Longest arithmetic progression of a set of numbers {ab_{1},ab_{2},ab_{3} .... ab_{n}} is defined as a subset {bb_{1},bb_{2},bb_{3} .... bb_{n}} such that b_{i+1} - b_{i} is constant.

I would like to extend this problems to a set of two dimensional points lying on a straight line.
Lets define Dist(P_{1},P_{2}) is the distance between two Points P_{1}(X_{1},Y_{1}) and P_{2}(X_{2},Y_{2}) on a line as

Dist(P_{1},P_{2}) = Dist((X_{1},Y_{1}),(X_{2},Y_{2})) = (X_{2} - X_{1})^{2} + (Y_{2} - Y_{1}))^{2}

Now For a given set of points I need to find the largest Arithmetic Progression such that Dist(P_{i},P_{i+1}) is constant, assuming they all lie on the same line (m & C are constant).

I researched a bit but could not figure out an algorithm which is better than O(n^{2}).

In fact currently the way I am doing is I am maintaining a Dictionary say

```
DistDict=dict()
```

and say Points are defined in a List as

```
Points = [(X1,Y1),(X2,Y2),....]
```

then this is what I am doing

```
for i,pi in enumerate(Points):
for pj in Points[i+1:]:
DistDict.setdefault(dist(pi,pj),set([])).add((pi,pj))
```

so all I have ended up with a dictionary of points which are of equal distance. So the only thing I have to do is to scan through to find out the longest `set`

.

I am just wondering that this ought to have a better solution, but somehow I can't figure out one. I have also seen couple of similar older SO posts but none I can find to give something that is more efficient than O(n^{2}). Is this somehow an NP Hard problem that we can never have something better or if not what approach could be take.
Please note I came across a post which claims about an efficient divide and conquer algorithm but couldn't make any head or tail out of it.

Any help in this regard?

Note*** I am tagging this Python because I understand Python better than maybe Matlab or Ruby. C/C++/Java is also fine as I am somewhat proficient in these too :-)