libs/utility/base_from_member_test.cpp
// Boost test program for base-from-member class templates -----------------// // Copyright 2001, 2003 Daryle Walker. Use, modification, and distribution are // subject to the Boost Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or a copy at <http://www.boost.org/LICENSE_1_0.txt>.) // See <http://www.boost.org/libs/utility/> for the library's home page. // Revision History // 14 Jun 2003 Adjusted code for Boost.Test changes (Daryle Walker) // 29 Aug 2001 Initial Version (Daryle Walker) #include <boost/test/minimal.hpp> // for BOOST_CHECK, main #include <boost/config.hpp> // for BOOST_NO_MEMBER_TEMPLATES #include <boost/cstdlib.hpp> // for boost::exit_success #include <boost/noncopyable.hpp> // for boost::noncopyable #include <boost/utility/base_from_member.hpp> // for boost::base_from_member #include <functional> // for std::binary_function, std::less #include <iostream> // for std::cout (std::ostream, std::endl indirectly) #include <set> // for std::set #include <typeinfo> // for std::type_info #include <utility> // for std::pair, std::make_pair #include <vector> // for std::vector // Control if extra information is printed #ifndef CONTROL_EXTRA_PRINTING #define CONTROL_EXTRA_PRINTING 1 #endif // A (sub)object can be identified by its memory location and its type. // Both are needed since an object can start at the same place as its // first base class subobject and/or contained subobject. typedef std::pair< void *, std::type_info const * > object_id; // Object IDs need to be printed std::ostream & operator <<( std::ostream &os, object_id const &oi ); // A way to generate an object ID template < typename T > object_id identify( T &obj ); // A custom comparison type is needed struct object_id_compare : std::binary_function<object_id, object_id, bool> { bool operator ()( object_id const &a, object_id const &b ) const; }; // object_id_compare // A singleton of this type coordinates the acknowledgements // of objects being created and used. class object_registrar : private boost::noncopyable { public: #ifndef BOOST_NO_MEMBER_TEMPLATES template < typename T > void register_object( T &obj ) { this->register_object_imp( identify(obj) ); } template < typename T, typename U > void register_use( T &owner, U &owned ) { this->register_use_imp( identify(owner), identify(owned) ); } template < typename T, typename U > void unregister_use( T &owner, U &owned ) { this->unregister_use_imp( identify(owner), identify(owned) ); } template < typename T > void unregister_object( T &obj ) { this->unregister_object_imp( identify(obj) ); } #endif void register_object_imp( object_id obj ); void register_use_imp( object_id owner, object_id owned ); void unregister_use_imp( object_id owner, object_id owned ); void unregister_object_imp( object_id obj ); typedef std::set<object_id, object_id_compare> set_type; typedef std::vector<object_id> error_record_type; typedef std::vector< std::pair<object_id, object_id> > error_pair_type; set_type db_; error_pair_type defrauders_in_, defrauders_out_; error_record_type overeager_, overkilled_; }; // object_registrar // A sample type to be used by containing types class base_or_member { public: explicit base_or_member( int x = 1, double y = -0.25 ); ~base_or_member(); }; // base_or_member // A sample type that uses base_or_member, used // as a base for the main demonstration classes class base_class { public: explicit base_class( base_or_member &x, base_or_member *y = 0, base_or_member *z = 0 ); ~base_class(); private: base_or_member *x_, *y_, *z_; }; // base_class // This bad class demonstrates the direct method of a base class needing // to be initialized by a member. This is improper since the member // isn't initialized until after the base class. class bad_class : public base_class { public: bad_class(); ~bad_class(); private: base_or_member x_; }; // bad_class // The first good class demonstrates the correct way to initialize a // base class with a member. The member is changed to another base // class, one that is initialized before the base that needs it. class good_class_1 : private boost::base_from_member<base_or_member> , public base_class { typedef boost::base_from_member<base_or_member> pbase_type; typedef base_class base_type; public: good_class_1(); ~good_class_1(); }; // good_class_1 // The second good class also demonstrates the correct way to initialize // base classes with other subobjects. This class uses the other helpers // in the library, and shows the technique of using two base subobjects // of the "same" type. class good_class_2 : private boost::base_from_member<base_or_member, 0> , private boost::base_from_member<base_or_member, 1> , private boost::base_from_member<base_or_member, 2> , public base_class { typedef boost::base_from_member<base_or_member, 0> pbase_type0; typedef boost::base_from_member<base_or_member, 1> pbase_type1; typedef boost::base_from_member<base_or_member, 2> pbase_type2; typedef base_class base_type; public: good_class_2(); ~good_class_2(); }; // good_class_2 // Declare/define the single object registrar object_registrar obj_reg; // Main functionality int test_main( int , char * [] ) { BOOST_CHECK( obj_reg.db_.empty() ); BOOST_CHECK( obj_reg.defrauders_in_.empty() ); BOOST_CHECK( obj_reg.defrauders_out_.empty() ); BOOST_CHECK( obj_reg.overeager_.empty() ); BOOST_CHECK( obj_reg.overkilled_.empty() ); // Make a separate block to examine pre- and post-effects { using std::cout; using std::endl; bad_class bc; BOOST_CHECK( obj_reg.db_.size() == 3 ); BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 ); good_class_1 gc1; BOOST_CHECK( obj_reg.db_.size() == 6 ); BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 ); good_class_2 gc2; BOOST_CHECK( obj_reg.db_.size() == 11 ); BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 ); BOOST_CHECK( obj_reg.defrauders_out_.empty() ); BOOST_CHECK( obj_reg.overeager_.empty() ); BOOST_CHECK( obj_reg.overkilled_.empty() ); // Getting the addresses of the objects ensure // that they're used, and not optimized away. cout << "Object 'bc' is at " << &bc << '.' << endl; cout << "Object 'gc1' is at " << &gc1 << '.' << endl; cout << "Object 'gc2' is at " << &gc2 << '.' << endl; } BOOST_CHECK( obj_reg.db_.empty() ); BOOST_CHECK( obj_reg.defrauders_in_.size() == 1 ); BOOST_CHECK( obj_reg.defrauders_out_.size() == 1 ); BOOST_CHECK( obj_reg.overeager_.empty() ); BOOST_CHECK( obj_reg.overkilled_.empty() ); return boost::exit_success; } // Print an object's ID std::ostream & operator << ( std::ostream & os, object_id const & oi ) { // I had an std::ostringstream to help, but I did not need it since // the program never screws around with formatting. Worse, using // std::ostringstream is an issue with some compilers. return os << '[' << ( oi.second ? oi.second->name() : "NOTHING" ) << " at " << oi.first << ']'; } // Get an object ID given an object template < typename T > inline object_id identify ( T & obj ) { return std::make_pair( static_cast<void *>(&obj), &(typeid( obj )) ); } // Compare two object IDs bool object_id_compare::operator () ( object_id const & a, object_id const & b ) const { std::less<void *> vp_cmp; if ( vp_cmp(a.first, b.first) ) { return true; } else if ( vp_cmp(b.first, a.first) ) { return false; } else { // object pointers are equal, compare the types if ( a.second == b.second ) { return false; } else if ( !a.second ) { return true; // NULL preceeds anything else } else if ( !b.second ) { return false; // NULL preceeds anything else } else { return a.second->before( *b.second ) != 0; } } } // Let an object register its existence void object_registrar::register_object_imp ( object_id obj ) { if ( db_.count(obj) <= 0 ) { db_.insert( obj ); #if CONTROL_EXTRA_PRINTING std::cout << "Registered " << obj << '.' << std::endl; #endif } else { overeager_.push_back( obj ); #if CONTROL_EXTRA_PRINTING std::cout << "Attempted to register a non-existant " << obj << '.' << std::endl; #endif } } // Let an object register its use of another object void object_registrar::register_use_imp ( object_id owner, object_id owned ) { if ( db_.count(owned) > 0 ) { // We don't care to record usage registrations } else { defrauders_in_.push_back( std::make_pair(owner, owned) ); #if CONTROL_EXTRA_PRINTING std::cout << "Attempted to own a non-existant " << owned << " by " << owner << '.' << std::endl; #endif } } // Let an object un-register its use of another object void object_registrar::unregister_use_imp ( object_id owner, object_id owned ) { if ( db_.count(owned) > 0 ) { // We don't care to record usage un-registrations } else { defrauders_out_.push_back( std::make_pair(owner, owned) ); #if CONTROL_EXTRA_PRINTING std::cout << "Attempted to disown a non-existant " << owned << " by " << owner << '.' << std::endl; #endif } } // Let an object un-register its existence void object_registrar::unregister_object_imp ( object_id obj ) { set_type::iterator const i = db_.find( obj ); if ( i != db_.end() ) { db_.erase( i ); #if CONTROL_EXTRA_PRINTING std::cout << "Unregistered " << obj << '.' << std::endl; #endif } else { overkilled_.push_back( obj ); #if CONTROL_EXTRA_PRINTING std::cout << "Attempted to unregister a non-existant " << obj << '.' << std::endl; #endif } } // Macros to abstract the registration of objects #ifndef BOOST_NO_MEMBER_TEMPLATES #define PRIVATE_REGISTER_BIRTH(o) obj_reg.register_object( (o) ) #define PRIVATE_REGISTER_DEATH(o) obj_reg.unregister_object( (o) ) #define PRIVATE_REGISTER_USE(o, w) obj_reg.register_use( (o), (w) ) #define PRIVATE_UNREGISTER_USE(o, w) obj_reg.unregister_use( (o), (w) ) #else #define PRIVATE_REGISTER_BIRTH(o) obj_reg.register_object_imp( \ identify((o)) ) #define PRIVATE_REGISTER_DEATH(o) obj_reg.unregister_object_imp( \ identify((o)) ) #define PRIVATE_REGISTER_USE(o, w) obj_reg.register_use_imp( identify((o)), \ identify((w)) ) #define PRIVATE_UNREGISTER_USE(o, w) obj_reg.unregister_use_imp( \ identify((o)), identify((w)) ) #endif // Create a base_or_member, with arguments to simulate member initializations base_or_member::base_or_member ( int x, // = 1 double y // = -0.25 ) { PRIVATE_REGISTER_BIRTH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy x-factor is " << x << " and my y-factor is " << y << '.' << std::endl; #endif } // Destroy a base_or_member inline base_or_member::~base_or_member ( ) { PRIVATE_REGISTER_DEATH( *this ); } // Create a base_class, registering any objects used base_class::base_class ( base_or_member & x, base_or_member * y, // = 0 base_or_member * z // = 0 ) : x_( &x ), y_( y ), z_( z ) { PRIVATE_REGISTER_BIRTH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy x-factor is " << x_; #endif PRIVATE_REGISTER_USE( *this, *x_ ); if ( y_ ) { #if CONTROL_EXTRA_PRINTING std::cout << ", my y-factor is " << y_; #endif PRIVATE_REGISTER_USE( *this, *y_ ); } if ( z_ ) { #if CONTROL_EXTRA_PRINTING std::cout << ", my z-factor is " << z_; #endif PRIVATE_REGISTER_USE( *this, *z_ ); } #if CONTROL_EXTRA_PRINTING std::cout << '.' << std::endl; #endif } // Destroy a base_class, unregistering the objects it uses base_class::~base_class ( ) { PRIVATE_REGISTER_DEATH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy x-factor was " << x_; #endif PRIVATE_UNREGISTER_USE( *this, *x_ ); if ( y_ ) { #if CONTROL_EXTRA_PRINTING std::cout << ", my y-factor was " << y_; #endif PRIVATE_UNREGISTER_USE( *this, *y_ ); } if ( z_ ) { #if CONTROL_EXTRA_PRINTING std::cout << ", my z-factor was " << z_; #endif PRIVATE_UNREGISTER_USE( *this, *z_ ); } #if CONTROL_EXTRA_PRINTING std::cout << '.' << std::endl; #endif } // Create a bad_class, noting the improper construction order bad_class::bad_class ( ) : x_( -7, 16.75 ), base_class( x_ ) // this order doesn't matter { PRIVATE_REGISTER_BIRTH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy factor is at " << &x_ << " and my base is at " << static_cast<base_class *>(this) << '.' << std::endl; #endif } // Destroy a bad_class, noting the improper destruction order bad_class::~bad_class ( ) { PRIVATE_REGISTER_DEATH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy factor was at " << &x_ << " and my base was at " << static_cast<base_class *>(this) << '.' << std::endl; #endif } // Create a good_class_1, noting the proper construction order good_class_1::good_class_1 ( ) : pbase_type( 8 ), base_type( member ) { PRIVATE_REGISTER_BIRTH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy factor is at " << &member << " and my base is at " << static_cast<base_class *>(this) << '.' << std::endl; #endif } // Destroy a good_class_1, noting the proper destruction order good_class_1::~good_class_1 ( ) { PRIVATE_REGISTER_DEATH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy factor was at " << &member << " and my base was at " << static_cast<base_class *>(this) << '.' << std::endl; #endif } // Create a good_class_2, noting the proper construction order good_class_2::good_class_2 ( ) : pbase_type0(), pbase_type1(-16, 0.125), pbase_type2(2, -3) , base_type( pbase_type1::member, &this->pbase_type0::member, &this->pbase_type2::member ) { PRIVATE_REGISTER_BIRTH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy factors are at " << &this->pbase_type0::member << ", " << &this->pbase_type1::member << ", " << &this->pbase_type2::member << ", and my base is at " << static_cast<base_class *>(this) << '.' << std::endl; #endif } // Destroy a good_class_2, noting the proper destruction order good_class_2::~good_class_2 ( ) { PRIVATE_REGISTER_DEATH( *this ); #if CONTROL_EXTRA_PRINTING std::cout << "\tMy factors were at " << &this->pbase_type0::member << ", " << &this->pbase_type1::member << ", " << &this->pbase_type2::member << ", and my base was at " << static_cast<base_class *>(this) << '.' << std::endl; #endif }