// // Boost.Pointer Container // // Copyright Thorsten Ottosen 2003-2005. Use, modification and // distribution is subject to 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) // // For more information, see http://www.boost.org/libs/ptr_container/ // #ifndef BOOST_PTR_CONTAINER_DETAIL_REVERSIBLE_PTR_CONTAINER_HPP #define BOOST_PTR_CONTAINER_DETAIL_REVERSIBLE_PTR_CONTAINER_HPP #if defined(_MSC_VER) && (_MSC_VER >= 1200) # pragma once #endif #include #include #include #include #include #include #include #ifdef BOOST_NO_SFINAE #else #include #endif #include #include #include #include #include #include #include #include #include #if BOOST_WORKAROUND(BOOST_MSVC, >= 1400) #pragma warning(push) #pragma warning(disable:4127) #pragma warning(disable:4224) // formal parameter was previously defined as a type. #endif #if defined(BOOST_PTR_CONTAINER_DISABLE_DEPRECATED) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wdeprecated-declarations" #endif namespace boost { namespace ptr_container_detail { template< class Container > struct dynamic_clone_deleter { dynamic_clone_deleter() { } dynamic_clone_deleter( Container& cont ) : cont(&cont) { } Container* cont; template< class T > void operator()( const T* p ) const { // remark: static_move_ptr already test for null cont->get_clone_allocator().deallocate_clone( p ); } }; template< class CloneAllocator > struct static_clone_deleter { static_clone_deleter() { } template< class Dummy > static_clone_deleter( const Dummy& ) { } template< class T > void operator()( const T* p ) const { // remark: static_move_ptr already test for null CloneAllocator::deallocate_clone( p ); } }; template< class T > struct is_pointer_or_integral { BOOST_STATIC_CONSTANT(bool, value = is_pointer::value || is_integral::value ); }; struct is_pointer_or_integral_tag {}; struct is_range_tag {}; struct sequence_tag {}; struct fixed_length_sequence_tag : sequence_tag {}; struct associative_container_tag {}; struct ordered_associative_container_tag : associative_container_tag {}; struct unordered_associative_container_tag : associative_container_tag {}; template < class Config, class CloneAllocator > class reversible_ptr_container : CloneAllocator { private: BOOST_STATIC_CONSTANT( bool, allow_null = Config::allow_null ); BOOST_STATIC_CONSTANT( bool, is_clone_allocator_empty = sizeof(CloneAllocator) < sizeof(void*) ); typedef BOOST_DEDUCED_TYPENAME Config::value_type Ty_; typedef BOOST_DEDUCED_TYPENAME Config::void_container_type container_type; typedef dynamic_clone_deleter dynamic_deleter_type; typedef static_clone_deleter static_deleter_type; container_type c_; public: container_type& base() { return c_; } protected: // having this public could break encapsulation const container_type& base() const { return c_; } public: // typedefs typedef Ty_ object_type; typedef Ty_* value_type; typedef Ty_* pointer; typedef Ty_& reference; typedef const Ty_& const_reference; typedef BOOST_DEDUCED_TYPENAME Config::iterator iterator; typedef BOOST_DEDUCED_TYPENAME Config::const_iterator const_iterator; typedef boost::reverse_iterator< iterator > reverse_iterator; typedef boost::reverse_iterator< const_iterator > const_reverse_iterator; typedef BOOST_DEDUCED_TYPENAME container_type::difference_type difference_type; typedef BOOST_DEDUCED_TYPENAME container_type::size_type size_type; typedef BOOST_DEDUCED_TYPENAME Config::allocator_type allocator_type; typedef CloneAllocator clone_allocator_type; typedef ptr_container_detail::static_move_ptr::type > auto_type; protected: typedef ptr_container_detail::scoped_deleter scoped_deleter; typedef BOOST_DEDUCED_TYPENAME container_type::iterator ptr_iterator; typedef BOOST_DEDUCED_TYPENAME container_type::const_iterator ptr_const_iterator; private: template< class InputIterator > void copy( InputIterator first, InputIterator last ) { std::copy( first, last, begin() ); } void copy( const reversible_ptr_container& r ) { this->copy( r.begin(), r.end() ); } void