source: lemon-0.x/src/work/alpar/emptygraph.h @ 242:b255f25ad394

// -*- c++ -*-
#ifndef HUGO_EMPTYGRAPH_H
#define HUGO_EMPTYGRAPH_H

///\file
///\brief Declaration of GraphSkeleton.

#include <invalid.h>

/// The namespace of HugoLib
namespace hugo {

  // @defgroup empty_graph The GraphSkeleton class
  // @{

  /// An empty graph class.
  
  /// This class provides all the common features of a graph structure,
  /// however completely without implementations and real data structures
  /// behind the interface.
  /// All graph algorithms should compile with this class, but it will not
  /// run properly, of course.
  ///
  /// It can be used for checking the interface compatibility,
  /// or it can serve as a skeleton of a new graph structure.
  /// 
  /// Also, you will find here the full documentation of a certain graph
  /// feature, the documentation of a real graph imlementation
  /// like @ref ListGraph or
  /// @ref SmartGraph will just refer to this structure.
  class GraphSkeleton
  {
  public:
    
    /// The base type of the node iterators.

    /// This is the base type of each node iterators,
    /// thus each kind of node iterator will convert to this.
    class Node {
    public:
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      Node() {}   //FIXME
      /// Invalid constructor \& conversion.

      /// This constructor initializes the iterator to be invalid.
      /// \sa Invalid for more details.

      Node(Invalid) {}
      //Node(const Node &) {}

      /// Two iterators are equal if and only if they point to the
      /// same object or both are invalid.
      bool operator==(Node n) const { return true; }

      /// \sa \ref operator==(Node n)
      ///
      bool operator!=(Node n) const { return true; }

      bool operator<(Node n) const { return true; }
    };
    
    /// This iterator goes through each node.

    /// This iterator goes through each node.
    /// Its usage is quite simple, for example you can count the number
    /// of nodes in graph \c G of type \c Graph like this:
    /// \code
    ///int count=0;
    ///for(Graph::NodeIt n(G);G.valid(n);G.next(n)) count++;
    /// \endcode
    class NodeIt : public Node {
    public:
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      NodeIt() {} //FIXME
      /// Invalid constructor \& conversion.

      /// Initialize the iterator to be invalid
      /// \sa Invalid for more details.
      NodeIt(Invalid) {}
      /// Sets the iterator to the first node of \c G.
      NodeIt(const GraphSkeleton &G) {}
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      NodeIt(const NodeIt &) {}
    };
    
    
    /// The base type of the edge iterators.
    class Edge {
    public:
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      Edge() {}   //FIXME
      /// Initialize the iterator to be invalid
      Edge(Invalid) {}
      /// Two iterators are equal if and only if they point to the
      /// same object or both are invalid.
      bool operator==(Edge n) const { return true; }
      bool operator!=(Edge n) const { return true; }
      bool operator<(Edge n) const { return true; }
    };
    
    /// This iterator goes trough the outgoing edges of a node.

    /// This iterator goes trough the \e outgoing edges of a certain node
    /// of a graph.
    /// Its usage is quite simple, for example you can count the number
    /// of outgoing edges of a node \c n
    /// in graph \c G of type \c Graph as follows.
    /// \code
    ///int count=0;
    ///for(Graph::OutEdgeIt e(G,n);G.valid(e);G.next(e)) count++;
    /// \endcode
    
    class OutEdgeIt : public Edge {
    public:
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      OutEdgeIt() {}
      /// Initialize the iterator to be invalid
      OutEdgeIt(Invalid) {}
      /// This constructor sets the iterator to first outgoing edge.
    
      /// This constructor set the iterator to the first outgoing edge of
      /// node
      ///@param n the node
      ///@param G the graph
      OutEdgeIt(const GraphSkeleton & G, Node n) {}
    };

    /// This iterator goes trough the incoming edges of a node.

