deba@1720: /* -*- C++ -*- deba@1720: * alpar@1956: * This file is a part of LEMON, a generic C++ optimization library alpar@1956: * alpar@2553: * Copyright (C) 2003-2008 alpar@1956: * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport deba@1720: * (Egervary Research Group on Combinatorial Optimization, EGRES). deba@1720: * deba@1720: * Permission to use, modify and distribute this software is granted deba@1720: * provided that this copyright notice appears in all copies. For deba@1720: * precise terms see the accompanying LICENSE file. deba@1720: * deba@1720: * This software is provided "AS IS" with no warranty of any kind, deba@1720: * express or implied, and with no claim as to its suitability for any deba@1720: * purpose. deba@1720: * deba@1720: */ deba@1720: deba@1720: #ifndef LEMON_MATRIX_MAPS_H deba@1720: #define LEMON_MATRIX_MAPS_H deba@1720: deba@1720: deba@1720: #include deba@1993: #include alpar@2088: #include deba@1720: #include deba@1720: alpar@2260: #include deba@1720: deba@1720: /// \file alpar@2072: /// \ingroup matrices deba@1720: /// \brief Maps indexed with pairs of items. deba@1720: /// alpar@2260: /// \todo This file has the same name as the concept file in concepts/, deba@1720: /// and this is not easily detectable in docs... deba@1720: namespace lemon { deba@1720: deba@1720: /// \brief Map for the coloumn view of the matrix deba@1720: /// alpar@2072: /// \ingroup matrices deba@1720: /// Map for the coloumn view of the matrix. alpar@2072: /// deba@1720: template deba@2039: class MatrixRowMap : public MatrixMapTraits<_MatrixMap> { deba@1720: public: deba@1720: typedef _MatrixMap MatrixMap; deba@1720: typedef typename MatrixMap::SecondKey Key; deba@1720: typedef typename MatrixMap::Value Value; deba@1720: deba@1720: deba@2084: /// \brief Constructor of the row map deba@2084: /// deba@2084: /// Constructor of the row map. deba@1751: MatrixRowMap(MatrixMap& _matrix, typename MatrixMap::FirstKey _row) deba@1720: : matrix(_matrix), row(_row) {} deba@1720: deba@1720: /// \brief Subscription operator deba@1720: /// deba@1720: /// Subscription operator. deba@2039: typename MatrixMapTraits::ReturnValue deba@1720: operator[](Key col) { deba@1751: return matrix(row, col); deba@1720: } deba@1720: deba@1720: /// \brief Setter function deba@1720: /// deba@1720: /// Setter function. deba@1720: void set(Key col, const Value& val) { deba@1751: matrix.set(row, col, val); deba@1720: } deba@1720: deba@1720: /// \brief Subscription operator deba@1720: /// deba@1720: /// Subscription operator. deba@2039: typename MatrixMapTraits::ConstReturnValue deba@1720: operator[](Key col) const { deba@1751: return matrix(row, col); deba@1720: } deba@1720: deba@1720: private: deba@1720: MatrixMap& matrix; deba@1751: typename MatrixMap::FirstKey row; deba@1720: }; deba@1720: deba@1720: /// \brief Map for the row view of the matrix deba@1720: /// alpar@2072: /// \ingroup matrices deba@1720: /// Map for the row view of the matrix. alpar@2072: /// deba@1720: template deba@2039: class ConstMatrixRowMap : public MatrixMapTraits<_MatrixMap> { deba@1720: public: deba@1720: typedef _MatrixMap MatrixMap; deba@1751: typedef typename MatrixMap::SecondKey Key; deba@1720: typedef typename MatrixMap::Value Value; deba@1720: deba@1751: deba@2084: /// \brief Constructor of the row map deba@2084: /// deba@2084: /// Constructor of the row map. deba@1720: ConstMatrixRowMap(const MatrixMap& _matrix, deba@1751: typename MatrixMap::FirstKey _row) deba@1720: : matrix(_matrix), row(_row) {} deba@1720: deba@1720: /// \brief Subscription operator deba@1720: /// deba@1720: /// Subscription operator. deba@2039: typename MatrixMapTraits::ConstReturnValue deba@1720: operator[](Key col) const { deba@1751: return matrix(row, col); deba@1720: } deba@1720: deba@1720: private: deba@1720: const MatrixMap& matrix; deba@1751: typename MatrixMap::FirstKey row; deba@1720: }; deba@1720: deba@2084: /// \ingroup matrices deba@2084: /// deba@1720: /// \brief Gives back a row view of the matrix map deba@1720: /// deba@1720: /// Gives back a row view of the matrix map. alpar@2072: /// deba@2084: /// \sa MatrixRowMap deba@2084: /// \sa ConstMatrixRowMap deba@1720: template deba@1720: MatrixRowMap matrixRowMap(MatrixMap& matrixMap, deba@1751: typename MatrixMap::FirstKey row) { deba@1720: return MatrixRowMap(matrixMap, row); deba@1720: } deba@1720: deba@1720: template deba@1751: ConstMatrixRowMap deba@1751: matrixRowMap(const MatrixMap& matrixMap, typename MatrixMap::FirstKey row) { deba@1720: return ConstMatrixRowMap(matrixMap, row); deba@1720: } deba@1720: alpar@2072: /// \brief Map for the column view of the matrix deba@1751: /// alpar@2072: /// \ingroup matrices alpar@2072: /// Map for the column view of the matrix. alpar@2072: /// deba@1751: template deba@2039: class MatrixColMap : public MatrixMapTraits<_MatrixMap> { deba@1751: public: deba@1751: typedef _MatrixMap MatrixMap; deba@1751: typedef typename MatrixMap::FirstKey Key; deba@1751: typedef typename MatrixMap::Value Value; deba@1751: