Understanding boost::disjoint_sets

Question

I need to use boost::disjoint_sets, but the documentation is unclear to me. Can someone please explain what each template parameter means, and perhaps give a small example code for creating a disjoint_sets?

As per the request, I am using disjoint_sets to implement Tarjan's off-line least common ancestors algorithm, i.e - the value type should be vertex_descriptor.

Answer 1

What I can understand from the documentation :

Disjoint need to associate a rank and a parent (in the forest tree) to each element. Since you might want to work with any kind of data you may,for example, not always want to use a map for the parent: with integer an array is sufficient. You also need a rank foe each element (the rank needed for the union-find).

You'll need two "properties" :

• one to associate an integer to each element (first template argument), the rank
• one to associate an element to an other one (second template argument), the fathers

On an example :

std::vector<int>  rank (100);
std::vector<int>  parent (100);
boost::disjoint_sets<int*,int*> ds(&rank[0], &parent[0]);

Arrays are used &rank[0], &parent[0] to the type in the template is int*

For a more complex example (using maps) you can look at Ugo's answer.

You are just giving to the algorithm two structures to store the data (rank/parent) he needs.

Answer 2

disjoint_sets<Rank, Parent, FindCompress>

• Rank PropertyMap used to store the size of a set (element -> std::size_t). See union by rank
• Parent PropertyMap used to store the parent of an element (element -> element). See Path compression
• FindCompress Optional argument defining the find method. Default to find_with_full_path_compression See here (Default should be what you need).

Example:

template <typename Rank, typename Parent>
void algo(Rank& r, Parent& p, std::vector<Element>& elements)
{
 boost::disjoint_sets<Rank,Parent> dsets(r, p);
 for (std::vector<Element>::iterator e = elements.begin();
      e != elements.end(); e++)
  dsets.make_set(*e);
  ...
}

int main()
{
  std::vector<Element> elements;
  elements.push_back(Element(...));
  ...

  typedef std::map<Element,std::size_t> rank_t; // => order on Element
  typedef std::map<Element,Element> parent_t;
  rank_t rank_map;
  parent_t parent_map;

  boost::associative_property_map<rank_t>   rank_pmap(rank_map);
  boost::associative_property_map<parent_t> parent_pmap(parent_map);

  algo(rank_pmap, parent_pmap, elements);
}

Note that "The Boost Property Map Library contains a few adaptors that convert commonly used data-structures that implement a mapping operation, such as builtin arrays (pointers), iterators, and std::map, to have the property map interface"

This list of these adaptors (like boost::associative_property_map) can be found here.