# Quadtree moving of stored points

I use a quad tree as a datastructure to store points. As I need to find in a fast way all points in certain area.

However I need to move the points. In my C++ program. As the movement happens to all points but for every point in an different direction I currently destroy my quadtree and rebuild it, which causes lots of allocation and deletion.

My question is therefore is there a better datastructure for this kind of problem?

I have the following requirements: I have n-Points.

I need to get in an fast way all points in a given certain area. With my quadtree this is about O(log(n)). However this operation is called m times where m > n therefore it is about O(m*log(n)).

I need to move all points. At the moment this runs in about O(n*logn). This method is only called once for all m.

However I find this solution at the moment unsatisfactory. As I always destroy my quadtree and rebuild it which causes an overhead due to the allocation.

UPDATE: The points are not uniformely distributed. There are positions where they are dense and some position where there are few points.

Here is some simplified code. Here the code of the pointer which are stored:

``````class Point
{
public:
Point(double x, double y):x(x),y(y){};

void movePoint(double ux, double uy);

double x;
double y;
};
``````

here is the interface of the quad tree

``````class QuadTree
{
public:
QuadTree(double north, double west, double south, double east,
int maxItems);

//inserts a point into the tree runs in log(n)
bool put(Point* pt);
// returns all point in the rectange defined by the four variables runs in log(n)
std::vector<Point*> get(double north, double west, double south, double east);
// deletes everything in the quad tree
void clear();

private:

};
``````

and here the interface of the QuadTreeNode with the get and put method implementation to show how a Point is stored.

``````class QuadTreeNode
{
public:

QuadTreeNode(double north, double west, double south, double east,
int maximumItems);

//split the node if to much items are stored.
void split();
//returns the children of the node
QuadTreeNode* getChild(double x, double y);

bool put(Point* leaf){
if (children_ == nullptr) {
items_.push_back(leaf);

if (items_.size() > maxItems_)
split();
return true;
} else {
QuadTreeNode* node = getChild(leaf->getX(), leaf->getY());
if (node != nullptr) {
return node->put(leaf);
}
}
return false;
}

if (children_ == nullptr) {
for (Point* pt : items_) {
if (rect.pointWithinBounds(pt->getX(),pt->getY())) {
vector.push_back(pt);
}
}
} else {
for (QuadTreeNode* child : *children_) {
if (child->bounds_.within(rect)) {
child->get(rect, vector);
}
}
}
return vector;
}

std::vector<Point*> items_;

unsigned int maxItems_;

std::array<QuadTreeNode*,4>* children_ = nullptr;

};
``````
-
Please, provide more info on what is your quadtree. Maybe some code snippet. –  Kirill Kobelev Oct 10 '12 at 18:56
you can re-use the previously allocated storage, avoiding allocation. –  Walter Oct 10 '12 at 19:17
if your points are nearly homogeneous (near-uniformly distributed), then it may be better to use a simple search grid (buckets), using the bit pattern of the coordinates themselves as index. –  Walter Oct 10 '12 at 19:19
I am not sure how, as the structure of the quadtree might be completely different. The points stored are not reallocated, but the quadTree might be. –  tune2fs Oct 10 '12 at 19:19
I think what Walter meant (in his first post) was to re-use the quadtree nodes when possible by re-linking node pointers, adjusting the graph as necessary. You could also maintain a 'pool' of unused nodes. Implementing either of these adds some complexity, but might be worth it if you're bottlenecking on reallocs. –  WeirdlyCheezy Oct 10 '12 at 19:38

1. For each moved point, check whether it moved out of the bounding rectangle (`bounds_`). If yes, remove it from the tree. After moving all points, either insert them into the same tree, or into another tree. Every once in a while (e.g. when the size of the other tree becomes 1/10 of the main tree), rebuild everything.