src/work/marci/bfs_dfs.h
author alpar
Thu, 22 Jul 2004 14:29:20 +0000
changeset 730 af375858f17c
parent 650 588ff2ca55bd
child 774 4297098d9677
permissions -rw-r--r--
Custom made INSTALL file (will be sometime).
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// -*- c++ -*-
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#ifndef HUGO_BFS_DFS_H
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#define HUGO_BFS_DFS_H
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/// \ingroup galgs
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/// \file
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/// \brief Bfs and dfs iterators.
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///
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/// This file contains bfs and dfs iterator classes.
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///
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// /// \author Marton Makai
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#include <queue>
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#include <stack>
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#include <utility>
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#include <hugo/invalid.h>
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namespace hugo {
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  /// Bfs searches for the nodes wich are not marked in 
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  /// \c reached_map
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  /// Reached have to be a read-write bool node-map.
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  /// \ingroup galgs
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  template <typename Graph, /*typename OutEdgeIt,*/ 
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	    typename ReachedMap/*=typename Graph::NodeMap<bool>*/ >
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  class BfsIterator {
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  protected:
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    typedef typename Graph::Node Node;
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    typedef typename Graph::OutEdgeIt OutEdgeIt;
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    const Graph* graph;
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    std::queue<Node> bfs_queue;
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    ReachedMap& reached;
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    bool b_node_newly_reached;
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    OutEdgeIt actual_edge;
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    bool own_reached_map;
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  public:
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    /// In that constructor \c _reached have to be a reference 
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    /// for a bool bode-map. The algorithm will search for the 
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    /// initially \c false nodes 
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    /// in a bfs order.
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    BfsIterator(const Graph& _graph, ReachedMap& _reached) : 
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      graph(&_graph), reached(_reached), 
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      own_reached_map(false) { }
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    /// The same as above, but the map storing the reached nodes 
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    /// is constructed dynamically to everywhere false.
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    /// \deprecated
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    BfsIterator(const Graph& _graph) : 
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      graph(&_graph), reached(*(new ReachedMap(*graph /*, false*/))), 
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      own_reached_map(true) { }
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    /// The map storing the reached nodes have to be destroyed if 
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    /// it was constructed dynamically
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    ~BfsIterator() { if (own_reached_map) delete &reached; }
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    /// This method markes \c s reached.
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    /// If the queue is empty, then \c s is pushed in the bfs queue 
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    /// and the first out-edge is processed.
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    /// If the queue is not empty, then \c s is simply pushed.
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    void pushAndSetReached(Node s) { 
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      reached.set(s, true);
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      if (bfs_queue.empty()) {
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	bfs_queue.push(s);
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	graph->first(actual_edge, s);
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	if (graph->valid(actual_edge)) { 
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	  Node w=graph->bNode(actual_edge);
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	  if (!reached[w]) {
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	    bfs_queue.push(w);
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	    reached.set(w, true);
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	    b_node_newly_reached=true;
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	  } else {
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	    b_node_newly_reached=false;
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	  }
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	} 
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      } else {
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	bfs_queue.push(s);
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      }
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    }
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    /// As \c BfsIterator<Graph, ReachedMap> works as an edge-iterator, 
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    /// its \c operator++() iterates on the edges in a bfs order.
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    BfsIterator<Graph, /*OutEdgeIt,*/ ReachedMap>& 
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    operator++() { 
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      if (graph->valid(actual_edge)) { 
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	graph->next(actual_edge);
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	if (graph->valid(actual_edge)) {
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	  Node w=graph->bNode(actual_edge);
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	  if (!reached[w]) {
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	    bfs_queue.push(w);
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	    reached.set(w, true);
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	    b_node_newly_reached=true;
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	  } else {
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	    b_node_newly_reached=false;
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	  }
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	}
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      } else {
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	bfs_queue.pop(); 
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	if (!bfs_queue.empty()) {
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	  graph->first(actual_edge, bfs_queue.front());
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	  if (graph->valid(actual_edge)) {
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	    Node w=graph->bNode(actual_edge);
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	    if (!reached[w]) {
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	      bfs_queue.push(w);
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	      reached.set(w, true);
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	      b_node_newly_reached=true;
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	    } else {
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	      b_node_newly_reached=false;
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	    }
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	  }
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	}
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      }
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      return *this;
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    }
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    /// Returns true iff the algorithm is finished.
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    bool finished() const { return bfs_queue.empty(); }
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    /// The conversion operator makes for converting the bfs-iterator 
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    /// to an \c out-edge-iterator.
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    ///\bug Edge have to be in HUGO 0.2
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    operator OutEdgeIt() const { return actual_edge; }
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    /// Returns if b-node has been reached just now.
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    bool isBNodeNewlyReached() const { return b_node_newly_reached; }
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    /// Returns if a-node is examined.