deba@2084: /// \brief Constructor of the column map deba@2084: /// deba@2084: /// Constructor of the column map. deba@1751: MatrixColMap(MatrixMap& _matrix, typename MatrixMap::SecondKey _col) deba@1751: : matrix(_matrix), col(_col) {} deba@1751: deba@1751: /// \brief Subscription operator deba@1751: /// deba@1751: /// Subscription operator. deba@2039: typename MatrixMapTraits::ReturnValue deba@1751: operator[](Key row) { deba@1751: return matrix(row, col); deba@1751: } deba@1751: deba@1751: /// \brief Setter function deba@1751: /// deba@1751: /// Setter function. deba@1751: void set(Key row, const Value& val) { deba@1751: matrix.set(row, col, val); deba@1751: } deba@1751: deba@1751: /// \brief Subscription operator deba@1751: /// deba@1751: /// Subscription operator. deba@2039: typename MatrixMapTraits::ConstReturnValue deba@1751: operator[](Key row) const { deba@1751: return matrix(row, col); deba@1751: } deba@1751: deba@1751: private: deba@1751: MatrixMap& matrix; deba@1751: typename MatrixMap::SecondKey col; deba@1751: }; deba@1751: alpar@2072: /// \brief Map for the column view of the matrix deba@1751: /// alpar@2072: /// \ingroup matrices alpar@2072: /// Map for the column view of the matrix. alpar@2072: /// deba@1751: template deba@2039: class ConstMatrixColMap : public MatrixMapTraits<_MatrixMap> { deba@1751: public: deba@1751: typedef _MatrixMap MatrixMap; deba@1751: typedef typename MatrixMap::FirstKey Key; deba@1751: typedef typename MatrixMap::Value Value; deba@1751: deba@2084: /// \brief Constructor of the column map deba@2084: /// deba@2084: /// Constructor of the column map. deba@1751: ConstMatrixColMap(const MatrixMap& _matrix, deba@1751: typename MatrixMap::SecondKey _col) deba@1751: : matrix(_matrix), col(_col) {} deba@1751: deba@1751: /// \brief Subscription operator deba@1751: /// deba@1751: /// Subscription operator. deba@2039: typename MatrixMapTraits::ConstReturnValue deba@1751: operator[](Key row) const { deba@1751: return matrix(row, col); deba@1751: } deba@1751: deba@1751: private: deba@1751: const MatrixMap& matrix; deba@1751: typename MatrixMap::SecondKey col; deba@1751: }; deba@1751: deba@2084: /// \ingroup matrices deba@2084: /// alpar@2072: /// \brief Gives back a column view of the matrix map deba@1751: /// alpar@2072: /// Gives back a column view of the matrix map. alpar@2072: /// deba@2084: /// \sa MatrixColMap deba@2084: /// \sa ConstMatrixColMap deba@1751: template deba@1751: MatrixColMap matrixColMap(MatrixMap& matrixMap, deba@1751: typename MatrixMap::SecondKey col) { deba@1751: return MatrixColMap(matrixMap, col); deba@1751: } deba@1751: deba@1751: template deba@1751: ConstMatrixColMap deba@1751: matrixColMap(const MatrixMap& matrixMap, typename MatrixMap::SecondKey col) { deba@1751: return ConstMatrixColMap(matrixMap, col); deba@1751: } deba@1751: deba@1720: /// \brief Container for store values for each ordered pair of graph items deba@1720: /// alpar@2072: /// \ingroup matrices alpar@1757: /// This data structure can strore for each pair of the same item deba@1720: /// type a value. It increase the size of the container when the deba@1720: /// associated graph modified, so it updated automaticly whenever deba@1720: /// it is needed. deba@1720: template deba@1720: class DynamicMatrixMap deba@1999: : protected ItemSetTraits<_Graph, _Item>::ItemNotifier::ObserverBase { deba@1720: public: deba@1999: typedef typename ItemSetTraits<_Graph, _Item>::ItemNotifier::ObserverBase deba@1999: Parent; deba@1720: deba@1720: typedef _Graph Graph; deba@1720: typedef _Item Key; deba@1720: deba@1720: typedef _Item FirstKey; deba@1720: typedef _Item SecondKey; deba@1720: typedef _Value Value; deba@1720: deba@1720: typedef True ReferenceMapTag; deba@1720: deba@1720: private: deba@1720: deba@1720: typedef std::vector Container; deba@1720: deba@1720: public: deba@1720: deba@1720: typedef typename Container::reference Reference; deba@1720: typedef typename Container::const_reference ConstReference; deba@1720: deba@1720: /// \brief Creates an item matrix for the given graph deba@1720: /// deba@1720: /// Creates an item matrix for the given graph. deba@1720: DynamicMatrixMap(const Graph& _graph) deba@1999: : values(size(_graph.maxId(Key()) + 1)) { deba@2384: Parent::attach(_graph.notifier(Key())); deba@1720: } deba@1720: deba@1720: /// \brief Creates an item matrix for the given graph deba@1720: /// deba@1720: /// Creates an item matrix for the given graph and assigns for each deba@1720: /// pairs of keys the given parameter. deba@1720: DynamicMatrixMap(const Graph& _graph, const Value& _val) deba@1999: : values(size(_graph.maxId(Key()) + 1), _val) { deba@2384: Parent::attach(_graph.notifier(Key())); deba@1720: } deba@1720: deba@2039: ///\brief The assignement operator. deba@2039: /// deba@2039: ///It allow to assign a map to an other. deba@2039: DynamicMatrixMap& operator=(const DynamicMatrixMap& _cmap){ deba@2039: return operator=(_cmap); deba@2039: } deba@2039: deba@2039: ///\brief Template assignement operator. deba@2039: /// deba@2039: ///It copy the element of the given map to its own container. The deba@2039: ///type of the two map shall be the same. deba@2039: template deba@2039: DynamicMatrixMap& operator=(const CMap& _cmap){ alpar@2260: checkConcept, CMap>(); deba@2384: typename Parent::Notifier* notifier = Parent::notifier(); deba@2039: Key first, second; deba@2039: for(notifier->first(first); first != INVALID; deba@2039: notifier->next(first)){ deba@2039: for(notifier->first(second); second != INVALID; deba@2039: notifier->next(second)){ deba@2039: set(first, second, _cmap(first, second)); deba@2039: } deba@2039: } deba@2039: return *this; deba@2039: } deba@2039: deba@1720: /// \brief Gives back the value assigned to the \c first - \c second deba@1720: /// ordered pair. deba@1720: /// deba@1720: /// Gives back the value assigned to the \c first - \c second ordered pair. deba@1720: ConstReference operator()(const Key& first, const Key& second) const { deba@2384: return values[index(Parent::notifier()->id(first), deba@2384: Parent::notifier()->id(second))]; deba@1720: } deba@1720: deba@1720: /// \brief Gives back the value assigned to the \c first - \c second deba@1720: /// ordered pair. deba@1720: /// deba@1720: /// Gives back the value assigned to the \c first - \c second ordered pair. deba@1720: Reference operator()(const Key& first, const Key& second) { deba@2384: return values[index(Parent::notifier()->id(first), deba@2384: Parent::notifier()->id(second))]; deba@1720: } deba@1720: deba@1720: /// \brief Setter function for the matrix map. deba@1720: /// deba@1720: /// Setter function for the matrix map. deba@1720: void set(const Key& first, const Key& second, const Value& val) { deba@2384: values[index(Parent::notifier()->id(first), deba@2384: Parent::notifier()->id(second))] = val; deba@1720: } deba@1720: deba@1720: protected: deba@1720: deba@1720: static int index(int i, int j) { deba@1720: if (i < j) { deba@1720: return j * j + i; deba@1720: } else { deba@1720: return i * i + i + j; deba@1720: } deba@1720: } deba@1720: deba@1720: static int size(int s) { deba@1720: return s * s; deba@1720: } deba@1720: deba@1720: virtual void add(const Key& key) { deba@2386: if (size(Parent::notifier()->id(key) + 1) >= int(values.size())) { deba@2384: values.resize(size(Parent::notifier()->id(key) + 1)); deba@1720: } deba@1720: } deba@1720: deba@2305: virtual void add(const std::vector& keys) { deba@2305: int new_size = 0; deba@2386: for (int i = 0; i < int(keys.size()); ++i) { deba@2384: if (size(Parent::notifier()->id(keys[i]) + 1) >= new_size) { deba@2384: new_size = size(Parent::notifier()->id(keys[i]) + 1); deba@2305: } deba@2305: } deba@2386: if (new_size > int(values.size())) { deba@2305: values.resize(new_size); deba@2305: } deba@2305: } deba@2305: deba@1720: virtual void erase(const Key&) {} deba@1720: deba@2305: virtual void erase(const std::vector&) {} deba@2305: deba@1720: virtual void build() { deba@2384: values.resize(size(Parent::notifier()->maxId() + 1)); deba@1720: } deba@1720: deba@1720: virtual void clear() { deba@1720: values.clear(); deba@1720: } deba@1720: deba@1720: private: deba@1720: std::vector values; deba@1720: }; deba@1720: deba@1720: /// \brief Container for store values for each unordered pair of graph items deba@1720: /// alpar@2072: /// \ingroup matrices alpar@1757: /// This data structure can strore for each pair of the same item deba@1720: /// type a value. It increase the size of the container when the deba@1720: /// associated graph modified, so it updated automaticly whenever deba@1720: /// it is needed. deba@1720: template deba@1720: class DynamicSymMatrixMap deba@1999: : protected ItemSetTraits<_Graph, _Item>::ItemNotifier::ObserverBase { deba@1720: public: deba@1999: typedef typename ItemSetTraits<_Graph, _Item>::ItemNotifier::ObserverBase deba@1999: Parent; deba@1720: deba@1720: typedef _Graph Graph; deba@1720: typedef _Item Key; deba@1720: deba@1720: typedef _Item FirstKey; deba@1720: typedef _Item SecondKey; deba@1720: typedef _Value Value; deba@1720: deba@1720: typedef True ReferenceMapTag; deba@1720: deba@1720: private: deba@1720: deba@1720: typedef std::vector Container; deba@1720: deba@1720: public: deba@1720: deba@1720: typedef typename Container::reference Reference; deba@1720: typedef typename Container::const_reference ConstReference; deba@1720: deba@1720: /// \brief Creates an item matrix for the given graph deba@1720: /// deba@1720: /// Creates an item matrix for the given graph. deba@1720: DynamicSymMatrixMap(const Graph& _graph) deba@1999: : values(size(_graph.maxId(Key()) + 1)) { deba@2384: Parent::attach(_graph.notifier(Key())); deba@1720: } deba@1720: deba@1720: /// \brief Creates an item matrix for the given graph deba@1720: /// deba@1720: /// Creates an item matrix for the given graph and assigns for each deba@1720: /// pairs of keys the given parameter. deba@1720: DynamicSymMatrixMap(const Graph& _graph, const Value& _val) deba@1999: : values(size(_graph.maxId(Key()) + 1), _val) { deba@2384: