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(){}
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;
topological_sort(g,std::back_inserter(output));
std::vector<vertex_descriptor>::reverse_iterator iter=output.rbegin(),end=output.rend();
for(;iter!=end;++iter)
std::cout << g[*iter].name << " ";
std::cout << std::endl;
}
int main()
{
graph_type g;
//BUILD THE GRAPH
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;
add_edge(v0,v1,g);
add_edge(v0,v3,g);
add_edge(v2,v4,g);
add_edge(v1,v4,g);
std::tie(e4,std::ignore) = add_edge(v4,v3,g);
std::tie(e5,std::ignore) = add_edge(v2,v5,g);
//GRAPH BUILT
std::cout << "Original graph:" << std::endl;
print_topological_order(g);
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
removed.insert(e5);
std::cout << "Filtered Graph after \"removing\" 2 edges" << std::endl;
print_topological_order(fg);
removed.clear(); //clearing the set restores your original graph
std::cout << "Filtered Graph after resetting" << std::endl;
print_topological_order(fg);
}
```