PrusaSlicer-NonPlainar/xs/include/boost/test/impl/exception_safety.ipp

538 lines
17 KiB
C++

// (C) Copyright Gennadiy Rozental 2005-2008.
// Use, modification, and distribution are subject to the
// Boost Software License, Version 1.0. (See accompanying file
// http://www.boost.org/LICENSE_1_0.txt)
// See http://www.boost.org/libs/test for the library home page.
//
// File : $RCSfile$
//
// Version : $Revision: 54633 $
//
// Description : Facilities to perform exception safety tests
// ***************************************************************************
#ifndef BOOST_TEST_EXECUTION_SAFETY_IPP_112005GER
#define BOOST_TEST_EXECUTION_SAFETY_IPP_112005GER
// Boost.Test
#include <boost/test/detail/config.hpp>
#if BOOST_TEST_SUPPORT_INTERACTION_TESTING
#include <boost/test/detail/global_typedef.hpp>
#include <boost/test/detail/unit_test_parameters.hpp>
#include <boost/test/utils/callback.hpp>
#include <boost/test/utils/wrap_stringstream.hpp>
#include <boost/test/utils/iterator/token_iterator.hpp>
#include <boost/test/interaction_based.hpp>
#include <boost/test/test_tools.hpp>
#include <boost/test/unit_test_log.hpp>
#include <boost/test/framework.hpp>
#include <boost/test/test_observer.hpp>
#include <boost/test/debug.hpp>
#include <boost/test/detail/suppress_warnings.hpp>
// Boost
#include <boost/lexical_cast.hpp>
// STL
#include <vector>
#include <cstdlib>
#include <map>
#include <iomanip>
#include <cctype>
#include <boost/limits.hpp>
//____________________________________________________________________________//
namespace boost {
using namespace ::boost::unit_test;
namespace itest {
// ************************************************************************** //
// ************** execution_path_point ************** //
// ************************************************************************** //
enum exec_path_point_type { EPP_SCOPE, EPP_EXCEPT, EPP_DECISION, EPP_ALLOC };
struct execution_path_point {
execution_path_point( exec_path_point_type t, const_string file, std::size_t line_num )
: m_type( t )
, m_file_name( file )
, m_line_num( line_num )
{}
exec_path_point_type m_type;
const_string m_file_name;
std::size_t m_line_num;
// Execution path point specific
struct decision_data {
bool value;
unsigned forced_exception_point;
};
struct scope_data {
unsigned size;
char const* name;
};
struct except_data {
char const* description;
};
struct alloc_data {
void* ptr;
std::size_t size;
};
union {
struct decision_data m_decision;
struct scope_data m_scope;
struct except_data m_except;
struct alloc_data m_alloc;
};
};
// ************************************************************************** //
// ************** exception safety test implementation ************** //
// ************************************************************************** //
struct exception_safety_tester : itest::manager, test_observer {
// helpers types
struct unique_exception {};
// Constructor
explicit exception_safety_tester( const_string test_name );
~exception_safety_tester();
// check last run and prepare for next
bool next_execution_path();
// memory tracking
// manager interface implementation
virtual void exception_point( const_string file, std::size_t line_num, const_string description );
virtual bool decision_point( const_string file, std::size_t line_num );
virtual unsigned enter_scope( const_string file, std::size_t line_num, const_string scope_name );
virtual void leave_scope( unsigned enter_scope_point );
virtual void allocated( const_string file, std::size_t line_num, void* p, std::size_t s );
virtual void freed( void* p );
// test observer interface
virtual void assertion_result( bool passed );
virtual int priority() { return (std::numeric_limits<int>::max)(); } // we want this observer to run the last
private:
void failure_point();
void report_error();
typedef std::vector<execution_path_point> exec_path;
typedef std::map<void*,unsigned> registry;
// Data members
bool m_internal_activity;
unsigned m_exception_point_counter;
unsigned m_forced_exception_point;
unsigned m_exec_path_point;
exec_path m_execution_path;
unsigned m_exec_path_counter;
unsigned m_break_exec_path;
bool m_invairant_failed;
registry m_memory_in_use;
};
//____________________________________________________________________________//
struct activity_guard {
bool& m_v;
activity_guard( bool& v ) : m_v( v ) { m_v = true; }
~activity_guard() { m_v = false; }
};
//____________________________________________________________________________//
exception_safety_tester::exception_safety_tester( const_string test_name )
: m_internal_activity( true )
, m_exception_point_counter( 0 )
, m_forced_exception_point( 1 )
, m_exec_path_point( 0 )
, m_exec_path_counter( 1 )
, m_break_exec_path( static_cast<unsigned>(-1) )
, m_invairant_failed( false )
{
