/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright 2017 CERN * Copyright (C) 2020-2021 KiCad Developers, see AUTHORS.txt for contributors. * * @author Maciej Suminski * @author Bernhard Stegmaier * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #ifndef MULTIVECTOR_H #define MULTIVECTOR_H #include #include /** * Multivector container type. * * Keeps items segregated by their type in multiple ptr_vectors. Provides both * access as a flat list as well as access by type of item. * * T is the stored type, needs to provide Type() method used to segregate items. * FIRST_TYPE_VAL is the lower boundary value of the types stored in the container. * LAST_TYPE_VAL is the upper boundary value of the types stored in the container. */ template class MULTIVECTOR { public: /** * Type value to indicate no specific type. Mostly used to access the container as a flat list * or to return data for the whole container. */ static constexpr int UNDEFINED_TYPE = 0; static_assert( FIRST_TYPE_VAL > UNDEFINED_TYPE, "FIRST_TYPE_VAL has to be greater than UNDEFINED_TYPE" ); static_assert( FIRST_TYPE_VAL < LAST_TYPE_VAL, "FIRST_TYPE_VAL has to be greater than LAST_TYPE_VAL" ); /** * Helper for defining a list of library draw object pointers. * * The Boost pointer containers are responsible for deleting object pointers placed * in them. If you access a object pointer from the list, do not delete it directly. */ typedef boost::ptr_vector ITEM_PTR_VECTOR; /** * Generic implementation of a flat const/non-const iterator over contained items. */ template class ITERATOR_BASE { public: ITEM_TYPE& operator*() { return *m_it; } ITEM_TYPE* operator->() { return &( *m_it ); } ITERATOR_BASE& operator++() { if( m_it != (*m_parent)[ m_curType ].end() ) ++m_it; validate(); return *this; } bool operator!=( const ITERATOR_BASE& aOther ) const { if( aOther.m_parent != m_parent ) return true; if( aOther.m_filter != m_filter ) return true; if( aOther.m_curType != m_curType ) return true; return aOther.m_it != m_it; } protected: /** * @param aItems is the container to wrap. * @param aIt is the iterator to initialize this iterator (usually some begin() or end() * iterator). * @param aBucket is the type ID of the given iterator. * @param aType enables item type filtering. When aType is UNDEFINED_TYPE, there is no * filtering and all item types are accessible by the iterator. */ ITERATOR_BASE( ITEM_CONTAINER* aItems, ITEM_CONTAINER_IT aIt, int aBucket, int aType = UNDEFINED_TYPE ) : m_parent( aItems ), m_it( aIt ), m_curType( aBucket ) { m_filter = ( aType != UNDEFINED_TYPE ); } ///< Assures the iterator is in a valid state. void validate() { // for all-items iterators (unfiltered): check if this is the end of the // current type container, if so switch to the next non-empty container if( !m_filter && m_it == (*m_parent)[ m_curType ].end() ) { // switch to the next type (look for a not empty container) int nextType = m_curType; do ++nextType; while( ( nextType <= LAST_TYPE ) && (*m_parent)[ nextType ].empty() ); // there is another not empty container, so make the iterator point to it, // otherwise it means the iterator points to the last item if( nextType <= LAST_TYPE ) { m_curType = nextType; m_it = (*m_parent)[ m_curType ].begin(); } } } ///< Wrapped container ITEM_CONTAINER* m_parent; ///< Iterator for one of the ptr_vector containers stored in the array ITEM_CONTAINER_IT m_it; ///< Flag