src/work/marci/bfs_dfs.h
author marci
Mon, 17 May 2004 06:32:12 +0000
changeset 644 d84f3d42237d
parent 604 4acd273c3009
child 646 bd7a69231cf8
permissions -rw-r--r--
#ifndef correction
     1 // -*- c++ -*-
     2 #ifndef HUGO_BFS_DFS_H
     3 #define HUGO_BFS_DFS_H
     4 
     5 /// \ingroup galgs
     6 /// \file
     7 /// \brief Bfs and dfs iterators.
     8 ///
     9 /// This file contains bfs and dfs iterator classes.
    10 ///
    11 // /// \author Marton Makai
    12 
    13 #include <queue>
    14 #include <stack>
    15 #include <utility>
    16 
    17 #include <hugo/invalid.h>
    18 
    19 namespace hugo {
    20 
    21   /// Bfs searches for the nodes wich are not marked in 
    22   /// \c reached_map
    23   /// Reached have to work as read-write bool Node-map.
    24   /// \ingroup galgs
    25   template <typename Graph, /*typename OutEdgeIt,*/ 
    26 	    typename ReachedMap/*=typename Graph::NodeMap<bool>*/ >
    27   class BfsIterator {
    28   protected:
    29     typedef typename Graph::Node Node;
    30     typedef typename Graph::OutEdgeIt OutEdgeIt;
    31     const Graph* graph;
    32     std::queue<Node> bfs_queue;
    33     ReachedMap& reached;
    34     bool b_node_newly_reached;
    35     OutEdgeIt actual_edge;
    36     bool own_reached_map;
    37   public:
    38     /// In that constructor \c _reached have to be a reference 
    39     /// for a bool Node-map. The algorithm will search in a bfs order for 
    40     /// the nodes which are \c false initially
    41     BfsIterator(const Graph& _graph, ReachedMap& _reached) : 
    42       graph(&_graph), reached(_reached), 
    43       own_reached_map(false) { }
    44     /// The same as above, but the map storing the reached nodes 
    45     /// is constructed dynamically to everywhere false.
    46     BfsIterator(const Graph& _graph) : 
    47       graph(&_graph), reached(*(new ReachedMap(*graph /*, false*/))), 
    48       own_reached_map(true) { }
    49     /// The map storing the reached nodes have to be destroyed if 
    50     /// it was constructed dynamically
    51     ~BfsIterator() { if (own_reached_map) delete &reached; }
    52     /// This method markes \c s reached.
    53     /// If the queue is empty, then \c s is pushed in the bfs queue 
    54     /// and the first out-edge is processed.
    55     /// If the queue is not empty, then \c s is simply pushed.
    56     void pushAndSetReached(Node s) { 
    57       reached.set(s, true);
    58       if (bfs_queue.empty()) {
    59 	bfs_queue.push(s);
    60 	graph->first(actual_edge, s);
    61 	if (graph->valid(actual_edge)) { 
    62 	  Node w=graph->bNode(actual_edge);
    63 	  if (!reached[w]) {
    64 	    bfs_queue.push(w);
    65 	    reached.set(w, true);
    66 	    b_node_newly_reached=true;
    67 	  } else {
    68 	    b_node_newly_reached=false;
    69 	  }
    70 	} 
    71       } else {
    72 	bfs_queue.push(s);
    73       }
    74     }
    75     /// As \c BfsIterator<Graph, ReachedMap> works as an edge-iterator, 
    76     /// its \c operator++() iterates on the edges in a bfs order.
    77     BfsIterator<Graph, /*OutEdgeIt,*/ ReachedMap>& 
    78     operator++() { 
    79       if (graph->valid(actual_edge)) { 
    80 	graph->next(actual_edge);
    81 	if (graph->valid(actual_edge)) {
    82 	  Node w=graph->bNode(actual_edge);
    83 	  if (!reached[w]) {
    84 	    bfs_queue.push(w);
    85 	    reached.set(w, true);
    86 	    b_node_newly_reached=true;
    87 	  } else {
    88 	    b_node_newly_reached=false;
    89 	  }
    90 	}
    91       } else {
    92 	bfs_queue.pop(); 
    93 	if (!bfs_queue.empty()) {
    94 	  graph->first(actual_edge, bfs_queue.front());
    95 	  if (graph->valid(actual_edge)) {
    96 	    Node w=graph->bNode(actual_edge);
    97 	    if (!reached[w]) {
    98 	      bfs_queue.push(w);
    99 	      reached.set(w, true);
   100 	      b_node_newly_reached=true;
   101 	    } else {
   102 	      b_node_newly_reached=false;
   103 	    }
   104 	  }
   105 	}
   106       }
   107       return *this;
   108     }
   109     /// Guess what?
   110     bool finished() const { return bfs_queue.empty(); }
   111     /// The conversion operator makes for converting the bfs-iterator 
   112     /// to an \c out-edge-iterator.
