doc/adaptor_references.dox
author athos
Thu, 09 Jun 2005 15:12:01 +0000
changeset 1461 9f99ede44d59
child 1590 ba2cb5006358
permissions -rw-r--r--
Bugfix.
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namespace lemon {
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/*!
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\page adaptor-references Smart Reference Handling
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The adaptor classes are very useful tools in the lemon library. It makes
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possible to create various data view of the current data structures without
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of the copy of them. This makes the lemon programming efficient and 
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consederably fast.
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\section problem The problem
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The adaptors usually use references or pointers to reference to an 
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existing data structure. We may use an algorithm in the next way:
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\code
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function_algorithm(adaptor(structure));
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\endcode 
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But what about the class algorithms:
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\code
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class_algorithm alg;
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alg.add(adaptor(structure));
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alg.run();
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\endcode
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The algorithm store a reference to the given structure. It is a created
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as temporarly and when the expression of the \c add() function is evaluated it
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will be destructed. It is very dangerous handling of the adaptors.
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\section solution The solution
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We made reference to a temporarly constructed adaptor but we should make
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a copy of the adaptor when it is given as parameter to a class.
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It is not impossible with a little tranformation of the code.
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Let's first create some helper class:
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\code
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template <typename _Type, typename Enable = void>
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struct SmartConstReference {
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  typedef const _Type& Type;
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};
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template <typename _Type>
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struct SmartConstReference<
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  _Type, 
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  typename enable_if<typename _Type::NeedCopy, void>::type
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> {
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  typedef const _Type Type;
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};
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\endcode
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Then we can place NeedCopy tags in the adaptor classes:
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\code
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template<class M1,class M2> 
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class AddMap {
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  typename SmartConstReference<M1>::Type m1;
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  typename SmartConstReference<M2>::Type m2;
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public:
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  typedef True NeedCopy;
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  typedef typename M1::Key Key;
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  typedef typename M1::Value Value;
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  AddMap(const M1 &_m1,const M2 &_m2) : m1(_m1), m2(_m2) {};
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  Value operator[](Key k) const {return m1[k]+m2[k];}
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};
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\endcode
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Then we can transform all of the template map and graph references to
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\c SmartConstReference<Map>::Type or \c SmartConstReference<Graph>::Type.
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This way we copy all of maps and graphs what we should copy but the
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greater data structures are not copied.
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\section not-const If the adaptor is not const
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The solution is very similar but it gives an additional problem.
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We make the same \c SmartReferences:
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\code
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template <typename _Type, typename Enable = void>
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struct SmartReference {
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  typedef _Type& Type;
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};
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template <typename _Type>
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struct SmartReference<
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  _Type, 
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  typename enable_if<typename _Type::NeedCopy, void>::type
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> {
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  typedef _Type Type;
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};
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\endcode
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Let's create a class that use it:
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\code
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template <typename Map>
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class Algorithm {
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public:
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  SmartReference<Map>::Type map;
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  Algorithm(Map& _map) : map(_map) {}
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  ...
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};
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\endcode
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But if we want to give an adaptor function as parameter
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it will be a compile error. The adaptor will be created as temporarly
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so it cannot give as reference just as const reference.
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Make more helper class:
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\code
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template <typename _Type, typename Enable = void>
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struct SmartParameter {
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  typedef _Type& Type;
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};
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template <typename _Type>
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struct SmartParameter<
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  _Type, 
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  typename enable_if<typename _Type::NeedCopy, void>::type
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> {
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  typedef const _Type& Type;
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};
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\endcode
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And the repaired code:
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\code
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template <typename Map>
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class Algorithm {
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public:
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  SmartReference<Map>::Type map;
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  Algorithm(SmartParameter<Map>::Type _map) : map(_map) {}
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  ...
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};
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\endcode
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But some times it does not help:
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\code
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class Algorithm {
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public:
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  ...
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  template <typename Map>
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  void addMap(SmartParameter<Map>::Type _map) {
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    ...
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  }
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  ...
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};
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\endcode
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Actually, it is a good code but the template parameter should
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be written because it cannot be found out from the parameter type.
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This can be solved with a bigger transformation:
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\code
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class Algorithm {
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public:
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  ...
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  template <typename Map>
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  void addMap(const Map& _map) {
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    _addMap<SmartParameter<Map>::Type, Map>(_map);
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  }
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  template <typename Map>
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  void addMap(const Map& _map) {
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    _addMap<SmartParameter<Map>::Type, Map>(_map);
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  }
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private:
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  template <typename MapParameter, typename Map>
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  void _addMap(MapParameter _map) {
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    ...
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  }
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  ...
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};
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\endcode
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This way we solved the smart referencing problem.
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\author Balazs Dezso
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*/
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}