framework::register_observer( *this );
if( !runtime_config::break_exec_path().is_empty() ) {
using namespace unit_test;
string_token_iterator tit( runtime_config::break_exec_path(),
(dropped_delimeters = ":",kept_delimeters = " ") );
const_string test_to_break = *tit;
if( test_to_break == test_name ) {
++tit;
m_break_exec_path = lexical_cast<unsigned>( *tit );
}
}
m_internal_activity = false;
}
//____________________________________________________________________________//
exception_safety_tester::~exception_safety_tester()
{
m_internal_activity = true;
framework::deregister_observer( *this );
}
//____________________________________________________________________________//
bool
exception_safety_tester::next_execution_path()
{
activity_guard ag( m_internal_activity );
// check memory usage
if( m_execution_path.size() > 0 ) {
bool errors_detected = m_invairant_failed || (m_memory_in_use.size() != 0);
framework::assertion_result( !errors_detected );
if( errors_detected )
report_error();
m_memory_in_use.clear();
}
m_exec_path_point = 0;
m_exception_point_counter = 0;
m_invairant_failed = false;
++m_exec_path_counter;
while( m_execution_path.size() > 0 ) {
switch( m_execution_path.back().m_type ) {
case EPP_SCOPE:
case EPP_ALLOC:
m_execution_path.pop_back();
break;
case EPP_DECISION:
if( !m_execution_path.back().m_decision.value ) {
m_execution_path.pop_back();
break;
}
m_execution_path.back().m_decision.value = false;
m_forced_exception_point = m_execution_path.back().m_decision.forced_exception_point;
return true;
case EPP_EXCEPT:
m_execution_path.pop_back();
++m_forced_exception_point;
return true;
}
}
BOOST_TEST_MESSAGE( "Total tested " << --m_exec_path_counter << " execution path" );
return false;
}
//____________________________________________________________________________//
void
exception_safety_tester::exception_point( const_string file, std::size_t line_num, const_string description )
{
activity_guard ag( m_internal_activity );
if( ++m_exception_point_counter == m_forced_exception_point ) {
m_execution_path.push_back(
execution_path_point( EPP_EXCEPT, file, line_num ) );
m_execution_path.back().m_except.description = description.begin();
++m_exec_path_point;
failure_point();
}
}
//____________________________________________________________________________//
bool
exception_safety_tester::decision_point( const_string file, std::size_t line_num )
{
activity_guard ag( m_internal_activity );
if( m_exec_path_point < m_execution_path.size() ) {
BOOST_REQUIRE_MESSAGE( m_execution_path[m_exec_path_point].m_type == EPP_DECISION &&
m_execution_path[m_exec_path_point].m_file_name == file &&
m_execution_path[m_exec_path_point].m_line_num == line_num,
"Function under test exibit non-deterministic behavior" );
}
else {
m_execution_path.push_back(
execution_path_point( EPP_DECISION, file, line_num ) );
m_execution_path.back().m_decision.value = true;
m_execution_path.back().m_decision.forced_exception_point = m_forced_exception_point;
}
return m_execution_path[m_exec_path_point++].m_decision.value;
}
//____________________________________________________________________________//
unsigned
exception_safety_tester::enter_scope( const_string file, std::size_t line_num, const_string scope_name )
{
activity_guard ag( m_internal_activity );
if( m_exec_path_point < m_execution_path.size() ) {
BOOST_REQUIRE_MESSAGE( m_execution_path[m_exec_path_point].m_type == EPP_SCOPE &&
m_execution_path[m_exec_path_point].m_file_name == file &&
m_execution_path[m_exec_path_point].m_line_num == line_num,
"Function under test exibit non-deterministic behavior" );
}
else {
m_execution_path.push_back(
execution_path_point( EPP_SCOPE, file, line_num ) );
}
m_execution_path[m_exec_path_point].m_scope.size = 0;
m_execution_path[m_exec_path_point].m_scope.name = scope_name.begin();
return m_exec_path_point++;
}
//____________________________________________________________________________//
void
exception_safety_tester::leave_scope( unsigned enter_scope_point )
{
activity_guard ag( m_internal_activity );
BOOST_REQUIRE_MESSAGE( m_execution_path[enter_scope_point].m_type == EPP_SCOPE,
"Function under test exibit non-deterministic behavior" );
m_execution_path[enter_scope_point].m_scope.size = m_exec_path_point - enter_scope_point;
}
//____________________________________________________________________________//
void
exception_safety_tester::allocated( const_string file, std::size_t line_num, void* p, std::size_t s )
{
if( m_internal_activity )
return;
activity_guard ag( m_internal_activity );
if( m_exec_path_point < m_execution_path.size() )
BOOST_REQUIRE_MESSAGE( m_execution_path[m_exec_path_point].m_type == EPP_ALLOC,
"Function under test exibit non-deterministic behavior" );
else
m_execution_path.push_back(
execution_path_point( EPP_ALLOC, file, line_num ) );
