## Background

I have an ordered set of data points stored as a `TreeSet<DataPoint>`

. Each data point has a `position`

and a `Set`

of `Event`

objects (`HashSet<Event>`

).

There are 4 possible `Event`

objects `A`

, `B`

, `C`

, and `D`

. Every `DataPoint`

has 2 of these, e.g. `A`

and `C`

, except the first and last `DataPoint`

objects in the set, which have `T`

of size 1.

My algorithm is to find the probability of a new `DataPoint`

`Q`

at position `x`

having `Event`

`q`

in this set.

I do this by calculating a value `S`

for this data set, then adding `Q`

to the set and calculating `S`

again. I then divide the second `S`

by the first to isolate the probability for the new `DataPoint`

`Q`

.

## Algorithm

The formula for calculating `S`

is:

where

for

and

is an expensive probability function that only depends on its arguments and nothing else (and ), is the last `DataPoint`

in the set (righthand node), is the first `DataPoint`

(lefthand node), is the rightmost `DataPoint`

that isn't the node, is a `DataPoint`

, is the `Set`

of events for this `DataPoint`

.

So the probability for `Q`

with `Event`

`q`

is:

## Implementation

I implemented this algorithm in Java like so:

```
public class ProbabilityCalculator {
private Double p(DataPoint right, Event rightEvent, DataPoint left, Event leftEvent) {
// do some stuff
}
private Double f(DataPoint right, Event rightEvent, NavigableSet<DataPoint> points) {
DataPoint left = points.lower(right);
Double result = 0.0;
if(left.isLefthandNode()) {
result = 0.25 * p(right, rightEvent, left, null);
} else if(left.isQ()) {
result = p(right, rightEvent, left, left.getQEvent()) * f(left, left.getQEvent(), points);
} else { // if M_k
for(Event leftEvent : left.getEvents())
result += p(right, rightEvent, left, leftEvent) * f(left, leftEvent, points);
}
return result;
}
public Double S(NavigableSet<DataPoint> points) {
return f(points.last(), points.last().getRightNodeEvent(), points)
}
}
```

So to find the probability of `Q`

at `x`

with `q`

:

```
Double S1 = S(points);
points.add(Q);
Double S2 = S(points);
Double probability = S2/S1;
```

## Problem

As the implementation stands at the moment it follows the mathematical algorithm closely. However this turns out not to be a particularly good idea in practice, as `f`

calls itself twice for each `DataPoint`

. So for , `f`

is called twice, then for the `n-1`

`f`

is called twice again for each of the previous calls, and so on and so forth. This leads to a complexity of `O(2^n)`

which is pretty terrible considering there can be over 1000 `DataPoints`

in each `Set`

. Because `p()`

is independent of everything except its parameters I have included a caching function where if `p()`

has already been calculated for these parameters it just returns the previous result, but this doesn't solve the inherent complexity problem. Am I missing something here with regards to repeat computations, or is the complexity unavoidable in this algorithm?

`f`

as well? Just move parameter`points`

from function parameter to class member. – Dialecticus Aug 15 '12 at 11:41`points`

to the left of`right`

this would mean the cache would used even after I add`Q`

to the points once`Q`

has been passed in the process. – fophillips Aug 15 '12 at 13:19