copy_clones_and_release( scoped_deleter& sd ) // nothrow { BOOST_ASSERT( size_type( std::distance( sd.begin(), sd.end() ) ) == c_.size() ); std::copy( sd.begin(), sd.end(), c_.begin() ); sd.release(); } template< class ForwardIterator > void clone_assign( ForwardIterator first, ForwardIterator last ) // strong { BOOST_ASSERT( first != last ); scoped_deleter sd( *this, first, last ); // strong copy_clones_and_release( sd ); // nothrow } template< class ForwardIterator > void clone_back_insert( ForwardIterator first, ForwardIterator last ) { BOOST_ASSERT( first != last ); scoped_deleter sd( *this, first, last ); insert_clones_and_release( sd, end() ); } void remove_all() { this->remove( begin(), end() ); } protected: void insert_clones_and_release( scoped_deleter& sd, iterator where ) // strong { // // 'c_.insert' always provides the strong guarantee for T* elements // since a copy constructor of a pointer cannot throw // c_.insert( where.base(), sd.begin(), sd.end() ); sd.release(); } void insert_clones_and_release( scoped_deleter& sd ) // strong { c_.insert( sd.begin(), sd.end() ); sd.release(); } template< class U > void remove( U* ptr ) { this->deallocate_clone( ptr ); } template< class I > void remove( I i ) { this->deallocate_clone( Config::get_const_pointer(i) ); } template< class I > void remove( I first, I last ) { for( ; first != last; ++first ) this->remove( first ); } static void enforce_null_policy( const Ty_* x, const char* msg ) { if( !allow_null ) { BOOST_PTR_CONTAINER_THROW_EXCEPTION( 0 == x && "null not allowed", bad_pointer, msg ); } } public: Ty_* null_policy_allocate_clone( const Ty_* x ) { if( allow_null ) { if( x == 0 ) return 0; } else { BOOST_ASSERT( x != 0 && "Cannot insert clone of null!" ); } Ty_* res = this->get_clone_allocator().allocate_clone( *x ); BOOST_ASSERT( typeid(*res) == typeid(*x) && "CloneAllocator::allocate_clone() does not clone the " "object properly. Check that new_clone() is implemented" " correctly" ); return res; } template< class Iterator > Ty_* null_policy_allocate_clone_from_iterator( Iterator i ) { return this->null_policy_allocate_clone(Config::get_const_pointer(i)); } void null_policy_deallocate_clone( const Ty_* x ) { if( allow_null ) { if( x == 0 ) return; } this->get_clone_allocator().deallocate_clone( x ); } private: template< class ForwardIterator > ForwardIterator advance( ForwardIterator begin, size_type n ) { ForwardIterator iter = begin; std::advance( iter, n ); return iter; } template< class I > void constructor_impl( I first, I last, std::input_iterator_tag ) // basic { while( first != last ) { insert( end(), this->allocate_clone_from_iterator(first) ); ++first; } } template< class I > void constructor_impl( I first, I last, std::forward_iterator_tag ) // strong { if( first == last ) return; clone_back_insert( first, last ); } template< class I > void associative_constructor_impl( I first, I last ) // strong { if( first == last ) return; scoped_deleter sd( *this, first, last ); insert_clones_and_release( sd ); } public: // foundation: should be protected, but public for poor compilers' sake. reversible_ptr_container() { } template< class SizeType > reversible_ptr_container( SizeType n, unordered_associative_container_tag ) : c_( n ) { } template< class SizeType > reversible_ptr_container( SizeType n, fixed_length_sequence_tag ) : c_( n ) { } template< class SizeType > reversible_ptr_container( SizeType n, const allocator_type& a, fixed_length_sequence_tag ) : c_( n, a ) { } explicit reversible_ptr_container( const allocator_type& a ) : c_( a ) { } #ifndef BOOST_NO_AUTO_PTR template< class PtrContainer > explicit reversible_ptr_container( std::auto_ptr clone ) { swap( *clone ); } #endif #ifndef BOOST_NO_CXX11_SMART_PTR template< class PtrContainer > explicit reversible_ptr_container( std::unique_ptr clone ) { swap( *clone ); } #endif reversible_ptr_container( const reversible_ptr_container& r ) { constructor_impl( r.begin(), r.end(), std::forward_iterator_tag() ); } template< class C, class V > reversible_ptr_container( const reversible_ptr_container& r ) { constructor_impl( r.begin(), r.end(), std::forward_iterator_tag() ); } #ifndef BOOST_NO_AUTO_PTR template< class PtrContainer > reversible_ptr_container& operator=( std::auto_ptr clone ) // nothrow { swap( *clone ); return *this; } #endif #ifndef BOOST_NO_CXX11_SMART_PTR template< class PtrContainer > reversible_ptr_container& operator=( std::unique_ptr clone ) // nothrow { swap( *clone ); return *this; } #endif reversible_ptr_container& operator=( reversible_ptr_container r ) // strong { swap( r ); return *this; } // overhead: null-initilization of container pointer (very cheap compared to cloning) // overhead: 1 heap allocation (very cheap compared to cloning) template< class InputIterator > reversible_ptr_container( InputIterator first, InputIterator last, const allocator_type& a = allocator_type() ) // basic, strong : c_( a ) { constructor_impl( first, last, #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) #else BOOST_DEDUCED_TYPENAME #endif iterator_category::type() ); } template< class Compare > reversible_ptr_container( const Compare& comp, const allocator_type& a ) : c_( comp, a ) {} template< class ForwardIterator > reversible_ptr_container( ForwardIterator first, ForwardIterator last, fixed_length_sequence_tag ) : c_( std::distance(first,last) ) { constructor_impl( first, last, std::forward_iterator_tag() ); } template< class SizeType, class InputIterator > reversible_ptr_container( SizeType n, InputIterator first, InputIterator last, fixed_length_sequence_tag ) : c_( n ) { constructor_impl( first, last, #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) #else BOOST_DEDUCED_TYPENAME #endif iterator_category::type() ); } template< class Compare > reversible_ptr_container( const Compare& comp, const allocator_type& a, associative_container_tag ) : c_( comp, a ) { } template< class InputIterator > reversible_ptr_container( InputIterator first, InputIterator last, associative_container_tag ) { associative_constructor_impl( first, last ); } template< class InputIterator, class Compare > reversible_ptr_container( InputIterator first, InputIterator last, const Compare& comp, const allocator_type& a, associative_container_tag ) : c_( comp, a ) { associative_constructor_impl( first, last ); } explicit reversible_ptr_container( size_type n ) : c_( n ) {} template< class Hash, class Pred > reversible_ptr_container( const Hash& h, const Pred& pred, const allocator_type& a ) : c_( h, pred, a ) {} template< class InputIterator, class Hash, class Pred > reversible_ptr_container( InputIterator first, InputIterator last, const Hash& h, const Pred& pred, const allocator_type& a ) : c_( h, pred, a ) { associative_constructor_impl( first, last ); } public: ~reversible_ptr_container() { remove_all(); } public: allocator_type get_allocator() const { return c_.get_allocator(); } clone_allocator_type& get_clone_allocator() { return static_cast(*this); } const clone_allocator_type& get_clone_allocator() const { return static_cast(*this); } public: // container requirements iterator begin() { return iterator( c_.begin() ); } const_iterator begin() const { return const_iterator( c_.begin() ); } iterator end() { return iterator( c_.end() ); } const_iterator end() const { return const_iterator( c_.end() ); } reverse_iterator rbegin() { return reverse_iterator( this->end() ); } const_reverse_iterator rbegin() const { return const_reverse_iterator( this->end() ); } reverse_iterator rend() { return reverse_iterator( this->begin() ); } const_reverse_iterator rend() const { return const_reverse_iterator( this->begin() ); } const_iterator cbegin() const { return const_iterator( c_.begin() ); } const_iterator cend() const { return const_iterator( c_.end() ); } const_reverse_iterator crbegin() const { return