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    bool isANodeExamined() const { return !(graph->valid(actual_edge)); }
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    /// Returns a-node of the actual edge, so does if the edge is invalid.
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    Node aNode() const { return bfs_queue.front(); }
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    /// \pre The actual edge have to be valid.
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    Node bNode() const { return graph->bNode(actual_edge); }
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    /// Guess what?
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    /// \deprecated 
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    const ReachedMap& getReachedMap() const { return reached; }
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    /// Guess what?
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    /// \deprecated
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    const std::queue<Node>& getBfsQueue() const { return bfs_queue; }
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  };
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  /// Bfs searches for the nodes wich are not marked in 
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  /// \c reached_map
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  /// Reached have to work as a read-write bool Node-map, 
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  /// Pred is a write edge node-map and
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  /// Dist is a read-write node-map of integral value, have to be. 
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  /// \ingroup galgs
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  template <typename Graph, 
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	    typename ReachedMap=typename Graph::template NodeMap<bool>, 
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	    typename PredMap
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	    =typename Graph::template NodeMap<typename Graph::Edge>, 
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	    typename DistMap=typename Graph::template NodeMap<int> > 
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  class Bfs : public BfsIterator<Graph, ReachedMap> {
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    typedef BfsIterator<Graph, ReachedMap> Parent;
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  protected:
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    typedef typename Parent::Node Node;
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    PredMap& pred;
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    DistMap& dist;
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  public:
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    /// The algorithm will search in a bfs order for 
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    /// the nodes which are \c false initially. 
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    /// The constructor makes no initial changes on the maps.
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    Bfs<Graph, ReachedMap, PredMap, DistMap>(const Graph& _graph, ReachedMap& _reached, PredMap& _pred, DistMap& _dist) : 
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      BfsIterator<Graph, ReachedMap>(_graph, _reached), 
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      pred(_pred), dist(_dist) { }
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    /// \c s is marked to be reached and pushed in the bfs queue.
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    /// If the queue is empty, then the first out-edge is processed.
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    /// If \c s was not marked previously, then 
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    /// in addition its pred is set to be \c INVALID, and dist to \c 0. 
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    /// if \c s was marked previuosly, then it is simply pushed.
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    void push(Node s) { 
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      if (this->reached[s]) {
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	Parent::pushAndSetReached(s);
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      } else {
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	Parent::pushAndSetReached(s);
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	pred.set(s, INVALID);
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	dist.set(s, 0);
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      }
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    }
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    /// A bfs is processed from \c s.
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    void run(Node s) {
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      push(s);
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      while (!this->finished()) this->operator++();
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    }
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    /// Beside the bfs iteration, \c pred and \dist are saved in a 
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    /// newly reached node. 
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    Bfs<Graph, ReachedMap, PredMap, DistMap>& operator++() {
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      Parent::operator++();
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      if (this->graph->valid(this->actual_edge) && this->b_node_newly_reached) 
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      {
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	pred.set(this->bNode(), this->actual_edge);
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	dist.set(this->bNode(), dist[this->aNode()]);
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      }
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      return *this;
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    }
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    /// Guess what?
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    /// \deprecated 
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    const PredMap& getPredMap() const { return pred; }
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    /// Guess what?
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    /// \deprecated
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    const DistMap& getDistMap() const { return dist; }
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  };
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  /// Dfs searches for the nodes wich are not marked in 
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  /// \c reached_map
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  /// Reached have to be a read-write bool Node-map.
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  /// \ingroup galgs
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  template <typename Graph, /*typename OutEdgeIt,*/ 
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	    typename ReachedMap/*=typename Graph::NodeMap<bool>*/ >
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  class DfsIterator {
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  protected:
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    typedef typename Graph::Node Node;
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    typedef typename Graph::OutEdgeIt OutEdgeIt;
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    const Graph* graph;
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    std::stack<OutEdgeIt> dfs_stack;
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    bool b_node_newly_reached;
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    OutEdgeIt actual_edge;
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    Node actual_node;
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    ReachedMap& reached;
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    bool own_reached_map;
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  public:
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    /// In that constructor \c _reached have to be a reference 
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    /// for a bool node-map. The algorithm will search in a dfs order for 
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    /// the nodes which are \c false initially
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    DfsIterator(const Graph& _graph, ReachedMap& _reached) : 
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      graph(&_graph), reached(_reached), 
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      own_reached_map(false) { }
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    /// The same as above, but the map of reached nodes is 
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    /// constructed dynamically 
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    /// to everywhere false.
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    DfsIterator(const Graph& _graph) : 
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      graph(&_graph), reached(*(new ReachedMap(*graph /*, false*/))), 
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      own_reached_map(true) { }
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    ~DfsIterator() { if (own_reached_map) delete &reached; }
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    /// This method markes s reached and first out-edge is processed.
