Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I am tinkering with geospatial data, specifically Tracks (ordered sequences of geographic positions defined by latitude and longitude).

Most applications require that I calculate the cumulative distance from start to a given point. So, if I call track.totalDistance[20], for example, I would get the distance from start to the point with index 20.

Currently I am solving this by pre-calculating every consecutive distance, increasing a variable, and assigning the value to each point, which is not a good behavior because I plan to edit the track (add, delete and update points), and "total distance" is not actually an intrinsic property of a trackpoint, but of a trackpoint in the context of its containing track.

On the other hand, if I defer evaluation for a getter function, say, getTotalDistance(track, 20), there would be a lot of repetitive and actually unnecessary calculations.

So the question is: How could I implement a class in a way that I could more efficiently get the cumulative sum of an arbitrary index at any time, while avoiding unnecessary computations (full initialization or repetitive)?

Languages that I use are mostly Python, Javascript and C#, but I suppose the answer could be a general structure that could be implemented in any language.

share|improve this question

You could use a self-balancing tree, with nodes like this:

public class Node
    public Node(Node leftChild, Node rightChild)
        FirstPoint = leftChild.FirstPoint;
        LastPoint = rightChild.LastPoint;
        LeafCount = leftChild.LeafCount + rightChild.LeafCount;
        BetweenDistance = leftChild.LastPoint.DistanceTo(rightChild.FirstPoint);
        TotalDistanceSum = leftChild.TotalDistanceSum
            + BetweenDistance
            + rightChild.TotalDistanceSum;
        IsLeaf = false;
        LeftChild = leftChild;
        RightChild = rightChild;

    public Node(Point p)
        FirstPoint = p;
        LastPoint = p;
        LeafCount = 1;
        IsLeaf = true;

    /// The point of the leftmost decendant.
    public Point FirstPoint { get; set; }
    /// The point of the rightmost decendant.
    public Point LastPoint { get; set; }

    /// Number of leaves.
    public int LeafCount { get; set; }
    /// The distance from FirstPoint to LastPoint along the path.
    public double TotalDistanceSum { get; set; }
    /// The distance between LeftChild and RightChild.
    public double BetweenDistance { get; set; }

    /// Flag wheter this is a node or a leaf.
    public bool IsLeaf { get; set; }
    /// Left child of this non-leaf node.
    public Node LeftChild { get; set; }
    /// Right child of this non-leaf node.
    public Node RightChild { get; set; }

    /// Calculates the distance between two point along the path. 'start' is inclusive. 'end' is exclusive.
    public double DistanceSum(int start, int end)
        if (IsLeaf || start >= LeafCount || end < 0 || start >= end)
            return 0;

        if (end > LeafCount) end = LeafCount;
        if (start < 0) start = 0;

        if (start == 0 && end == LeafCount)
            return TotalDistanceSum;

        int n = LeftChild.LeafCount;
        return LeftChild.DistanceSum(start, end)
            + BetweenDistance
            + RightChild.DistanceSum(start - n, end - n);

public class Point
    public double X { get; private set; }
    public double Y { get; private set; }

    public Point(double x, double y)
        X = x;
        Y = y;

    public double DistanceTo(Point other)
        double dx = other.X - X;
        double dy = other.Y - Y;
        return Math.Sqrt(dx*dx + dy*dy);


var tree = new Node(
    new Node(
        new Node(new Point(0,0)),
        new Node(new Point(1,0))
    new Node(
        new Node(new Point(1,1)),
        new Node(new Point(0,1))
double dist = tree.DistanceSum(0,4); // returns 3.0
share|improve this answer
While this seems pretty ingenious, it's a bit too advanced for me now... I'll have to take a look at this for a while, but the words "self balancing tree" sound like what I imagine to be the best way to go in geospatial stuff like these (along with K-D-trees of course). Thank you for now! – heltonbiker Jun 3 '13 at 14:09
The self-balancing is only to ensure there is a worst-case O(log n) time for each operation. If the tree gets tilted into a linked list, it will make the operations take worst-case O(n) time. It will work fine without the self-balancing, but not always as effectively. – Markus Jarderot Jun 3 '13 at 18:17
Without self-balancing, you could recursively create a tree from each half of the nodes, and combine them into one tree. That will give you an initial balanced tree. Over time the tree probably will get skewed though. – Markus Jarderot Jun 3 '13 at 18:21

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.