1

I would like to have a generic KDTree implementation in C++ that can hold any kind of positionable object. Such objects have a 2D position.

Unfortunately. Positionable classes could have different ways of getting the position.

  • Getters getX() and getY()
  • std::pair<double, double>
  • sf::Vector2f
  • ...

What would be the proper way to wrap such classes into my KDTree?

My Tree is composed of nodes such as:

template <typename T>
struct Node {
    int id;
    T element;
    Node *left, *right;
    Node(T element) : element(element), left(NULL), right(NULL)
    {
        static int id = 0;
        this->id = id++;
    }
};

Somehow I would like to have a generic getter to the position of T element.

One possible solution is to define a positionable interface:

struct KDTreeElement {
    virtual getX() = 0;
    virtual getY() = 0;
}

The con of this method is that the positionable element must know the KDTree library

What are the alternatives?

2

Check the design rationale of boost geometry for a solution to this problem. The methodology boils down to these steps:

  1. Declare a class template that extracts position information from a type, e.g.

    template <class Geometry>
    struct Position;
    
  2. To make your kd Tree usable with a new type, say MyAwesome2dPoint, specialize this template for it. In the specialization you can use the type's method of getting the position:

    template <>
    struct Position<MyAwesome2dPoint>
    {
        static float getX(MyAwesome2dPoint const& p) { return p.x; }
        static float getY(MyAwesome2dPoint const& p) { return p.y; } 
    }
    
  3. Use this type system in your kd tree, i.e. instead of directly accessing positions, go through the Position class:

    class KdTree 
    {
        template <class PointType>
        auto contains(PointType const& g)
        {
            // Geometric properties are accessed through the traits system.
            return contains_impl(
                Position<PointType>::getX(g), 
                Position<PointType>::getY(g));
        }
    }
    
  4. For extra credit, create a concept to avoid the weird compilation errors when using a type that hasn't been configured to work with your library:

    template <class G>
    concept Positionable = requires (G g) { 
        Position<G>::getX() + Position<G>::getY(); 
    }; 
    
    // So now you can explicitly operate on such types
    template <Positionable G>
    auto contains(G const& g)
    {
    }
    

No inheritance, no virtuals, no modifications to existing types. Just create a layer that can be specialized for everyone (even C types) and you're good to go. Concepts will save your life when abstracting even further, e.g. boost geometry generalizes to N dimensions, different coordinate systems and more.

1
  • Whooh ! This is exactly the kind of answer I was looking for :)
    – nowox
    Dec 4 '21 at 21:41

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