const_reverse_iterator( this->end() ); } const_reverse_iterator crend() const { return const_reverse_iterator( this->begin() ); } void swap( reversible_ptr_container& r ) // nothrow { boost::swap( get_clone_allocator(), r.get_clone_allocator() ); // nothrow c_.swap( r.c_ ); // nothrow } size_type size() const // nothrow { return c_.size(); } size_type max_size() const // nothrow { return c_.max_size(); } bool empty() const // nothrow { return c_.empty(); } public: // optional container requirements bool operator==( const reversible_ptr_container& r ) const // nothrow { if( size() != r.size() ) return false; else return std::equal( begin(), end(), r.begin() ); } bool operator!=( const reversible_ptr_container& r ) const // nothrow { return !(*this == r); } bool operator<( const reversible_ptr_container& r ) const // nothrow { return std::lexicographical_compare( begin(), end(), r.begin(), r.end() ); } bool operator<=( const reversible_ptr_container& r ) const // nothrow { return !(r < *this); } bool operator>( const reversible_ptr_container& r ) const // nothrow { return r < *this; } bool operator>=( const reversible_ptr_container& r ) const // nothrow { return !(*this < r); } public: // modifiers iterator insert( iterator before, Ty_* x ) { enforce_null_policy( x, "Null pointer in 'insert()'" ); auto_type ptr( x, *this ); // nothrow iterator res( c_.insert( before.base(), x ) ); // strong, commit ptr.release(); // nothrow return res; } #ifndef BOOST_NO_AUTO_PTR template< class U > iterator insert( iterator before, std::auto_ptr x ) { return insert( before, x.release() ); } #endif #ifndef BOOST_NO_CXX11_SMART_PTR template< class U > iterator insert( iterator before, std::unique_ptr x ) { return insert( before, x.release() ); } #endif iterator erase( iterator x ) // nothrow { BOOST_ASSERT( !empty() ); BOOST_ASSERT( x != end() ); remove( x ); return iterator( c_.erase( x.base() ) ); } iterator erase( iterator first, iterator last ) // nothrow { remove( first, last ); return iterator( c_.erase( first.base(), last.base() ) ); } template< class Range > iterator erase( const Range& r ) { return erase( boost::begin(r), boost::end(r) ); } void clear() { remove_all(); c_.clear(); } public: // access interface auto_type release( iterator where ) { BOOST_ASSERT( where != end() ); BOOST_PTR_CONTAINER_THROW_EXCEPTION( empty(), bad_ptr_container_operation, "'release()' on empty container" ); auto_type ptr( Config::get_pointer(where), *this ); // nothrow c_.erase( where.base() ); // nothrow return boost::ptr_container_detail::move( ptr ); } auto_type replace( iterator where, Ty_* x ) // strong { BOOST_ASSERT( where != end() ); enforce_null_policy( x, "Null pointer in 'replace()'" ); auto_type ptr( x, *this ); BOOST_PTR_CONTAINER_THROW_EXCEPTION( empty(), bad_ptr_container_operation, "'replace()' on empty container" ); auto_type old( Config::get_pointer(where), *this ); // nothrow const_cast(*where.base()) = ptr.release(); return boost::ptr_container_detail::move( old ); } #ifndef BOOST_NO_AUTO_PTR template< class U > auto_type replace( iterator where, std::auto_ptr x ) { return replace( where, x.release() ); } #endif #ifndef BOOST_NO_CXX11_SMART_PTR template< class U > auto_type replace( iterator where, std::unique_ptr x ) { return replace( where, x.release() ); } #endif auto_type replace( size_type idx, Ty_* x ) // strong { enforce_null_policy( x, "Null pointer in 'replace()'" ); auto_type ptr( x, *this ); BOOST_PTR_CONTAINER_THROW_EXCEPTION( idx >= size(), bad_index, "'replace()' out of bounds" ); auto_type old( static_cast(c_[idx]), *this ); // nothrow c_[idx] = ptr.release(); // nothrow, commit return boost::ptr_container_detail::move( old ); } #ifndef BOOST_NO_AUTO_PTR template< class U > auto_type replace( size_type idx, std::auto_ptr x ) { return replace( idx, x.release() ); } #endif #ifndef BOOST_NO_CXX11_SMART_PTR template< class U > auto_type replace( size_type idx, std::unique_ptr x ) { return