.microsoft.com/VisualStudio/feedback/details/106937/memory-leaks-reported-by-debug-crt-inside-typeinfo-name # if BOOST_WORKAROUND(BOOST_MSVC, <= 1600 ) && !defined(_DLL) && defined(_DEBUG) # if BOOST_WORKAROUND(BOOST_MSVC, < 1600 ) #define _Next next #define _MemPtr memPtr #endif __type_info_node* pNode = __type_info_root_node._Next; __type_info_node* tmpNode = &__type_info_root_node; for( ; pNode!=NULL; pNode = tmpNode ) { tmpNode = pNode->_Next; delete pNode->_MemPtr; delete pNode; } # if BOOST_WORKAROUND(BOOST_MSVC, < 1600 ) #undef _Next #undef _MemPtr #endif # endif } //____________________________________________________________________________// // ************************************************************************** // // ************** register_test_unit ************** // // ************************************************************************** // void register_test_unit( test_case* tc ) { BOOST_TEST_SETUP_ASSERT( tc->p_id == INV_TEST_UNIT_ID, BOOST_TEST_L( "test case already registered" ) ); test_unit_id new_id = impl::s_frk_state().m_next_test_case_id; BOOST_TEST_SETUP_ASSERT( new_id != MAX_TEST_CASE_ID, BOOST_TEST_L( "too many test cases" ) ); typedef state::test_unit_store::value_type map_value_type; impl::s_frk_state().m_test_units.insert( map_value_type( new_id, tc ) ); impl::s_frk_state().m_next_test_case_id++; impl::s_frk_state().set_tu_id( *tc, new_id ); } //____________________________________________________________________________// // ************************************************************************** // // ************** register_test_unit ************** // // ************************************************************************** // void register_test_unit( test_suite* ts ) { BOOST_TEST_SETUP_ASSERT( ts->p_id == INV_TEST_UNIT_ID, BOOST_TEST_L( "test suite already registered" ) ); test_unit_id new_id = impl::s_frk_state().m_next_test_suite_id; BOOST_TEST_SETUP_ASSERT( new_id != MAX_TEST_SUITE_ID, BOOST_TEST_L( "too many test suites" ) ); typedef state::test_unit_store::value_type map_value_type; impl::s_frk_state().m_test_units.insert( map_value_type( new_id, ts ) ); impl::s_frk_state().m_next_test_suite_id++; impl::s_frk_state().set_tu_id( *ts, new_id ); } //____________________________________________________________________________// // ************************************************************************** // // ************** deregister_test_unit ************** // // ************************************************************************** // void deregister_test_unit( test_unit* tu ) { impl::s_frk_state().m_test_units.erase( tu->p_id ); } //____________________________________________________________________________// // ************************************************************************** // // ************** clear ************** // // ************************************************************************** // void clear() { impl::s_frk_state().clear(); } //____________________________________________________________________________// // ************************************************************************** // // ************** register_observer ************** // // ************************************************************************** // void register_observer( test_observer& to ) { impl::s_frk_state().m_observers.insert( &to ); } //____________________________________________________________________________// // ************************************************************************** // // ************** deregister_observer ************** // // ************************************************************************** // void deregister_observer( test_observer& to ) { impl::s_frk_state().m_observers.erase( &to ); } //____________________________________________________________________________// // ************************************************************************** // // ************** register_global_fixture ************** // // ************************************************************************** // void register_global_fixture( global_fixture& tuf ) { impl::s_frk_state().m_global_fixtures.insert( &tuf ); } //____________________________________________________________________________// // ************************************************************************** // // ************** deregister_global_fixture ************** // // ************************************************************************** // void deregister_global_fixture( global_fixture &tuf ) { impl::s_frk_state().m_global_fixtures.erase( &tuf ); } //____________________________________________________________________________// // ************************************************************************** // // ************** add_context ************** // // ************************************************************************** // int add_context( ::boost::unit_test::lazy_ostream const& context_descr, bool sticky ) { std::stringstream buffer; context_descr( buffer ); int res_idx = impl::s_frk_state().m_context_idx++; impl::s_frk_state().m_context.push_back( state::context_frame( buffer.str(), res_idx, sticky ) ); return res_idx; } //____________________________________________________________________________// // ************************************************************************** // // ************** clear_context ************** // // ************************************************************************** // struct frame_with_id { explicit frame_with_id( int id ) : m_id( id ) {} bool operator()( state::context_frame const& f ) { return f.frame_id == m_id; } int m_id; }; //____________________________________________________________________________// void clear_context( int frame_id ) { if( frame_id == -1 ) { // clear all non sticky frames for( int i=static_cast(impl::s_frk_state().m_context.size())-1; i>=0; i-- ) if( !impl::s_frk_state().m_context[i].is_sticky ) impl::s_frk_state().m_context.erase( impl::s_frk_state().m_context.begin()+i ); } else { // clear specific frame state::context_data::iterator it = std::find_if( impl::s_frk_state().m_context.begin(), impl::s_frk_state().m_context.end(), frame_with_id( frame_id ) ); if( it != impl::s_frk_state().m_context.end() ) // really an internal error if this is not true impl::s_frk_state().m_context.erase( it ); } } //____________________________________________________________________________// // ************************************************************************** // // ************** get_context ************** // // ************************************************************************** // context_generator get_context() { return context_generator(); } //____________________________________________________________________________// // ************************************************************************** // // ************** context_generator ************** // // ************************************************************************** // bool context_generator::is_empty() const { return impl::s_frk_state().m_context.empty(); } //____________________________________________________________________________// const_string context_generator::next() const { return m_curr_frame < impl::s_frk_state().m_context.size() ? impl::s_frk_state().m_context[m_curr_frame++].descr : const_string(); } //____________________________________________________________________________// // ************************************************************************** // // ************** master_test_suite ************** // // ************************************************************************** // master_test_suite_t& master_test_suite() { if( !impl::s_frk_state().m_master_test_suite ) impl::s_frk_state().m_master_test_suite = new master_test_suite_t; return *impl::s_frk_state().m_master_test_suite; } namespace impl { master_test_suite_name_setter::master_test_suite_name_setter(const_string name) { assign_op( master_test_suite().p_name.value, name.trim( "\"" ), 0 ); } } //____________________________________________________________________________// // ************************************************************************** // // ************** current_auto_test_suite ************** // // ************************************************************************** // test_suite& current_auto_test_suite( test_suite* ts, bool push_or_pop ) { if( impl::s_frk_state().m_auto_test_suites.empty() ) impl::s_frk_state().m_auto_test_suites.push_back( &framework::master_test_suite() ); if( !push_or_pop ) impl::s_frk_state().m_auto_test_suites.pop_back(); else if( ts ) impl::s_frk_state().m_auto_test_suites.push_back( ts ); return *impl::s_frk_state().m_auto_test_suites.back(); } //____________________________________________________________________________// // ************************************************************************** // // ************** current_test_case ************** // // ************************************************************************** // test_case const& current_test_case() { return get( impl::s_frk_state().m_curr_test_unit ); } test_unit const& current_test_unit() { return *impl::s_frk_state().m_test_units[impl::s_frk_state().m_curr_test_unit]; } //____________________________________________________________________________// test_unit_id current_test_case_id() { return impl::s_frk_state().m_curr_test_unit; } //____________________________________________________________________________// // ************************************************************************** // // ************** framework::get ************** // // ************************************************************************** // test_unit& get( test_unit_id id, test_unit_type t ) { test_unit* res = impl::s_frk_state().m_test_units[id]; BOOST_TEST_I_ASSRT( (res->p_type & t) != 0, internal_error( "Invalid test unit type" ) ); return *res; } //____________________________________________________________________________// // ************************************************************************** // // ************** framework::run ************** // // ************************************************************************** // template struct swap_on_delete { swap_on_delete(Cont& c1, Cont& c2) : m_c1(c1), m_c2(c2){} ~swap_on_delete() { m_c1.swap(m_c2); } Cont& m_c1; Cont& m_c2; }; void run( test_unit_id id, bool continue_test ) { if( id == INV_TEST_UNIT_ID ) id = master_test_suite().p_id; // Figure out run status for execution phase impl::s_frk_state().deduce_run_status( id ); test_case_counter tcc; traverse_test_tree( id, tcc ); BOOST_TEST_SETUP_ASSERT( tcc.p_count != 0 , runtime_config::get >( runtime_config::btrt_run_filters ).empty() ? BOOST_TEST_L( "test tree is empty" ) : BOOST_TEST_L( "no test cases matching filter or all test cases were disabled" ) ); bool was_in_progress = framework::test_in_progress(); bool call_start_finish = !continue_test || !was_in_progress; bool init_ok = true; const_string setup_error; if( call_start_finish ) { // indicates the framework that no test is in progress now if observers need to be notified impl::s_frk_state().m_test_in_progress = false; // unit_test::framework_init_observer will get cleared first BOOST_TEST_FOREACH( test_observer*, to, impl::s_frk_state().m_observers ) { BOOST_TEST_I_TRY { ut_detail::test_unit_id_restore restore_current_test_unit(impl::s_frk_state().m_curr_test_unit, id); unit_test_monitor_t::error_level result = unit_test_monitor.execute_and_translate( boost::bind( &test_observer::test_start, to, tcc.p_count ) ); if( init_ok ) { if( result != unit_test_monitor_t::test_ok ) { init_ok = false; } else { if( unit_test::framework_init_observer.has_failed() ) { init_ok = false; } } } } BOOST_TEST_I_CATCH( execution_exception, ex ) { if( init_ok ) { // log only the first error init_ok = false; setup_error = ex.what(); } // break; // we should continue otherwise loggers may have improper structure (XML start missing for instance) } } } if( init_ok ) { // attaching the global fixtures to the main entry point test_unit& entry_test_unit = framework::get( id, TUT_ANY ); std::vector v_saved_fixture(entry_test_unit.p_fixtures.value.begin(), entry_test_unit.p_fixtures.value.end()); BOOST_TEST_FOREACH( test_unit_fixture*, tuf, impl::s_frk_state().m_global_fixtures ) { entry_test_unit.p_fixtures.value.insert( entry_test_unit.p_fixtures.value.begin(), test_unit_fixture_ptr(new impl::global_fixture_handle(tuf)) ); } swap_on_delete< std::vector > raii_fixture(v_saved_fixture, entry_test_unit.p_fixtures.value); // now work in progress impl::s_frk_state().m_test_in_progress = true; unsigned seed = runtime_config::get( runtime_config::btrt_random_seed ); switch( seed ) { case 0: break; case 1: seed = static_cast( std::rand() ^ std::time( 0 ) ); // better init using std::rand() ^ ... BOOST_FALLTHROUGH; default: BOOST_TEST_FRAMEWORK_MESSAGE( "Test cases order is shuffled using seed: " << seed ); std::srand( seed ); } // executing the test tree impl::s_frk_state().execute_test_tree( id ); // removing previously added global fixtures: dtor raii_fixture } impl::s_frk_state().m_test_in_progress = false; results_reporter::make_report( INV_REPORT_LEVEL, id ); unit_test::framework_init_observer.clear(); if( call_start_finish ) { // indicates the framework that no test is in progress anymore if observers need to be notified // and this is a teardown, so assertions should not raise any exception otherwise an exception // might be raised in a dtor of a global fixture impl::s_frk_state().m_test_in_progress = false; BOOST_TEST_REVERSE_FOREACH( test_observer*, to, impl::s_frk_state().m_observers ) { ut_detail::test_unit_id_restore restore_current_test_unit(impl::s_frk_state().m_curr_test_unit, id); to->test_finish(); } } impl::s_frk_state().m_test_in_progress = was_in_progress; // propagates the init/teardown error if any BOOST_TEST_SETUP_ASSERT( init_ok && !unit_test::framework_init_observer.has_failed(), setup_error ); } //____________________________________________________________________________// void run( test_unit const* tu, bool continue_test ) { run( tu->p_id, continue_test ); } //____________________________________________________________________________// // ************************************************************************** // // ************** assertion_result ************** // // ************************************************************************** // void assertion_result( unit_test::assertion_result ar ) { BOOST_TEST_FOREACH( test_observer*, to, impl::s_frk_state().m_observers ) to->assertion_result( ar ); } //____________________________________________________________________________// // ************************************************************************** // // ************** exception_caught ************** // // ************************************************************************** // void exception_caught( execution_exception const& ex ) { BOOST_TEST_FOREACH( test_observer*, to, impl::s_frk_state().m_observers ) to->exception_caught( ex ); } //____________________________________________________________________________// // ************************************************************************** // // ************** test_unit_aborted ************** // // ************************************************************************** // void test_unit_aborted( test_unit const& tu ) { BOOST_TEST_FOREACH( test_observer*, to, impl::s_frk_state().m_observers ) to->test_unit_aborted( tu ); } // ************************************************************************** // // ************** test_aborted ************** // // ************************************************************************** // void test_aborted( ) { BOOST_TEST_FOREACH( test_observer*, to, impl::s_frk_state().m_observers ) to->test_aborted( ); } //____________________________________________________________________________// } // namespace framework } // namespace unit_test } // namespace boost #include #endif // BOOST_TEST_FRAMEWORK_IPP_021005GER