    /// This iterator goes trough the \e incoming edges of a certain node
    /// of a graph.
    /// Its usage is quite simple, for example you can count the number
    /// of outgoing edges of a node \c n
    /// in graph \c G of type \c Graph as follows.
    /// \code
    ///int count=0;
    ///for(Graph::InEdgeIt e(G,n);G.valid(e);G.next(e)) count++;
    /// \endcode

    class InEdgeIt : public Edge {
    public:
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      InEdgeIt() {}
      /// Initialize the iterator to be invalid
      InEdgeIt(Invalid) {}
      InEdgeIt(const GraphSkeleton &, Node) {}    
    };
    //  class SymEdgeIt : public Edge {};

    /// This iterator goes through each edge.

    /// This iterator goes through each edge of a graph.
    /// Its usage is quite simple, for example you can count the number
    /// of edges in a graph \c G of type \c Graph as follows:
    /// \code
    ///int count=0;
    ///for(Graph::EdgeIt e(G);G.valid(e);G.next(e)) count++;
    /// \endcode
    class EdgeIt : public Edge {
    public:
      /// @warning The default constructor sets the iterator
      /// to an undefined value.
      EdgeIt() {}
      /// Initialize the iterator to be invalid
      EdgeIt(Invalid) {}
      EdgeIt(const GraphSkeleton &) {}
    };

    /// First node of the graph.

    /// \post \c i and the return value will be the first node.
    ///
    NodeIt &first(NodeIt &i) const { return i;}

    /// The first incoming edge.
    InEdgeIt &first(InEdgeIt &i, Node n) const { return i;}
    /// The first outgoing edge.
    OutEdgeIt &first(OutEdgeIt &i, Node n) const { return i;}
    //  SymEdgeIt &first(SymEdgeIt &, Node) const { return i;}
    /// The first edge of the Graph.
    EdgeIt &first(EdgeIt &i) const { return i;}

//     Node getNext(Node) const {}
//     InEdgeIt getNext(InEdgeIt) const {}
//     OutEdgeIt getNext(OutEdgeIt) const {}
//     //SymEdgeIt getNext(SymEdgeIt) const {}
//     EdgeIt getNext(EdgeIt) const {}

    /// Go to the next node.
    NodeIt &next(NodeIt &i) const { return i;}
    /// Go to the next incoming edge.
    InEdgeIt &next(InEdgeIt &i) const { return i;}
    /// Go to the next outgoing edge.
    OutEdgeIt &next(OutEdgeIt &i) const { return i;}
    //SymEdgeIt &next(SymEdgeIt &) const {}
    /// Go to the next edge.
    EdgeIt &next(EdgeIt &i) const { return i;}

    ///Gives back the head node of an edge.
    Node head(Edge) const { return INVALID; }
    ///Gives back the tail node of an edge.
    Node tail(Edge) const { return INVALID; }
  
    //   Node aNode(InEdgeIt) const {}
    //   Node aNode(OutEdgeIt) const {}
    //   Node aNode(SymEdgeIt) const {}

    //   Node bNode(InEdgeIt) const {}
    //   Node bNode(OutEdgeIt) const {}
    //   Node bNode(SymEdgeIt) const {}

    /// Checks if a node iterator is valid

    ///\todo Maybe, it would be better if iterator converted to
    ///bool directly, as Jacint prefers.
    bool valid(const Node) const { return true;}
    /// Checks if an edge iterator is valid

    ///\todo Maybe, it would be better if iterator converted to
    ///bool directly, as Jacint prefers.
    bool valid(const Edge) const { return true;}

    ///Gives back the \e id of a node.

    ///\warning Not all graph structures provide this feature.
    ///
    int id(const Node) const { return 0;}
    ///Gives back the \e id of an edge.

    ///\warning Not all graph structures provide this feature.
    ///
    int id(const Edge) const { return 0;}

    //void setInvalid(Node &) const {};
    //void setInvalid(Edge &) const {};
  
    ///Add a new node to the graph.

    /// \return the new node.
    ///
    Node addNode() { return INVALID;}
    ///Add a new edge to the graph.

    ///Add a new edge to the graph with tail node \c tail
    ///and head node \c head.
    ///\return the new edge.
    Edge addEdge(Node tail, Node head) { return INVALID;}
    
    /// Resets the graph.