Parent::attach(_graph.notifier(Key())); deba@1720: } deba@1720: deba@2039: deba@2039: ///\brief The assignement operator. deba@2039: /// deba@2039: ///It allow to assign a map to an other. alpar@2072: /// deba@2039: DynamicSymMatrixMap& operator=(const DynamicSymMatrixMap& _cmap){ deba@2039: return operator=(_cmap); deba@2039: } deba@2039: deba@2039: ///\brief Template assignement operator. deba@2039: /// deba@2039: ///It copy the element of the given map to its own container. The deba@2039: ///type of the two map shall be the same. deba@2039: template deba@2039: DynamicSymMatrixMap& operator=(const CMap& _cmap){ alpar@2260: checkConcept, CMap>(); deba@2384: typename Parent::Notifier* notifier = Parent::notifier(); deba@2039: Key first, second; deba@2039: for(notifier->first(first); first != INVALID; deba@2039: notifier->next(first)){ deba@2039: for(notifier->first(second); second != first; deba@2039: notifier->next(second)){ deba@2039: set(first, second, _cmap(first, second)); deba@2039: } deba@2039: set(first, first, _cmap(first, first)); deba@2039: } deba@2039: return *this; deba@2039: } deba@2039: deba@1720: /// \brief Gives back the value assigned to the \c first - \c second deba@1720: /// unordered pair. deba@1720: /// deba@1720: /// Gives back the value assigned to the \c first - \c second unordered deba@1720: /// pair. deba@1720: ConstReference operator()(const Key& first, const Key& second) const { deba@2384: return values[index(Parent::notifier()->id(first), deba@2384: Parent::notifier()->id(second))]; deba@1720: } deba@1720: deba@1720: /// \brief Gives back the value assigned to the \c first - \c second deba@1720: /// unordered pair. deba@1720: /// deba@1720: /// Gives back the value assigned to the \c first - \c second unordered deba@1720: /// pair. deba@1720: Reference operator()(const Key& first, const Key& second) { deba@2384: return values[index(Parent::notifier()->id(first), deba@2384: Parent::notifier()->id(second))]; deba@1720: } deba@1720: deba@1720: /// \brief Setter function for the matrix map. deba@1720: /// deba@1720: /// Setter function for the matrix map. alpar@2072: /// deba@1720: void set(const Key& first, const Key& second, const Value& val) { deba@2384: values[index(Parent::notifier()->id(first), deba@2384: Parent::notifier()->id(second))] = val; deba@1720: } deba@1720: deba@1720: protected: deba@1720: deba@1720: static int index(int i, int j) { deba@1720: if (i < j) { deba@1720: return j * (j + 1) / 2 + i; deba@1720: } else { deba@1720: return i * (i + 1) / 2 + j; deba@1720: } deba@1720: } deba@1720: deba@1720: static int size(int s) { deba@1720: return s * (s + 1) / 2; deba@1720: } deba@1720: deba@1720: virtual void add(const Key& key) { deba@2386: if (size(Parent::notifier()->id(key) + 1) >= int(values.size())) { deba@2384: values.resize(size(Parent::notifier()->id(key) + 1)); deba@1720: } deba@1720: } deba@1720: deba@2305: virtual void add(const std::vector& keys) { deba@2305: int new_size = 0; deba@2386: for (int i = 0; i < int(keys.size()); ++i) { deba@2384: if (size(Parent::notifier()->id(keys[i]) + 1) >= new_size) { deba@2384: new_size = size(Parent::notifier()->id(keys[i]) + 1); deba@2305: } deba@2305: } deba@2386: if (new_size > int(values.size())) { deba@2305: values.resize(new_size); deba@2305: } deba@2305: } deba@2305: deba@1720: virtual void erase(const Key&) {} deba@1720: deba@2305: virtual void erase(const std::vector&) {} deba@2305: deba@1720: virtual void build() { deba@2384: values.resize(size(Parent::notifier()->maxId() + 1)); deba@1720: } deba@1720: deba@1720: virtual void clear() { deba@1720: values.clear(); deba@1720: } deba@1720: deba@1720: private: deba@1720: std::vector values; deba@1720: }; deba@2039: deba@2039: ///\brief Dynamic Asymmetric Matrix Map. deba@2039: /// alpar@2072: ///\ingroup matrices deba@2039: ///Dynamic Asymmetric Matrix Map. Container for store values for each deba@2039: ///ordered pair of containers items. This data structure can store deba@2039: ///data with different key types from different container types. It deba@2039: ///increases the size of the container if the linked containers deba@2039: ///content change, so it is updated automaticly whenever it is deba@2039: ///needed. deba@2039: /// alpar@2260: ///This map meet with the concepts::ReferenceMatrixMap called as deba@2039: ///"ReferenceMatrixMap". deba@2039: /// deba@2376: ///\warning Do not use this map type when the two item sets are deba@2376: ///equal or based on the same item set. deba@2376: /// deba@2039: ///\param _FirstContainer the desired type of first container. It is deba@2039: ///ususally a Graph type, but can be any type with alteration deba@2039: ///property. deba@2039: /// deba@2039: ///\param _FirstContainerItem the nested type of the deba@2039: ///FirstContainer. It is usually a graph item as Node, Edge, deba@2039: ///etc. This type will be the FirstKey type. deba@2039: /// deba@2039: ///\param _SecondContainer the desired type of the second deba@2039: ///container. It is usualy a Graph type, but