   113     ///\bug Edge have to be in HUGO 0.2
   114     operator OutEdgeIt() const { return actual_edge; }
   115     /// Guess what?
   116     bool isBNodeNewlyReached() const { return b_node_newly_reached; }
   117     /// Guess what?
   118     bool isANodeExamined() const { return !(graph->valid(actual_edge)); }
   119     /// Guess what?
   120     Node aNode() const { return bfs_queue.front(); }
   121     /// Guess what?
   122     Node bNode() const { return graph->bNode(actual_edge); }
   123     /// Guess what?
   124     const ReachedMap& getReachedMap() const { return reached; }
   125     /// Guess what?
   126     const std::queue<Node>& getBfsQueue() const { return bfs_queue; }
   127   };
   128 
   129   /// Bfs searches for the nodes wich are not marked in 
   130   /// \c reached_map
   131   /// Reached have to work as a read-write bool Node-map, 
   132   /// Pred is a write Edge Node-map and
   133   /// Dist is a read-write Node-map of integral value, have to be. 
   134   /// \ingroup galgs
   135   template <typename Graph, 
   136 	    typename ReachedMap=typename Graph::template NodeMap<bool>, 
   137 	    typename PredMap
   138 	    =typename Graph::template NodeMap<typename Graph::Edge>, 
   139 	    typename DistMap=typename Graph::template NodeMap<int> > 
   140   class Bfs : public BfsIterator<Graph, ReachedMap> {
   141     typedef BfsIterator<Graph, ReachedMap> Parent;
   142   protected:
   143     typedef typename Parent::Node Node;
   144     PredMap& pred;
   145     DistMap& dist;
   146   public:
   147     /// The algorithm will search in a bfs order for 
   148     /// the nodes which are \c false initially. 
   149     /// The constructor makes no initial changes on the maps.
   150     Bfs<Graph, ReachedMap, PredMap, DistMap>(const Graph& _graph, ReachedMap& _reached, PredMap& _pred, DistMap& _dist) : BfsIterator<Graph, ReachedMap>(_graph, _reached), pred(&_pred), dist(&_dist) { }
   151     /// \c s is marked to be reached and pushed in the bfs queue.
   152     /// If the queue is empty, then the first out-edge is processed.
   153     /// If \c s was not marked previously, then 
   154     /// in addition its pred is set to be \c INVALID, and dist to \c 0. 
   155     /// if \c s was marked previuosly, then it is simply pushed.
   156     void push(Node s) { 
   157       if (this->reached[s]) {
   158 	Parent::pushAndSetReached(s);
   159       } else {
   160 	Parent::pushAndSetReached(s);
   161 	pred.set(s, INVALID);
   162 	dist.set(s, 0);
   163       }
   164     }
   165     /// A bfs is processed from \c s.
   166     void run(Node s) {
   167       push(s);
   168       while (!this->finished()) this->operator++();
   169     }
   170     /// Beside the bfs iteration, \c pred and \dist are saved in a 
   171     /// newly reached node. 
   172     Bfs<Graph, ReachedMap, PredMap, DistMap>& operator++() {
   173       Parent::operator++();
   174       if (this->graph->valid(this->actual_edge) && this->b_node_newly_reached) 
   175       {
   176 	pred.set(this->bNode(), this->actual_edge);
   177 	dist.set(this->bNode(), dist[this->aNode()]);
   178       }
   179       return *this;
   180     }
   181     /// Guess what?
   182     const PredMap& getPredMap() const { return pred; }
   183     /// Guess what?
   184     const DistMap& getDistMap() const { return dist; }
   185   };
   186 
   187   /// Dfs searches for the nodes wich are not marked in 
   188   /// \c reached_map
   189   /// Reached have to be a read-write bool Node-map.
   190   /// \ingroup galgs
   191   template <typename Graph, /*typename OutEdgeIt,*/ 
   192 	    typename ReachedMap/*=typename Graph::NodeMap<bool>*/ >
   193   class DfsIterator {
   194   protected:
   195     typedef typename Graph::Node Node;
   196     typedef typename Graph::OutEdgeIt OutEdgeIt;
   197     const Graph* graph;
   198     std::stack<OutEdgeIt> dfs_stack;
   199     bool b_node_newly_reached;
   200     OutEdgeIt actual_edge;
   201     Node actual_node;
   202     ReachedMap& reached;
   203     bool own_reached_map;
   204   public:
   205     /// In that constructor \c _reached have to be a reference 
   206     /// for a bool Node-map. The algorithm will search in a dfs order for 
   207     /// the nodes which are \c false initially
   208     DfsIterator(const Graph& _graph, ReachedMap& _reached) : 
   209       graph(&_graph), reached(_reached), 
   210       own_reached_map(false) { }
   211     /// The same as above, but the map of reached nodes is 
   212     /// constructed dynamically 
   213     /// to everywhere false.
