src/work/athos/preflow_push_wogw.h
author hegyi
Fri, 01 Apr 2005 09:43:52 +0000
changeset 1288 6cc7b573b7b5
parent 921 818510fa3d99
permissions -rw-r--r--
Graph displayer is now displaying nodes. Edges remain still undisplayed yet.
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#ifndef LEMON_PREFLOW_PUSH_HH
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#define LEMON_PREFLOW_PUSH_HH
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//#include <algorithm>
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#include <list>
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#include <vector>
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#include <queue>
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//#include "pf_hiba.hh"
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//#include <marci_list_graph.hh>
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//#include <marci_graph_traits.hh>
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#include <invalid.h>
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//#include <reverse_bfs.hh>
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using namespace std;
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namespace lemon {
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  template <typename Graph, typename T>
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  class preflow_push {
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    //Useful typedefs
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    typedef typename Graph::Node Node;
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    typedef typename Graph::NodeIt NodeIt;
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    typedef typename Graph::Edge Edge;
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    typedef typename Graph::OutEdgeIt OutEdgeIt;
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    typedef typename Graph::InEdgeIt InEdgeIt;
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    //---------------------------------------------
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    //Parameters of the algorithm
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    //---------------------------------------------
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    //Fully examine an active node until excess becomes 0
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    enum node_examination_t {examine_full, examine_to_relabel};
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    //No more implemented yet:, examine_only_one_edge};
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    node_examination_t node_examination;
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    //Which implementation to be used
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    enum implementation_t {impl_fifo, impl_highest_label};
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    //No more implemented yet:};
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    implementation_t implementation;
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    //---------------------------------------------
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    //Parameters of the algorithm
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    //---------------------------------------------
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  private:
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    //input
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    Graph& G;
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    Node s;
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    Node t;
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    typename Graph::EdgeMap<T> &capacity;
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    //output
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    typename Graph::EdgeMap<T> preflow;
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    T maxflow_value;
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    //auxiliary variables for computation
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    //The number of the nodes
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    int number_of_nodes;
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    //A nodemap for the level
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    typename Graph::NodeMap<int> level;
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    //A nodemap for the excess
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    typename Graph::NodeMap<T> excess;
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    //Number of nodes on each level
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    vector<int> num_of_nodes_on_level;
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    //For the FIFO implementation
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    list<Node> fifo_nodes;
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    //For 'highest label' implementation
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    int highest_active;
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    //int second_highest_active;
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    vector< list<Node> > active_nodes;
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  public:
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    //Constructing the object using the graph, source, sink and capacity vector
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    preflow_push(
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		      Graph& _G, 
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		      Node _s, 
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		      Node _t, 
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		      typename Graph::EdgeMap<T> & _capacity)
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      : G(_G), s(_s), t(_t), 
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	capacity(_capacity), 
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	preflow(_G),
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	//Counting the number of nodes
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	//number_of_nodes(count(G.first<EachNodeIt>())),
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	number_of_nodes(G.nodeNum()),
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	level(_G),
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	excess(_G)//,
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        // Default constructor: active_nodes()
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    { 
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      //Simplest parameter settings
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      node_examination = examine_full;//examine_to_relabel;//
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      //Which implementation to be usedexamine_full
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      implementation = impl_highest_label;//impl_fifo;
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      //
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      num_of_nodes_on_level.resize(2*number_of_nodes-1);
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      num_of_nodes_on_level.clear();
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      switch(implementation){
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      case impl_highest_label :{
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	active_nodes.clear();
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	active_nodes.resize(2*number_of_nodes-1);
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	break;
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      }
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      default:
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	break;
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      }
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    }
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    //Returns the value of a maximal flow 
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    T run();
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    typename Graph::EdgeMap<T>  getmaxflow(){
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      return preflow;
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    }
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  private:
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    //For testing purposes only
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    //Lists the node_properties
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    void write_property_vector(typename Graph::NodeMap<T> a,
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			       //node_property_vector<Graph, T> a, 
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			       char* prop_name="property"){
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      for(NodeIt i=G.template first<NodeIt>(); G.valid(i); G.next(i)) {
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	cout<<"Node id.: "<<G.id(i)<<", "<<prop_name<<" value: "<<a[i]<<endl;
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      }
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      cout<<endl;
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    }
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    //Modifies the excess of the node and makes sufficient changes
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    void modify_excess(const Node& a ,T v){
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      //T old_value=excess[a];
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      excess[a] += v;
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    }
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    //This private procedure is supposed to modify the preflow on edge j
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    //by value v (which can be positive or negative as well) 
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    //and maintain the excess on the target and source
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    //Here we do not check whether this is possible or not
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    void modify_preflow(Edge j, const T& v){
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      //Modifiyng the edge
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      preflow[j] += v;
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      //Modifiyng the target
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      modify_excess(G.target(j),v);
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      //Modifiyng the source
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      modify_excess(G.source(j),-v);
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    }
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    //Gives the active node to work with 
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    //(depending on the implementation to be used)
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    Node get_active_node(){
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      switch(implementation) {
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      case impl_highest_label : {
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	//First need to find the highest label for which there's an active node
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	while( highest_active>=0 && active_nodes[highest_active].empty() ){ 
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	  --highest_active;
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	}
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	if( highest_active>=0) {
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	  Node a=active_nodes[highest_active].front();
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	  active_nodes[highest_active].pop_front();
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	  return a;
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	}
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	else {
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	  return INVALID;
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	}
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	break;
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      }
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      case impl_fifo : {
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	if( ! fifo_nodes.empty() ) {
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	  Node a=fifo_nodes.front();
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	  fifo_nodes.pop_front();
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	  return a;
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	}
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	else {
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	  return INVALID;
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	}
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	break;
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      }
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      }
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      //
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      return INVALID;
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    }
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    //Puts node 'a' among the active nodes
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    void make_active(const Node& a){
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      //s and t never become active
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      if (a!=s && a!= t){
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	switch(implementation){
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	case impl_highest_label :
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	  active_nodes[level[a]].push_back(a);
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	  break;
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	case impl_fifo :
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	  fifo_nodes.push_back(a);
