Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have written an algorithm which does (some sort of) 'topological sorting' (not exact). This algorithm copies the given graph and then manipulates the copy (by removing edges). On a million node boost graph, if my algorithm takes 3.1 seconds, 2.19 seconds are consumed by copying the given graph into a new one.

Can I remove edges without actually removing them permanently e.g. sort of masking in boost::graph library? And when algorithm is done, I unmask all edges the graph regains it original state. I suspect this should make my algorithm run much faster.

share|improve this question

1 Answer 1

Boost.Graph's filtered_graph seems a good fit for what you want. Unfortunately I really have no idea if it will perform better than your current approach (I suspect it will). If you decide to implement this approach I would love to hear about the results.

Example on LWS.

#include <iostream>
#include <tuple>

#include <boost/graph/adjacency_list.hpp>
#include <boost/graph/filtered_graph.hpp>
#include <boost/graph/topological_sort.hpp>

#include <boost/unordered_set.hpp>

struct Vertex
   Vertex(int val):name(val){}
   int name;

typedef boost::adjacency_list<boost::vecS,boost::vecS,boost::directedS,Vertex> graph_type;

typedef boost::graph_traits<graph_type>::vertex_descriptor vertex_descriptor;
typedef boost::graph_traits<graph_type>::edge_descriptor edge_descriptor;

// A hash function for edges.
struct edge_hash:std::unary_function<edge_descriptor, std::size_t> 
    edge_hash(graph_type const& g):g(g){}

    std::size_t operator()(edge_descriptor const& e) const {
    std::size_t seed = 0;
    boost::hash_combine(seed, source(e,g));
    boost::hash_combine(seed, target(e,g));
    //if you don't use vecS as your VertexList container
    //you will need to create and initialize a vertex_index property and then use:
    //boost::hash_combine(seed,get(boost::vertex_index, g, source(e,g)));
    //boost::hash_combine(seed,get(boost::vertex_index, g, target(e,g)));
    return seed;

  graph_type const& g;

typedef boost::unordered_set<edge_descriptor, edge_hash> edge_set;
typedef boost::filtered_graph<graph_type,boost::is_not_in_subset<edge_set> > filtered_graph_type;

template <typename Graph>
void print_topological_order(Graph const& g)
   std::vector<vertex_descriptor> output;
   std::vector<vertex_descriptor>::reverse_iterator iter=output.rbegin(),end=output.rend();
      std::cout << g[*iter].name << " ";
   std::cout << std::endl;

int main()
   graph_type g;

   vertex_descriptor v0 = add_vertex(0,g);
   vertex_descriptor v1 = add_vertex(1,g);
   vertex_descriptor v2 = add_vertex(2,g);
   vertex_descriptor v3 = add_vertex(3,g);
   vertex_descriptor v4 = add_vertex(4,g);
   vertex_descriptor v5 = add_vertex(5,g);

   edge_descriptor e4,e5;
   std::tie(e4,std::ignore) = add_edge(v4,v3,g);
   std::tie(e5,std::ignore) = add_edge(v2,v5,g);

   std::cout << "Original graph:" << std::endl;

   edge_hash hasher(g);
   edge_set removed(0,hasher); //need to pass "hasher" in the constructor since it is not default constructible

   filtered_graph_type fg(g,removed); //creates the filtered graph

   removed.insert(e4); //you can "remove" edges from the graph by adding them to this set

   std::cout << "Filtered Graph after \"removing\" 2 edges" << std::endl;

   removed.clear(); //clearing the set restores your original graph

   std::cout << "Filtered Graph after resetting" << std::endl;

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.