m_execution_path[m_exec_path_point].m_alloc.ptr = p;
m_execution_path[m_exec_path_point].m_alloc.size = s;
m_memory_in_use.insert( std::make_pair( p, m_exec_path_point++ ) );
}
//____________________________________________________________________________//
void
exception_safety_tester::freed( void* p )
{
if( m_internal_activity )
return;
activity_guard ag( m_internal_activity );
registry::iterator it = m_memory_in_use.find( p );
if( it != m_memory_in_use.end() ) {
m_execution_path[it->second].m_alloc.ptr = 0;
m_memory_in_use.erase( it );
}
}
//____________________________________________________________________________//
void
exception_safety_tester::assertion_result( bool passed )
{
if( !m_internal_activity && !passed ) {
m_invairant_failed = true;
failure_point();
}
}
//____________________________________________________________________________//
void
exception_safety_tester::failure_point()
{
if( m_exec_path_counter == m_break_exec_path )
debug::debugger_break();
throw unique_exception();
}
//____________________________________________________________________________//
namespace {
inline void
format_location( wrap_stringstream& formatter, execution_path_point const& /*p*/, unsigned indent )
{
if( indent )
formatter << std::left << std::setw( indent ) << "";
// !! ?? optional if( p.m_file_name )
// formatter << p.m_file_name << '(' << p.m_line_num << "): ";
}
//____________________________________________________________________________//
template<typename ExecPathIt>
inline void
format_execution_path( wrap_stringstream& formatter, ExecPathIt it, ExecPathIt end, unsigned indent = 0 )
{
while( it != end ) {
switch( it->m_type ) {
case EPP_SCOPE:
format_location( formatter, *it, indent );
formatter << "> \"" << it->m_scope.name << "\"\n";
format_execution_path( formatter, it+1, it + it->m_scope.size, indent + 2 );
format_location( formatter, *it, indent );
formatter << "< \"" << it->m_scope.name << "\"\n";
it += it->m_scope.size;
break;
case EPP_DECISION:
format_location( formatter, *it, indent );
formatter << "Decision made as " << std::boolalpha << it->m_decision.value << '\n';
++it;
break;
case EPP_EXCEPT:
format_location( formatter, *it, indent );
formatter << "Forced failure";
if( it->m_except.description )
formatter << ": " << it->m_except.description;
formatter << "\n";
++it;
break;
case EPP_ALLOC:
if( it->m_alloc.ptr ) {
format_location( formatter, *it, indent );
formatter << "Allocated memory block 0x" << std::uppercase << it->m_alloc.ptr
<< ", " << it->m_alloc.size << " bytes long: <";
unsigned i;
for( i = 0; i < std::min<std::size_t>( it->m_alloc.size, 8 ); i++ ) {
unsigned char c = static_cast<unsigned char*>(it->m_alloc.ptr)[i];
if( (std::isprint)( c ) )
formatter << c;
else
formatter << '.';
}
formatter << "> ";
for( i = 0; i < std::min<std::size_t>( it->m_alloc.size, 8 ); i++ ) {
unsigned c = static_cast<unsigned char*>(it->m_alloc.ptr)[i];
formatter << std::hex << std::uppercase << c << ' ';
}
formatter << "\n";
}
++it;
break;
}
}
}
//____________________________________________________________________________//
} // local namespace
void
exception_safety_tester::report_error()
{
activity_guard ag( m_internal_activity );
unit_test_log << unit_test::log::begin( m_execution_path.back().m_file_name,
m_execution_path.back().m_line_num )
<< log_all_errors;
wrap_stringstream formatter;
if( m_invairant_failed )
formatter << "Failed invariant";
if( m_memory_in_use.size() != 0 ) {
if( m_invairant_failed )
formatter << " and ";
formatter << static_cast<unsigned int>(m_memory_in_use.size()) << " memory leak";
if( m_memory_in_use.size() > 1 )
formatter << 's';
}
formatter << " detected in the execution path " << m_exec_path_counter << ":\n";
format_execution_path( formatter, m_execution_path.begin(), m_execution_path.end() );
unit_test_log << const_string( formatter.str() ) << unit_test::log::end();
}
//____________________________________________________________________________//
// ************************************************************************** //
// ************** exception safety test ************** //
// ************************************************************************** //
void BOOST_TEST_DECL
exception_safety( callback0<> const& F, const_string test_name )
{
exception_safety_tester est( test_name );
do {
try {
F();
}
catch( exception_safety_tester::unique_exception const& ) {}
} while( est.next_execution_path() );
}
//____________________________________________________________________________//
} // namespace itest
} // namespace boost
//____________________________________________________________________________//
#include <boost/test/detail/enable_warnings.hpp>
#endif // non-ancient compiler
#endif // BOOST_TEST_EXECUTION_SAFETY_IPP_112005GER