    /// This function deletes all edges and nodes of the graph.
    /// It also frees the memory allocated to store them.
    void clear() {}

    int nodeNum() const { return 0;}
    int edgeNum() const { return 0;}
 
    /// Defalult constructor.
    GraphSkeleton() {}
    ///Copy consructor.
    GraphSkeleton(const GraphSkeleton &G) {}
  
 

    ///Read/write/reference map of the nodes to type \c T.

    ///Read/write/reference map of the nodes to type \c T.
    /// \sa MemoryMapSkeleton
    /// \todo We may need copy constructor
    /// \todo We may need conversion from other nodetype
    /// \todo We may need operator=
    /// \warning Making maps that can handle bool type (NodeMap<bool>)
    /// needs extra attention!

    template<class T> class NodeMap
    {
    public:
      typedef T ValueType;
      typedef Node KeyType;

      NodeMap(const GraphSkeleton &G) {}
      NodeMap(const GraphSkeleton &G, T t) {}

      template<typename TT> NodeMap(const NodeMap<TT> &m) {}

      /// Sets the value of a node.

      /// Sets the value associated with node \c i to the value \c t.
      ///
      void set(Node i, T t) {}
      /// Gets the value of a node.
      T get(Node i) const {return *(T*)0;}  //FIXME: Is it necessary
      T &operator[](Node i) {return *(T*)0;}
      const T &operator[](Node i) const {return *(T*)0;}

      /// Updates the map if the graph has been changed

      /// \todo Do we need this?
      ///
      void update() {}
      void update(T a) {}   //FIXME: Is it necessary
    };

    ///Read/write/reference map of the edges to type \c T.

    ///Read/write/reference map of the edges to type \c T.
    ///It behaves exactly in the same way as \ref NodeMap.
    /// \sa NodeMap
    /// \sa MemoryMapSkeleton
    /// \todo We may need copy constructor
    /// \todo We may need conversion from other edgetype
    /// \todo We may need operator=
    template<class T> class EdgeMap
    {
    public:
      typedef T ValueType;
      typedef Edge KeyType;

      EdgeMap(const GraphSkeleton &G) {}
      EdgeMap(const GraphSkeleton &G, T t) {}
    
      void set(Edge i, T t) {}
      T get(Edge i) const {return *(T*)0;}
      T &operator[](Edge i) {return *(T*)0;}
    
      void update() {}
      void update(T a) {}   //FIXME: Is it necessary
    };
  };

  /// An empty eraseable graph class.
  
  /// This class provides all the common features of an \e eraseable graph
  /// structure,
  /// however completely without implementations and real data structures
  /// behind the interface.
  /// All graph algorithms should compile with this class, but it will not
  /// run properly, of course.
  ///
  /// \todo This blabla could be replaced by a sepatate description about
  /// Skeletons.
  ///
  /// It can be used for checking the interface compatibility,
  /// or it can serve as a skeleton of a new graph structure.
  /// 
  /// Also, you will find here the full documentation of a certain graph
  /// feature, the documentation of a real graph imlementation
  /// like @ref ListGraph or
  /// @ref SmartGraph will just refer to this structure.
  class EraseableGraphSkeleton : public GraphSkeleton
  {
  public:
    /// Deletes a node.
    void erase(Node n) {}
    /// Deletes an edge.
    void erase(Edge e) {}

    /// Defalult constructor.
    GraphSkeleton() {}
    ///Copy consructor.
    GraphSkeleton(const GraphSkeleton &G) {}
  };

  
  // @}

} //namespace hugo



// class EmptyBipGraph : public Graph Skeleton
// {
//   class ANode {};
//   class BNode {};

//   ANode &next(ANode &) {}
//   BNode &next(BNode &) {}

//   ANode &getFirst(ANode &) const {}
//   BNode &getFirst(BNode &) const {}

//   enum NodeClass { A = 0, B = 1 };
//   NodeClass getClass(Node n) {}

// }

#endif // HUGO_EMPTYGRAPH_H