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	  break;
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	}
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      }
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      //Update highest_active label
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      if (highest_active<level[a]){
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	highest_active=level[a];
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      }
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    }
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    //Changes the level of node a and make sufficent changes
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    void change_level_to(Node a, int new_value){
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      int seged = level[a];
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      level.set(a,new_value);
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      --num_of_nodes_on_level[seged];
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      ++num_of_nodes_on_level[new_value];
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    }
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    //Collection of things useful (or necessary) to do before running
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    void preprocess(){
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      //---------------------------------------
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      //Initialize parameters
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      //---------------------------------------
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      //Setting starting preflow, level and excess values to zero
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      //This can be important, if the algorithm is run more then once
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      for(NodeIt i=G.template first<NodeIt>(); G.valid(i); G.next(i)) {
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        level.set(i,0);
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        excess.set(i,0);
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	for(OutEdgeIt j=G.template first<OutEdgeIt>(i); G.valid(j); G.next(j)) 
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	  preflow.set(j, 0);
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      }
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      num_of_nodes_on_level[0]=number_of_nodes;
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      highest_active=0;
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      //---------------------------------------
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      //Initialize parameters
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      //---------------------------------------
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      //------------------------------------
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      //This is the only part that uses BFS
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      //------------------------------------
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      /*Reverse_bfs from t, to find the starting level.*/
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      //Copyright: Jacint
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      change_level_to(t,0);
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      std::queue<Node> bfs_queue;
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      bfs_queue.push(t);
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      while (!bfs_queue.empty()) {
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	Node v=bfs_queue.front();	
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	bfs_queue.pop();
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	int l=level[v]+1;
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	InEdgeIt e;
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	for(G.first(e,v); G.valid(e); G.next(e)) {
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	  Node w=G.source(e);
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	  if ( level[w] == number_of_nodes && w != s ) {
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	    bfs_queue.push(w);
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	    //Node first=level_list[l];
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	    //if ( G.valid(first) ) left.set(first,w);
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	    //right.set(w,first);
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	    //level_list[l]=w;
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	    change_level_to(w, l);
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	    //level.set(w, l);
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	  }
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	}
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      }
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      change_level_to(s,number_of_nodes);
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      //level.set(s,number_of_nodes);
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      /*
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      //Setting starting level values using reverse bfs
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      reverse_bfs<Graph> rev_bfs(G,t);
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      rev_bfs.run();
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      //write_property_vector(rev_bfs.dist,"rev_bfs");
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      for(NodeIt i=G.template first<NodeIt>(); G.valid(i); G.next(i)) {
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        change_level_to(i,rev_bfs.dist(i));
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	//level.put(i,rev_bfs.dist.get(i));
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      }
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      */
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      //------------------------------------
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      //This is the only part that uses BFS
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      //------------------------------------
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      //Starting level of s
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      change_level_to(s,number_of_nodes);
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      //level.put(s,number_of_nodes);
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      //we push as much preflow from s as possible to start with
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      for(OutEdgeIt j=G.template first<OutEdgeIt>(s); G.valid(j); G.next(j)){ 
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	modify_preflow(j,capacity[j] );
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	make_active(G.target(j));
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	int lev=level[G.target(j)];
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	if(highest_active<lev){
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	  highest_active=lev;
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	}
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      }
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      //cout<<highest_active<<endl;
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    } 
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    //If the preflow is less than the capacity on the given edge
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    //then it is an edge in the residual graph
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    bool is_admissible_forward_edge(Edge j, int& new_level){
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      if (capacity[j]>preflow[j]){
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	if(level[G.source(j)]==level[G.target(j)]+1){
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	  return true;
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	}
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	else{
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	  if (level[G.target(j)] < new_level)
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	    new_level=level[G.target(j)];
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	}
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      }
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      return false;
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    }
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    //If the preflow is greater than 0 on the given edge
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    //then the edge reversd is an edge in the residual graph
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    bool is_admissible_backward_edge(Edge j, int& new_level){
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      if (0<preflow[j]){
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	if(level[G.source(j)]==level[G.target(j)]-1){
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	  return true;
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	}
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	else{
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	  if (level[G.source(j)] < new_level)
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	    new_level=level[G.source(j)];
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	}
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      }
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      return false;
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    }
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  };  //class preflow_push  
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  template<typename Graph, typename T>
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    T preflow_push<Graph, T>::run() {
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    preprocess();
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    //write_property_vector(level,"level");
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    T e,v;
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    Node a;
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    while (a=get_active_node(), G.valid(a)){
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      //cout<<G.id(a)<<endl;
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      //write_property_vector(excess,"excess");
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      //write_property_vector(level,"level");
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      bool go_to_next_node=false;
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      e = excess[a];
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      while (!go_to_next_node){
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	//Initial value for the new level for the active node we are dealing with
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	int new_level=2*number_of_nodes;
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	//write_property_vector(excess,"excess");
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	//write_property_vector(level,"level");
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	//cout<<G.id(a)<<endl;
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	//Out edges from node a
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	{
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	  OutEdgeIt j=G.template first<OutEdgeIt>(a);
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	  while (G.valid(j) && e){
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	    if (is_admissible_forward_edge(j,new_level)){
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	      v=min(e,capacity[j] - preflow[j]);
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	      e -= v;
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	      //New node might become active
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	      if (excess[G.target(j)]==0){
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		make_active(G.target(j));
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	      }
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	      modify_preflow(j,v);
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	    }
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	    G.next(j);
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	  }
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	}
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	//In edges to node a
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	{
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	  InEdgeIt j=G.template first<InEdgeIt>(a);
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	  while (G.valid(j) && e){
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	    if (is_admissible_backward_edge(j,new_level)){
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	      v=min(e,preflow[j]);
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	      e -= v;
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	      //New node might become active
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	      if (excess[G.source(j)]==0){
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		make_active(G.source(j));
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	      }
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	      modify_preflow(j,-v);
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	    }
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	    G.next(j);
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	  }
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	}
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	//if (G.id(a)==999)
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	//cout<<new_level<<" e: "<<e<<endl;
athos@331
   418
	//cout<<G.id(a)<<" "<<new_level<<endl;
athos@331
   419
athos@331
   420
	if (0==e){
athos@331
   421
	  //Saturating push
athos@331
   422
	  go_to_next_node=true;
athos@331
   423
	}
athos@331
   424
	else{//If there is still excess in node a
athos@331
   425
	  