   214     DfsIterator(const Graph& _graph) : 
   215       graph(&_graph), reached(*(new ReachedMap(*graph /*, false*/))), 
   216       own_reached_map(true) { }
   217     ~DfsIterator() { if (own_reached_map) delete &reached; }
   218     /// This method markes s reached and first out-edge is processed.
   219     void pushAndSetReached(Node s) { 
   220       actual_node=s;
   221       reached.set(s, true);
   222       OutEdgeIt e;
   223       graph->first(e, s);
   224       dfs_stack.push(e); 
   225     }
   226     /// As \c DfsIterator<Graph, ReachedMap> works as an edge-iterator, 
   227     /// its \c operator++() iterates on the edges in a dfs order.
   228     DfsIterator<Graph, /*OutEdgeIt,*/ ReachedMap>& 
   229     operator++() { 
   230       actual_edge=dfs_stack.top();
   231       //actual_node=G.aNode(actual_edge);
   232       if (graph->valid(actual_edge)/*.valid()*/) { 
   233 	Node w=graph->bNode(actual_edge);
   234 	actual_node=w;
   235 	if (!reached[w]) {
   236 	  OutEdgeIt e;
   237 	  graph->first(e, w);
   238 	  dfs_stack.push(e);
   239 	  reached.set(w, true);
   240 	  b_node_newly_reached=true;
   241 	} else {
   242 	  actual_node=graph->aNode(actual_edge);
   243 	  graph->next(dfs_stack.top());
   244 	  b_node_newly_reached=false;
   245 	}
   246       } else {
   247 	//actual_node=G.aNode(dfs_stack.top());
   248 	dfs_stack.pop();
   249       }
   250       return *this;
   251     }
   252     /// Guess what?
   253     bool finished() const { return dfs_stack.empty(); }
   254     /// Guess what?
   255     operator OutEdgeIt() const { return actual_edge; }
   256     /// Guess what?
   257     bool isBNodeNewlyReached() const { return b_node_newly_reached; }
   258     /// Guess what?
   259     bool isANodeExamined() const { return !(graph->valid(actual_edge)); }
   260     /// Guess what?
   261     Node aNode() const { return actual_node; /*FIXME*/}
   262     /// Guess what?
   263     Node bNode() const { return graph->bNode(actual_edge); }
   264     /// Guess what?
   265     const ReachedMap& getReachedMap() const { return reached; }
   266     /// Guess what?
   267     const std::stack<OutEdgeIt>& getDfsStack() const { return dfs_stack; }
   268   };
   269 
   270   /// Dfs searches for the nodes wich are not marked in 
   271   /// \c reached_map
   272   /// Reached is a read-write bool Node-map, 
   273   /// Pred is a write Node-map, have to be.
   274   /// \ingroup galgs
   275   template <typename Graph, 
   276 	    typename ReachedMap=typename Graph::template NodeMap<bool>, 
   277 	    typename PredMap
   278 	    =typename Graph::template NodeMap<typename Graph::Edge> > 
   279   class Dfs : public DfsIterator<Graph, ReachedMap> {
   280     typedef DfsIterator<Graph, ReachedMap> Parent;
   281   protected:
   282     typedef typename Parent::Node Node;
   283     PredMap& pred;
   284   public:
   285     /// The algorithm will search in a dfs order for 
   286     /// the nodes which are \c false initially. 
   287     /// The constructor makes no initial changes on the maps.
   288     Dfs<Graph, ReachedMap, PredMap>(const Graph& _graph, ReachedMap& _reached, PredMap& _pred) : DfsIterator<Graph, ReachedMap>(_graph, _reached), pred(&_pred) { }
   289     /// \c s is marked to be reached and pushed in the bfs queue.
   290     /// If the queue is empty, then the first out-edge is processed.
   291     /// If \c s was not marked previously, then 
   292     /// in addition its pred is set to be \c INVALID. 
   293     /// if \c s was marked previuosly, then it is simply pushed.
   294     void push(Node s) { 
   295       if (this->reached[s]) {
   296 	Parent::pushAndSetReached(s);
   297       } else {
   298 	Parent::pushAndSetReached(s);
   299 	pred.set(s, INVALID);
   300       }
   301     }
   302     /// A bfs is processed from \c s.
   303     void run(Node s) {
   304       push(s);
   305       while (!this->finished()) this->operator++();
   306     }
   307     /// Beside the dfs iteration, \c pred is saved in a 
   308     /// newly reached node. 
   309     Dfs<Graph, ReachedMap, PredMap>& operator++() {
   310       Parent::operator++();
   311       if (this->graph->valid(this->actual_edge) && this->b_node_newly_reached) 
   312       {
   313 	pred.set(this->bNode(), this->actual_edge);
   314       }
   315       return *this;
   316     }
   317     /// Guess what?
   318     const PredMap& getPredMap() const { return pred; }
   319   };
   320 
   321 
   322 } // namespace hugo
   323 
   324 #endif //HUGO_BFS_DFS_H