replace( idx, x.release() ); } #endif }; // 'reversible_ptr_container' #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564)) #define BOOST_PTR_CONTAINER_DEFINE_RELEASE( base_type ) \ typename base_type::auto_type \ release( typename base_type::iterator i ) \ { \ return boost::ptr_container_detail::move(base_type::release(i)); \ } #else #define BOOST_PTR_CONTAINER_DEFINE_RELEASE( base_type ) \ using base_type::release; #endif #ifndef BOOST_NO_AUTO_PTR #define BOOST_PTR_CONTAINER_COPY_AND_ASSIGN_AUTO( PC, base_type, this_type ) \ explicit PC( std::auto_ptr r ) \ : base_type ( r ) { } \ \ PC& operator=( std::auto_ptr r ) \ { \ base_type::operator=( r ); \ return *this; \ } #else #define BOOST_PTR_CONTAINER_COPY_AND_ASSIGN_AUTO( PC, base_type, this_type ) #endif #ifndef BOOST_NO_CXX11_SMART_PTR #define BOOST_PTR_CONTAINER_COPY_AND_ASSIGN_UNIQUE( PC, base_type, this_type ) \ explicit PC( std::unique_ptr r ) \ : base_type ( std::move( r ) ) { } \ \ PC& operator=( std::unique_ptr r ) \ { \ base_type::operator=( std::move( r ) ); \ return *this; \ } #else #define BOOST_PTR_CONTAINER_COPY_AND_ASSIGN_UNIQUE( PC, base_type, this_type ) #endif #ifndef BOOST_NO_AUTO_PTR #define BOOST_PTR_CONTAINER_RELEASE_AND_CLONE( this_type ) \ std::auto_ptr release() \ { \ std::auto_ptr ptr( new this_type );\ this->swap( *ptr ); \ return ptr; \ } \ \ std::auto_ptr clone() const \ { \ return std::auto_ptr( new this_type( this->begin(), this->end() ) ); \ } #elif !defined( BOOST_NO_CXX11_SMART_PTR ) #define BOOST_PTR_CONTAINER_RELEASE_AND_CLONE( this_type ) \ std::unique_ptr release() \ { \ std::unique_ptr ptr( new this_type );\ this->swap( *ptr ); \ return ptr; \ } \ \ std::unique_ptr clone() const \ { \ return std::unique_ptr( new this_type( this->begin(), this->end() ) ); \ } #else #define BOOST_PTR_CONTAINER_RELEASE_AND_CLONE( this_type ) #endif // // two-phase lookup of template functions // is buggy on most compilers, so we use a macro instead // #define BOOST_PTR_CONTAINER_DEFINE_RELEASE_AND_CLONE( PC, base_type, this_type ) \ BOOST_PTR_CONTAINER_COPY_AND_ASSIGN_AUTO( PC, base_type, this_type ) \ BOOST_PTR_CONTAINER_COPY_AND_ASSIGN_UNIQUE( PC, base_type, this_type ) \ BOOST_PTR_CONTAINER_RELEASE_AND_CLONE( this_type ) \ BOOST_PTR_CONTAINER_DEFINE_RELEASE( base_type ) #define BOOST_PTR_CONTAINER_DEFINE_COPY_CONSTRUCTORS( PC, base_type ) \ \ template< class U > \ PC( const PC& r ) : base_type( r ) { } \ \ PC& operator=( PC r ) \ { \ this->swap( r ); \ return *this; \ } \ #define BOOST_PTR_CONTAINER_DEFINE_CONSTRUCTORS( PC, base_type ) \ typedef BOOST_DEDUCED_TYPENAME base_type::iterator iterator; \ typedef BOOST_DEDUCED_TYPENAME base_type::size_type size_type; \ typedef BOOST_DEDUCED_TYPENAME base_type::const_reference const_reference; \ typedef BOOST_DEDUCED_TYPENAME base_type::allocator_type allocator_type; \ PC() {} \ explicit PC( const allocator_type& a ) : base_type(a) {} \ template< class InputIterator > \ PC( InputIterator first, InputIterator last ) : base_type( first, last ) {} \ template< class InputIterator > \ PC( InputIterator first, InputIterator last, \ const allocator_type& a ) : base_type( first, last, a ) {} #define BOOST_PTR_CONTAINER_DEFINE_NON_INHERITED_MEMBERS( PC, base_type, this_type ) \ BOOST_PTR_CONTAINER_DEFINE_CONSTRUCTORS( PC, base_type ) \ BOOST_PTR_CONTAINER_DEFINE_RELEASE_AND_CLONE( PC, base_type, this_type ) #define BOOST_PTR_CONTAINER_DEFINE_SEQEUENCE_MEMBERS( PC, base_type, this_type ) \ BOOST_PTR_CONTAINER_DEFINE_NON_INHERITED_MEMBERS( PC, base_type, this_type ) \ BOOST_PTR_CONTAINER_DEFINE_COPY_CONSTRUCTORS( PC, base_type ) } // namespace 'ptr_container_detail' // // @remark: expose movability of internal move-pointer // namespace ptr_container { using ptr_container_detail::move; } } // namespace 'boost' #if defined(BOOST_PTR_CONTAINER_DISABLE_DEPRECATED) #pragma GCC diagnostic pop #endif #if BOOST_WORKAROUND(BOOST_MSVC, >= 1400) #pragma warning(pop) #endif #endif