# Optimisation of recursive algorithm in Java

## 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);
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?

-
Why not cache `f` as well? Just move parameter `points` from function parameter to class member. –  Dialecticus Aug 15 '12 at 11:41
@Dialecticus I think this would work even better if I stored a subset of `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
Yes, so main function would run these operations: clear P cache, clear F cache, get S1, add Q, clear F cache, get S2. –  Dialecticus Aug 15 '12 at 14:30
I don't think it would need to the clear the whole F cache, just the section to the right of Q. –  fophillips Aug 15 '12 at 14:46

You also need to memoize `f` on the first 2 arguments (the 3rd is always passed through, so you don't need to worry about that). This will reduce the time complexity of your code from O(2^n) to O(n).

-

UPDATED:

Since as commented below, order can not be used to help optimize another method must be utilized. Since most of the P values will be calculated multiple times (and as noted, this is expensive), one optimization would be to cache them. I am not sure of what the best key would be, but you could imagine changing the code something like:

``````....
private Map<String, Double> previousResultMap = new ....

private Double p(DataPoint right, Event rightEvent, DataPoint left, Event leftEvent) {
String key = // calculate unique key from inputs
Double previousResult = previousResultMap.get(key);
if (previousResult != null) {
return previousResult;
}

// do some stuff
previousResultMap.put(key, result);
return result;
}
``````

This approach should effectively reduce a lot of the redundant calculations - however, as you know the data much more than I, you will need to determine the best way to set the key (and even if String is the best representation for that).

-
If I understand you correctly I don't think this will work. As S does not just depend on the number of points. If I put `Q` at position `x` which is between point `x` and `y` then `S` without `Q` will call `p(x, xEvent, y, yEvent)` however, `S` with `Q` will call `p(x, xEvent, q, qEvent)` then `p(q, qEvent, y, yEvent)`. But I could call both `S` at the same time and only divert when one of them reaches `Q` –  fophillips Aug 15 '12 at 13:17
You should look at my own answer below! –  fophillips Aug 15 '12 at 15:53

Thanks for all your suggestions. I implemented my solution by creating new nested classes for the values of `P` and `F` already calculated, then used a `HashMap` to store the results. The `HashMap` is then queried for the result before computation takes place; if it is present it just returns the result, if it is not it computes the result and adds it to the `HashMap`.

The final product looks a bit like this:

``````public class ProbabilityCalculator {

private NavigableSet<DataPoint> points;

private ProbabilityCalculator(NavigableSet<DataPoint> points) {
this.points = points;
}

private static class P {
public final DataPoint left;
public final Event leftEvent;
public final DataPoint right;
public final Event rightEvent;

public P(DataPoint left, Event leftEvent, DataPoint right, Event rightEvent) {
this.left = left;
this.leftEvent = leftEvent;
this.right = right;
this.rightEvent = rightEvent;
}

public boolean equals(Object o) {
if(!(o instanceof P)) return false;
P p = (P) o;

if(!(this.leftEvent == null ? p.leftEvent == null : this.leftEvent.equals(p.leftEvent)))
return false;
if(!(this.rightEvent == null ? p.rightEvent == null : this.rightEvent.equals(p.rightEvent)))
return false;

return this.left.equals(p.left) && this.right.equals(p.right);
}

public int hashCode() {
int result = 93;

result = 31 * result + this.left.hashCode();
result = 31 * result + this.right.hashCode();
result = this.leftEvent != null ? 31 * result + this.leftEvent.hashCode() : 31 * result;
result = this.rightEvent != null ? 31 * result + this.rightEvent.hashCode() : 31 * result;

return result;
}
}

private Map<P, Double> usedPs = new HashMap<P, Double>();

private static class F {
public final DataPoint left;
public final Event leftEvent;
public final NavigableSet<DataPoint> dataPointsToLeft;

public F(DataPoint dataPoint, Event dataPointEvent, NavigableSet<DataPoint> dataPointsToLeft) {
this.dataPoint = dataPoint;
this.dataPointEvent = dataPointEvent;
this.dataPointsToLeft = dataPointsToLeft;
}

public boolean equals(Object o) {
if(!(o instanceof F)) return false;
F f = (F) o;
return this.dataPoint.equals(f.dataPoint) && this.dataPointEvent.equals(f.dataPointEvent) && this.dataPointsToLeft.equals(f.dataPointsToLeft);
}

public int hashCode() {
int result = 7;

result = 31 * result + this.dataPoint.hashCode();
result = 31 * result + this.dataPointEvent.hashCode();
result = 31 * result + this.dataPointsToLeft.hashCode();

return result;
}

}

private Map<F, Double> usedFs = new HashMap<F, Double>();

private Double p(DataPoint right, Event rightEvent, DataPoint left, Event leftEvent) {
P newP = new P(right, rightEvent, left, leftEvent);

if(this.usedPs.containsKey(newP)) return usedPs.get(newP);

// do some stuff

usedPs.put(newP, result);
return result;

}

private Double f(DataPoint right, Event rightEvent) {

F newF = new F(right, rightEvent, dataPointsToLeft);

if(usedFs.containsKey(newF)) return usedFs.get(newF);

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);
}

usedFs.put(newF, result)

return result;
}

public Double S() {
return f(points.last(), points.last().getRightNodeEvent(), points)
}

public static probabilityOfQ(DataPoint q, NavigableSet<DataPoint> points) {
ProbabilityCalculator pc = new ProbabilityCalculator(points);

Double S1 = S();