# Algorighm or design pattern for efficient, random-access Cumulative Sum

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.

-

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)

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);
}
}
``````

Example:

``````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
``````
-
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