can be any type with deba@2039: ///alteration property. deba@2039: /// deba@2039: ///\param _SecondContainerItem the nested type of the deba@2039: ///SecondContainer. It is usually a graph item such as Node, Edge, deba@2039: ///UEdge, etc. This type will be the SecondKey type. deba@2039: /// deba@2039: ///\param _Value the type of the strored values in the container. deba@2039: /// deba@2039: /// \author Janos Nagy deba@2039: template deba@2039: class DynamicAsymMatrixMap{ deba@2039: public: deba@2039: deba@2039: ///The first key type. deba@2039: typedef _FirstContainerItem FirstKey; deba@2039: deba@2039: ///The second key type. deba@2039: typedef _SecondContainerItem SecondKey; deba@2039: deba@2039: ///The value type of the map. deba@2039: typedef _Value Value; deba@2039: deba@2039: ///Indicates it is a reference map. deba@2039: typedef True ReferenceMapTag; deba@2039: deba@2039: protected: deba@2039: deba@2039: ///\brief Proxy class for the first key type. deba@2039: /// deba@2039: ///The proxy class belongs to the FirstKey type. It is necessary because deba@2039: ///if one want use the same conatainer types and same nested types but on deba@2039: ///other instances of containers than due to the type equiality of nested deba@2039: ///types it requires a proxy mechanism. deba@2039: class FirstKeyProxy deba@2039: : protected deba@2039: ItemSetTraits<_FirstContainer,_FirstContainerItem>:: deba@2039: ItemNotifier::ObserverBase deba@2039: { deba@2039: deba@2039: public: deba@2039: deba@2039: friend class DynamicAsymMatrixMap; deba@2039: deba@2039: ///Constructor. deba@2039: FirstKeyProxy(DynamicAsymMatrixMap& _map) : _owner(_map) { } deba@2039: protected: deba@2039: deba@2039: ///\brief Add a new FirstKey to the map. deba@2039: /// deba@2039: ///It adds a new FirstKey to the map. It is called by the deba@2039: ///observer notifier and it is ovverride the add() virtual deba@2039: ///member function in the observer base. It will call the deba@2039: ///maps addFirstKey() function. deba@2039: virtual void add(const FirstKey& _firstKey){ deba@2039: _owner.addFirstKey(_firstKey); deba@2039: } deba@2039: deba@2039: ///\brief Add more new FirstKey to the map. deba@2039: /// deba@2039: ///It adds more new FirstKey to the map. It is called by the deba@2039: ///observer notifier and it is ovverride the add() virtual deba@2039: ///member function in the observer base. It will call the deba@2039: ///map's addFirstKeys() function. deba@2039: virtual void add(const std::vector& _firstKeys){ deba@2039: _owner.addFirstKeys(_firstKeys); deba@2039: } deba@2039: deba@2039: ///\brief Erase a FirstKey from the map. deba@2039: /// deba@2039: ///Erase a FirstKey from the map. It called by the observer deba@2039: ///notifier and it overrides the erase() virtual member deba@2039: ///function of the observer base. It will call the map's deba@2039: ///eraseFirstKey() function. deba@2039: virtual void erase(const FirstKey& _firstKey){ deba@2039: _owner.eraseFirstKey(_firstKey); deba@2039: } deba@2039: deba@2039: ///\brief Erase more FirstKey from the map. deba@2039: /// deba@2039: ///Erase more FirstKey from the map. It called by the deba@2039: ///observer notifier and it overrides the erase() virtual deba@2039: ///member function of the observer base. It will call the deba@2039: ///map's eraseFirstKeys() function. deba@2039: virtual void erase(const std::vector& _firstKeys){ deba@2039: _owner.eraseFirstKeys(_firstKeys); deba@2039: } deba@2039: deba@2039: ///\brief Builds the map. deba@2039: /// deba@2039: ///It buildes the map. It called by the observer notifier deba@2039: ///and it overrides the build() virtual member function of deba@2039: ///the observer base. It will call the map's build() deba@2039: ///function. deba@2039: virtual void build() { deba@2039: _owner.build(); deba@2039: //_owner.buildFirst(); deba@2039: } deba@2039: deba@2039: ///\brief Clear the map. deba@2039: /// deba@2039: ///It erases all items from the map. It called by the deba@2039: ///observer notifier and it overrides the clear() virtual deba@2039: ///memeber function of the observer base. It will call the deba@2039: ///map's clear() function. deba@2039: virtual void clear() { deba@2039: _owner.clear(); deba@2039: //_owner.clearFirst(); deba@2039: } deba@2039: private: deba@2039: deba@2039: ///The map type for it is linked. deba@2039: DynamicAsymMatrixMap& _owner; alpar@2072: };//END OF FIRSTKEYPROXY deba@2039: deba@2039: ///\brief Proxy class for the second key type. deba@2039: /// ladanyi@2047: ///The proxy class belongs to the SecondKey type. It is deba@2039: ///necessary because if one want use the same conatainer types deba@2039: ///and same nested types but on other instances of containers deba@2039: ///than due to the type equiality of nested types it requires a deba@2039: ///proxy mechanism. deba@2039: class SecondKeyProxy deba@2039: : protected deba@2039: ItemSetTraits<_SecondContainer, _SecondContainerItem>:: deba@2039: ItemNotifier::ObserverBase { deba@2039: deba@2039: public: