//          Copyright (C) 2012, Michele Caini.
// Distributed under the Boost Software License, Version 1.0.
//    (See accompanying file LICENSE_1_0.txt or copy at
//          http://www.boost.org/LICENSE_1_0.txt)

//          Two Graphs Common Spanning Trees Algorithm
//      Based on academic article of Mint, Read and Tarjan
//     Efficient Algorithm for Common Spanning Tree Problem
// Electron. Lett., 28 April 1983, Volume 19, Issue 9, p.346-347


#include <boost/type_traits.hpp>
#include <boost/concept/requires.hpp>
#include <boost/assign/std/vector.hpp>
#include <boost/graph/adjacency_list.hpp>
#include <boost/compressed_pair.hpp>
#include <boost/test/minimal.hpp>
#include <boost/graph/two_graphs_common_spanning_trees.hpp>
#include <vector>

using namespace boost::assign;


namespace boost
{


typedef
boost::adjacency_list
  <
    boost::vecS,         // OutEdgeList
    boost::vecS,         // VertexList
    boost::undirectedS,  // Directed
    boost::no_property,  // VertexProperties
    boost::no_property,  // EdgeProperties
    boost::no_property,  // GraphProperties
    boost::listS         // EdgeList
  >
Graph
;

typedef
boost::graph_traits<Graph>::vertex_descriptor
vertex_descriptor;

typedef
boost::graph_traits<Graph>::edge_descriptor
edge_descriptor;

typedef
boost::graph_traits<Graph>::vertex_iterator
vertex_iterator;

typedef
boost::graph_traits<Graph>::edge_iterator
edge_iterator;


template < typename Coll, typename Seq >
struct check_edge
{
public:
  BOOST_CONCEPT_ASSERT((RandomAccessContainer<Coll>));
  BOOST_CONCEPT_ASSERT((RandomAccessContainer<Seq>));

  typedef typename Coll::value_type coll_value_type;
  typedef typename Seq::value_type seq_value_type;

  BOOST_STATIC_ASSERT((is_same<coll_value_type, Seq>::value));
  BOOST_STATIC_ASSERT((is_same<seq_value_type, bool>::value));

  void operator()(Coll& coll, Seq& seq)
  {
    bool found = false;

    for(typename Coll::iterator iterator = coll.begin();
        !found && iterator != coll.end(); ++iterator)
    {
      Seq& coll_seq = *iterator;

      BOOST_REQUIRE(coll_seq.size() == seq.size());

      found = true;
      for(typename Seq::size_type pos = 0; found && pos < seq.size(); ++pos) {
        found &= coll_seq[pos] == seq[pos];
      }
    }

    BOOST_REQUIRE(found);
  }
};


void two_graphs_common_spanning_trees_test()
{
  Graph iG, vG;
  std::vector< edge_descriptor > iG_o;
  std::vector< edge_descriptor > vG_o;

  iG_o.push_back(boost::add_edge(0, 1, iG).first);
  iG_o.push_back(boost::add_edge(1, 3, iG).first);
  iG_o.push_back(boost::add_edge(3, 2, iG).first);
  iG_o.push_back(boost::add_edge(1, 5, iG).first);
  iG_o.push_back(boost::add_edge(5, 4, iG).first);
  iG_o.push_back(boost::add_edge(5, 6, iG).first);
  iG_o.push_back(boost::add_edge(5, 3, iG).first);
  iG_o.push_back(boost::add_edge(3, 1, iG).first);
  iG_o.push_back(boost::add_edge(1, 3, iG).first);

  vG_o.push_back(boost::add_edge(0, 2, vG).first);
  vG_o.push_back(boost::add_edge(0, 4, vG).first);
  vG_o.push_back(boost::add_edge(0, 5, vG).first);
  vG_o.push_back(boost::add_edge(5, 1, vG).first);
  vG_o.push_back(boost::add_edge(5, 3, vG).first);
  vG_o.push_back(boost::add_edge(5, 6, vG).first);
  vG_o.push_back(boost::add_edge(5, 4, vG).first);
  vG_o.push_back(boost::add_edge(5, 2, vG).first);
  vG_o.push_back(boost::add_edge(2, 6, vG).first);

  std::vector< std::vector<bool> > coll;
  boost::tree_collector<
      std::vector< std::vector<bool> >, std::vector<bool>
    > collector(coll);
  std::vector<bool> inL(iG_o.size(), false);

  boost::two_graphs_common_spanning_trees(iG, iG_o, vG, vG_o, collector, inL);

  check_edge< std::vector< std::vector<bool> >, std::vector<bool> > checker;
  std::vector<bool> check;

  check.clear();
  check += true, true, true, true, true, true, false, false, false;
  checker(coll, check);

  check.clear();
  check += true, true, true, true, true, true, false, false, false;
  checker(coll, check);
}


}


int test_main ( int argc, char** argv )
{
  boost::two_graphs_common_spanning_trees_test();
  return EXIT_SUCCESS;
}