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    void pushAndSetReached(Node s) { 
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      actual_node=s;
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      reached.set(s, true);
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      OutEdgeIt e;
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      graph->first(e, s);
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      dfs_stack.push(e); 
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    }
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    /// As \c DfsIterator<Graph, ReachedMap> works as an edge-iterator, 
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    /// its \c operator++() iterates on the edges in a dfs order.
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    DfsIterator<Graph, /*OutEdgeIt,*/ ReachedMap>& 
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    operator++() { 
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      actual_edge=dfs_stack.top();
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      //actual_node=G.aNode(actual_edge);
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      if (graph->valid(actual_edge)/*.valid()*/) { 
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	Node w=graph->bNode(actual_edge);
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	actual_node=w;
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	if (!reached[w]) {
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	  OutEdgeIt e;
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	  graph->first(e, w);
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	  dfs_stack.push(e);
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	  reached.set(w, true);
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	  b_node_newly_reached=true;
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	} else {
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	  actual_node=graph->aNode(actual_edge);
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	  graph->next(dfs_stack.top());
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	  b_node_newly_reached=false;
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	}
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      } else {
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	//actual_node=G.aNode(dfs_stack.top());
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	dfs_stack.pop();
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      }
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      return *this;
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    }
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    /// Returns true iff the algorithm is finished.
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    bool finished() const { return dfs_stack.empty(); }
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    /// The conversion operator makes for converting the bfs-iterator 
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    /// to an \c out-edge-iterator.
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    ///\bug Edge have to be in HUGO 0.2
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    operator OutEdgeIt() const { return actual_edge; }
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    /// Returns if b-node has been reached just now.
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    bool isBNodeNewlyReached() const { return b_node_newly_reached; }
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    /// Returns if a-node is examined.
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    bool isANodeExamined() const { return !(graph->valid(actual_edge)); }
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    /// Returns a-node of the actual edge, so does if the edge is invalid.
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    Node aNode() const { return actual_node; /*FIXME*/}
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    /// Returns b-node of the actual edge. 
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    /// \pre The actual edge have to be valid.
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    Node bNode() const { return graph->bNode(actual_edge); }
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    /// Guess what?
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    /// \deprecated
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    const ReachedMap& getReachedMap() const { return reached; }
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    /// Guess what?
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    /// \deprecated
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    const std::stack<OutEdgeIt>& getDfsStack() const { return dfs_stack; }
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  };
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  /// Dfs searches for the nodes wich are not marked in 
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  /// \c reached_map
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  /// Reached is a read-write bool node-map, 
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  /// Pred is a write node-map, have to be.
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  /// \ingroup galgs
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  template <typename Graph, 
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	    typename ReachedMap=typename Graph::template NodeMap<bool>, 
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	    typename PredMap
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	    =typename Graph::template NodeMap<typename Graph::Edge> > 
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  class Dfs : public DfsIterator<Graph, ReachedMap> {
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    typedef DfsIterator<Graph, ReachedMap> Parent;
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  protected:
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    typedef typename Parent::Node Node;
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    PredMap& pred;
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  public:
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    /// The algorithm will search in a dfs order for 
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    /// the nodes which are \c false initially. 
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    /// The constructor makes no initial changes on the maps.
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    Dfs<Graph, ReachedMap, PredMap>(const Graph& _graph, ReachedMap& _reached, PredMap& _pred) : DfsIterator<Graph, ReachedMap>(_graph, _reached), pred(_pred) { }
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    /// \c s is marked to be reached and pushed in the bfs queue.
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    /// If the queue is empty, then the first out-edge is processed.
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    /// If \c s was not marked previously, then 
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    /// in addition its pred is set to be \c INVALID. 
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    /// if \c s was marked previuosly, then it is simply pushed.
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    void push(Node s) { 
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      if (this->reached[s]) {
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	Parent::pushAndSetReached(s);
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      } else {
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	Parent::pushAndSetReached(s);
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	pred.set(s, INVALID);
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      }
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    }
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    /// A bfs is processed from \c s.
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    void run(Node s) {
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      push(s);
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      while (!this->finished()) this->operator++();
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    }
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    /// Beside the dfs iteration, \c pred is saved in a 
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    /// newly reached node. 
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    Dfs<Graph, ReachedMap, PredMap>& operator++() {
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      Parent::operator++();
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      if (this->graph->valid(this->actual_edge) && this->b_node_newly_reached) 
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      {
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	pred.set(this->bNode(), this->actual_edge);
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      }
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      return *this;
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    }
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    /// Guess what?
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    /// \deprecated
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    const PredMap& getPredMap() const { return pred; }
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  };
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} // namespace hugo
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#endif //HUGO_BFS_DFS_H