athos@331
   426
	  //change_level_to(a,new_level+1);
athos@331
   427
	  
athos@331
   428
	  //Level remains empty
athos@331
   429
	  if (num_of_nodes_on_level[level[a]]==1){
athos@331
   430
	    change_level_to(a,number_of_nodes);
athos@331
   431
	    //go_to_next_node=True;
athos@331
   432
	  }
athos@331
   433
	  else{
athos@331
   434
	    change_level_to(a,new_level+1);
athos@331
   435
	    //increase_level(a);
athos@331
   436
	  }
athos@331
   437
	  
athos@331
   438
    
athos@331
   439
	  
athos@331
   440
athos@331
   441
	  switch(node_examination){
athos@331
   442
	  case examine_to_relabel:
athos@331
   443
	    make_active(a);
athos@331
   444
athos@331
   445
	    go_to_next_node = true;
athos@331
   446
	    break;
athos@331
   447
	  default:
athos@331
   448
	    break;
athos@331
   449
	  }
athos@331
   450
	  
athos@331
   451
    
athos@331
   452
	
athos@331
   453
	}//if (0==e)
athos@331
   454
      }
athos@331
   455
    }
athos@331
   456
    maxflow_value = excess[t];
athos@331
   457
    return maxflow_value;
athos@331
   458
  }//run
athos@331
   459
athos@331
   460
alpar@921
   461
}//namespace lemon
athos@331
   462
athos@331
   463
#endif //PREFLOW_PUSH_HH