Pick a point (randomly is easiest and has a good expected running time, although you can find a median point deterministically in linear time), split the axes into four quadrants:

```
x |
| x x
x | x
-----------x-----------
x |
x | x
| x
```

Denote the quadrants in counter-clockwise direction from top-left by `I`

,`II`

,`III`

,`IV`

:

```
II | I
----|----
III | IV
```

We shall disregard points that lie on the axes (edge case with theoretical probability of 0, and easily dealt with practically).

Note that all points in quadrant `III`

form a positively-sloped line with all points in `I`

, similarly no points from `II`

will form p.s. lines with points in `IV`

, so we recursively call:

```
NumPSLines(G) = |I|*|III| +
NumPSLines(I U II) +
NumPSLines(II U III) +
NumPSLines(III U IV)
```

Where `U`

denotes union.

Assuming (proof left to reader) that the *expected* values `E(|I|) = ... E(|IV|) = |G|/4 = n/4`

and that the partition into quadrants is linear then we get an expected run time of:

```
T(n) = O(n) + 3T(n/2)
= O(n) + ... + 3^k * t(n/2^k) // where k = log2(n)
= O( log2(n) * 3^log2(n) )
= O(n^(log2(3)) * logn)
~ O(n^1.6 * logn)
```

Not sure if that bound is tight; haven't thought about it much.

This solution can be super optimised, although it's a start.