indicating whether type filtering is enabled bool m_filter; ///< Type of the currently iterated items int m_curType; friend class MULTIVECTOR; }; ///< The non-const iterator typedef ITERATOR_BASE, typename ITEM_PTR_VECTOR::iterator> ITERATOR; ///< The const iterator typedef ITERATOR_BASE, typename ITEM_PTR_VECTOR::const_iterator> CONST_ITERATOR; MULTIVECTOR() { } void push_back( T* aItem ) { operator[]( aItem->Type() ).push_back( aItem ); } ITERATOR erase( const ITERATOR& aIterator ) { ITERATOR it( aIterator ); it.m_it = (*aIterator.m_parent)[ aIterator.m_curType ].erase( aIterator.m_it ); it.validate(); return it; } ITERATOR begin( int aType = UNDEFINED_TYPE ) { int bucket = ( aType != UNDEFINED_TYPE ) ? aType : first(); return ITERATOR( this, operator[]( bucket ).begin(), bucket, aType ); } ITERATOR end( int aType = UNDEFINED_TYPE ) { int bucket = ( aType != UNDEFINED_TYPE ) ? aType : last(); return ITERATOR( this, operator[]( bucket ).end(), bucket, aType ); } CONST_ITERATOR begin( int aType = UNDEFINED_TYPE ) const { int bucket = ( aType != UNDEFINED_TYPE ) ? aType : first(); return CONST_ITERATOR( this, operator[]( bucket ).begin(), bucket, aType ); } CONST_ITERATOR end( int aType = UNDEFINED_TYPE ) const { int bucket = ( aType != UNDEFINED_TYPE ) ? aType : last(); return CONST_ITERATOR( this, operator[]( bucket ).end(), bucket, aType ); } void clear( int aType = UNDEFINED_TYPE ) { if( aType != UNDEFINED_TYPE ) { operator[]( aType ).clear(); } else { for( int i = 0; i < TYPES_COUNT; ++i) m_data[ i ].clear(); } } size_t size( int aType = UNDEFINED_TYPE ) const { if( aType != UNDEFINED_TYPE ) { return operator[]( aType ).size(); } else { size_t cnt = 0; for( int i = 0; i < TYPES_COUNT; ++i) cnt += m_data[ i ].size(); return cnt; } } bool empty( int aType = UNDEFINED_TYPE ) { return ( size( aType ) == 0 ); } void sort() { for( int i = 0; i < TYPES_COUNT; ++i ) m_data[ i ].sort(); } /** * Remove duplicate elements in list */ void unique() { for( int i = 0; i < TYPES_COUNT; ++i ) { if( m_data[ i ].size() > 1 ) m_data[ i ].unique(); } } ITEM_PTR_VECTOR& operator[]( int aType ) { if( ( aType < FIRST_TYPE ) || ( aType > LAST_TYPE ) ) { wxFAIL_MSG( "Attempted access to type not within MULTIVECTOR" ); // return type is a reference so we have to return something... aType = FIRST_TYPE; } return m_data[ aType - FIRST_TYPE ]; } const ITEM_PTR_VECTOR& operator[]( int aType ) const { if( ( aType < FIRST_TYPE ) || ( aType > LAST_TYPE ) ) { wxFAIL_MSG( "Attempted access to type not within MULTIVECTOR" ); // return type is a reference so we have to return something... aType = FIRST_TYPE; } return m_data[ aType - FIRST_TYPE ]; } // Range of valid types handled by the iterator static constexpr int FIRST_TYPE = FIRST_TYPE_VAL; static constexpr int LAST_TYPE = LAST_TYPE_VAL; static constexpr int TYPES_COUNT = LAST_TYPE - FIRST_TYPE + 1; private: ///< Get first non-empty type or first type if all are empty. int first() const { int i = 0; while( ( i < TYPES_COUNT ) && ( m_data[ i ].empty() ) ) ++i; return ( i == TYPES_COUNT ) ? FIRST_TYPE : FIRST_TYPE + i; } ///< Get last non-empty type or first type if all are empty. int last() const { int i = TYPES_COUNT - 1; while( ( i >= 0 ) && ( m_data[ i ].empty() ) ) --i; return ( i < 0 ) ? FIRST_TYPE : FIRST_TYPE + i; } ///< Contained items by type ITEM_PTR_VECTOR m_data[TYPES_COUNT]; }; #endif /* MULTIVECTOR_H */