deba@2039: deba@2039: friend class DynamicAsymMatrixMap; deba@2039: ///Constructor. deba@2039: SecondKeyProxy(DynamicAsymMatrixMap& _map) : _owner(_map) { } deba@2039: deba@2039: protected: deba@2039: deba@2039: ///\brief Add a new SecondKey to the map. deba@2039: /// deba@2039: ///It adds a new SecondKey to the map. It is called by the deba@2039: ///observer notifier and it is ovverride the add() virtual deba@2039: ///member function in the observer base. It will call the deba@2039: ///maps addSecondKey() function. deba@2039: virtual void add(const SecondKey& _secondKey){ deba@2039: _owner.addSecondKey(_secondKey); deba@2039: } deba@2039: deba@2039: ///\brief Add more new SecondKey to the map. deba@2039: /// deba@2039: ///It adds more new SecondKey to the map. It is called by deba@2039: ///the observer notifier and it is ovverride the add() deba@2039: ///virtual member function in the observer base. It will deba@2039: ///call the maps addSecondKeys() function. deba@2039: virtual void add(const std::vector& _secondKeys){ deba@2039: _owner.addSecondKeys(_secondKeys); deba@2039: } deba@2039: deba@2039: ///\brief Erase a SecondKey from the map. deba@2039: /// deba@2039: ///Erase a SecondKey from the map. It called by the observer deba@2039: ///notifier and it overrides the erase() virtual member deba@2039: ///function of the observer base. It will call the map's deba@2039: ///eraseSecondKey() function. deba@2039: virtual void erase(const SecondKey& _secondKey){ deba@2039: _owner.eraseSecondKey(_secondKey); deba@2039: } deba@2039: deba@2039: ///\brief Erase more SecondKeys from the map. deba@2039: /// deba@2039: ///Erase more SecondKey from the map. It called by the deba@2039: ///observer notifier and it overrides the erase() virtual deba@2039: ///member function of the observer base. It will call the deba@2039: ///map's eraseSecondKeys() function. deba@2039: virtual void erase(const std::vector& _secondKeys){ deba@2039: _owner.eraseSecondKeys(_secondKeys); deba@2039: } deba@2039: deba@2039: ///\brief Builds the map. deba@2039: /// deba@2039: ///It buildes the map. It called by the observer notifier deba@2039: ///and it overrides the build() virtual member function of deba@2039: ///the observer base. It will call the map's build() deba@2039: ///function. deba@2039: virtual void build() { deba@2039: _owner.build(); deba@2039: } deba@2039: deba@2039: ///\brief Clear the map. deba@2039: /// deba@2039: ///It erases all items from the map. It called by the deba@2039: ///observer notifier and it overrides the clear() virtual deba@2039: ///memeber function of the observer base. It will call the deba@2039: ///map's clear() function. deba@2039: virtual void clear() { deba@2039: _owner.clear(); deba@2039: //_owner.clearFirst(); deba@2039: } deba@2039: private: deba@2039: deba@2039: ///The type of map for which it is attached. deba@2039: DynamicAsymMatrixMap& _owner; alpar@2072: };//END OF SECONDKEYPROXY deba@2039: deba@2039: private: deba@2039: deba@2039: /// \e deba@2039: typedef std::vector Container; deba@2039: deba@2039: ///The type of constainer which stores the values of the map. deba@2039: typedef std::vector DContainer; deba@2039: deba@2039: ///The std:vector type which contains the data deba@2039: DContainer values; deba@2039: deba@2039: ///Member for the first proxy class deba@2039: FirstKeyProxy _first_key_proxy; deba@2039: deba@2039: ///Member for the second proxy class deba@2039: SecondKeyProxy _second_key_proxy; deba@2039: deba@2039: public: deba@2039: deba@2039: ///The refernce type of the map. deba@2039: typedef typename Container::reference Reference; deba@2039: deba@2039: ///The const reference type of the constainer. deba@2039: typedef typename Container::const_reference ConstReference; deba@2039: deba@2039: ///\brief Constructor what create the map for the two containers type. deba@2039: /// deba@2039: ///Creates the matrix map and initialize the values with Value() deba@2039: DynamicAsymMatrixMap(const _FirstContainer& _firstContainer, deba@2039: const _SecondContainer& _secondContainer) deba@2039: : values(DContainer(_firstContainer.maxId(FirstKey())+1, deba@2039: Container(_secondContainer.maxId(SecondKey())+1))), deba@2039: _first_key_proxy(*this), deba@2039: _second_key_proxy(*this) deba@2039: { deba@2384: _first_key_proxy.attach(_firstContainer.notifier(FirstKey())); deba@2384: _second_key_proxy.attach(_secondContainer.notifier(SecondKey())); deba@2039: } deba@2039: deba@2039: ///\brief Constructor what create the map for the two containers type. deba@2039: /// deba@2039: ///Creates the matrix map and initialize the values with the given _value deba@2039: DynamicAsymMatrixMap(const _FirstContainer& _firstContainer, deba@2039: const _SecondContainer& _secondContainer, deba@2039: const Value& _value) deba@2039: : values(DContainer(_firstContainer.maxId(FirstKey())+1, deba@2039: Container(_secondContainer.maxId(SecondKey())+1, deba@2039: _value))), deba@2039: _first_key_proxy(*this), deba@2039: _second_key_proxy(*this) deba@2039: { deba@2384: _first_key_proxy.attach(_firstContainer.notifier(FirstKey())); deba@2384: _second_key_proxy.attach(_secondContainer.notifier(SecondKey())); deba@2039: } deba@2039: deba@2039: ///\brief Copy constructor. deba@2039: /// deba@2039: ///The copy constructor of the map. deba@2039: DynamicAsymMatrixMap(const DynamicAsymMatrixMap& _copy) deba@2039: : _first_key_proxy(*this), _second_key_proxy(*this) { deba@2039: if(_copy._first_key_proxy.attached() && deba@2039: _copy._second_key_proxy.attached()){ deba@2384: _first_key_proxy.attach(*_copy._first_key_proxy.notifier()); deba@2384: _second_key_proxy.attach(*_copy._second_key_proxy.notifier()); deba@2039: values = _copy.values; deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Destructor deba@2039: /// deba@2039: ///Destructor what detach() from the attached objects. May this deba@2039: ///function is not necessary because the destructor of deba@2039: ///ObserverBase do the same. deba@2039: ~DynamicAsymMatrixMap() { deba@2039: if(_first_key_proxy.attached()){ deba@2039: _first_key_proxy.detach(); deba@2039: } deba@2039: if(_second_key_proxy.attached()){ deba@2039: _second_key_proxy.detach(); deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Gives back the value assigned to the \c first - \c deba@2039: ///second ordered pair. deba@2039: /// deba@2039: ///Gives back the value assigned to the \c first - \c second deba@2039: ///ordered pair. deba@2039: Reference operator()(const FirstKey& _first, const SecondKey& _second) { deba@2384: return values[_first_key_proxy.notifier()->id(_first)] deba@2384: [_second_key_proxy.notifier()->id(_second)]; deba@2039: } deba@2039: deba@2039: ///\brief Gives back the value assigned to the \c first - \c deba@2039: ///second ordered pair. deba@2039: /// deba@2039: ///Gives back the value assigned to the \c first - \c second deba@2039: ///ordered pair. deba@2039: ConstReference operator()(const FirstKey& _first, deba@2039: const SecondKey& _second) const { deba@2384: return values[_first_key_proxy.notifier()->id(_first)] deba@2384: [_second_key_proxy.notifier()->id(_second)]; deba@2039: } deba@2039: deba@2039: ///\brief Setter function for this matrix map. deba@2039: /// deba@2039: ///Setter function for this matrix map. deba@2039: void set(const FirstKey& first, const SecondKey& second, deba@2039: const Value& value){ deba@2384: values[_first_key_proxy.notifier()->id(first)] deba@2384: [_second_key_proxy.notifier()->id(second)] = value; deba@2039: } deba@2039: deba@2039: ///\brief The assignement operator. deba@2039: /// deba@2039: ///It allow to assign a map to an other. It deba@2039: DynamicAsymMatrixMap& operator=(const DynamicAsymMatrixMap& _cmap){ deba@2039: return operator=(_cmap); deba@2039: } deba@2039: deba@2039: ///\brief Template assignement operator. deba@2039: /// deba@2039: ///It copy the element of the given map to its own container. The deba@2039: ///type of the two map shall be the same. deba@2039: template deba@2039: DynamicAsymMatrixMap& operator=(const CMap& _cdmap){ alpar@2260: checkConcept, CMap>(); deba@2039: const typename FirstKeyProxy::Notifier* notifierFirstKey = deba@2384: _first_key_proxy.notifier(); deba@2039: const typename SecondKeyProxy::Notifier* notifierSecondKey = deba@2384: _second_key_proxy.notifier(); deba@2039: FirstKey itemFirst; deba@2039: SecondKey itemSecond; deba@2039: for(notifierFirstKey->first(itemFirst); itemFirst != INVALID; deba@2039: notifierFirstKey->next(itemFirst)){ deba@2039: for(notifierSecondKey->first(itemSecond); itemSecond != INVALID; deba@2039: notifierSecondKey->next(itemSecond)){ deba@2039: set(itemFirst, itemSecond, _cdmap(itemFirst,itemSecond)); deba@2039: } deba@2039: } deba@2039: return *this; deba@2039: } deba@2039: deba@2039: protected: deba@2039: deba@2039: ///\brief Add a new FirstKey to the map. deba@2039: /// deba@2039: ///It adds a new FirstKey to the map. It is called by the observer deba@2039: ///class belongs to the FirstKey type. deba@2039: void addFirstKey(const FirstKey& firstKey) { deba@2386: int size = int(values.size()); deba@2384: if( _first_key_proxy.notifier()->id(firstKey)+1 >= size ){ deba@2384: values.resize(_first_key_proxy.notifier()->id(firstKey)+1); deba@2386: if( int(values[0].size()) != 0 ){ deba@2386: int innersize = int(values[0].size()); deba@2386: for(int i = size; i < int(values.size());++i){ deba@2039: (values[i]).resize(innersize); deba@2039: } deba@2384: }else if(_second_key_proxy.notifier()->maxId() >= 0){ deba@2384: int innersize = _second_key_proxy.notifier()->maxId(); deba@2386: for(int i = 0; i < int(values.size()); ++i){ deba@2039: values[0].resize(innersize); deba@2039: } deba@2039: } deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Adds more new FirstKeys to the map. deba@2039: /// deba@2039: ///It adds more new FirstKeys to the map. It called by the deba@2039: ///observer class belongs to the FirstKey type. deba@2039: void addFirstKeys(const std::vector& firstKeys){ deba@2039: int max = values.size() - 1; deba@2386: for(int i = 0; i < int(firstKeys.size()); ++i){ deba@2384: int id = _first_key_proxy.notifier()->id(firstKeys[i]); deba@2039: if(max < id){ deba@2039: max = id; deba@2039: } deba@2039: } deba@2386: int size = int(values.size()); deba@2039: if(max >= size){ deba@2039: values.resize(max + 1); deba@2386: if( int(values[0].size()) != 0){ deba@2386: int innersize = int(values[0].size()); deba@2386: for(int i = size; i < (max + 1); ++i){ deba@2039: values[i].resize(innersize); deba@2039: } deba@2384: }else if(_second_key_proxy.notifier()->maxId() >= 0){ deba@2384: int innersize = _second_key_proxy.notifier()->maxId(); deba@2386: for(int i = 0; i < int(values.size()); ++i){ deba@2039: values[i].resize(innersize); deba@2039: } deba@2039: } deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Add a new SecondKey to the map. deba@2039: /// deba@2039: ///It adds a new SecondKey to the map. It is called by the deba@2039: ///observer class belongs to the SecondKey type. deba@2039: void addSecondKey(const SecondKey& secondKey) { deba@2039: if(values.size() == 0){ deba@2039: return; deba@2039: } deba@2384: int id = _second_key_proxy.notifier()->id(secondKey); deba@2386: if(id >= int(values[0].size())){ deba@2386: for(int i = 0; i < int(values.size());++i){ deba@2039: values[i].resize(id+1); deba@2039: } deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Adds more new SecondKeys to the map. deba@2039: /// deba@2039: ///It adds more new SecondKeys to the map. It called by the deba@2039: ///observer class belongs to the SecondKey type. deba@2039: void addSecondKeys(const std::vector& secondKeys){ deba@2039: if(values.size() == 0){ deba@2039: return; deba@2039: } deba@2039: int max = values[0].size(); deba@2386: for(int i = 0; i < int(secondKeys.size()); ++i){ deba@2384: int id = _second_key_proxy.notifier()->id(secondKeys[i]); deba@2039: if(max < id){ deba@2039: max = id; deba@2039: } deba@2039: } deba@2386: if(max > int(values[0].size())){ deba@2386: for(int i = 0; i < int(values.size()); ++i){ deba@2039: values[i].resize(max + 1); deba@2039: } deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Erase a FirstKey from the map. deba@2039: /// deba@2039: ///Erase a FirstKey from the map. It called by the observer deba@2039: ///class belongs to the FirstKey type. deba@2039: void eraseFirstKey(const FirstKey& first) { deba@2384: int id = _first_key_proxy.notifier()->id(first); deba@2386: for(int i = 0; i < int(values[id].size()); ++i){ deba@2039: values[id][i] = Value(); deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Erase more FirstKey from the map. deba@2039: /// deba@2039: ///Erase more FirstKey from the map. It called by the observer deba@2039: ///class belongs to the FirstKey type. deba@2039: void eraseFirstKeys(const std::vector& firstKeys) { deba@2386: for(int j = 0; j < int(firstKeys.size()); ++j){ deba@2384: int id = _first_key_proxy.notifier()->id(firstKeys[j]); deba@2386: for(int i = 0; i < int(values[id].size()); ++i){ deba@2039: values[id][i] = Value(); deba@2039: } deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Erase a SecondKey from the map. deba@2039: /// deba@2039: ///Erase a SecondKey from the map. It called by the observer class deba@2039: ///belongs to the SecondKey type. deba@2039: void eraseSecondKey(const SecondKey& second) { deba@2039: if(values.size() == 0){ deba@2039: return; deba@2039: } deba@2384: int id = _second_key_proxy.notifier()->id(second); deba@2386: for(int i = 0; i < int(values.size()); ++i){ deba@2039: values[i][id] = Value(); deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Erase more SecondKey from the map. deba@2039: /// deba@2039: ///Erase more SecondKey from the map. It called by the observer deba@2039: ///class belongs to the SecondKey type. deba@2039: void eraseSecondKeys(const std::vector& secondKeys) { deba@2039: if(values.size() == 0){ deba@2039: return; deba@2039: } deba@2386: for(int j = 0; j < int(secondKeys.size()); ++j){ deba@2384: int id = _second_key_proxy.notifier()->id(secondKeys[j]); deba@2386: for(int i = 0; i < int(values.size()); ++i){ deba@2039: values[i][id] = Value(); deba@2039: } deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Builds the map. deba@2039: /// deba@2039: ///It buildes the map. It is called by the observer class belongs deba@2039: ///to the FirstKey or SecondKey type. deba@2039: void build() { deba@2384: values.resize(_first_key_proxy.notifier()->maxId()); deba@2386: for(int i = 0; i< int(values.size()); ++i){ deba@2384: values[i].resize(_second_key_proxy.notifier()->maxId()); deba@2039: } deba@2039: } deba@2039: deba@2039: ///\brief Clear the map. deba@2039: /// deba@2039: ///It erases all items from the map. It is called by the observer class deba@2039: ///belongs to the FirstKey or SecondKey type. deba@2039: void clear() { deba@2386: for(int i = 0; i < int(values.size()); ++i) { deba@2039: values[i].clear(); deba@2039: } deba@2039: values.clear(); deba@2039: } deba@2039: deba@2039: }; deba@2039: deba@2039: deba@1720: deba@1720: } deba@1720: deba@1720: #endif