The following is probably not optimized, but its complexity is the one your interviewer requested.

First create a list of (a,b,c) values for each couple of points (N² complexity)
--> (a,b,c) stands for the cartesian equation of a straight line a*x+b*y+c=0
Given two points and their coordinates (xa, ya) and (xb, yb), computing (a,b,c) is simple.
Either you can find a solution to

```
ya=alpha*xa+beta
yb=alpha*xb+beta
(if (xb-xa) != 0)
alpha = (yb-ya)/(xb-xa)
beta = ya - alpha*xa
a = alpha
b = -1
c = beta
```

or to

```
xa = gamma*ya+delta
xb = gamma*yb+delta
(you get the point)
```

The solvable set of equations can then be rewritten in the more general form

```
a*x+b*y+c = 0
```

Then sort the list (N² log(N²) complexity therefore N²log(N) complexity).

Iterate over elements of the list. If two sequential elements are equal, corresponding points are collinear. N² complexity.

You might want to add a last operation to filter duplicate results, but you should be fine, complexity-wise.

**EDIT** : i updated a bit the algorithm while coding it to make it more simple and optimal. Here it goes.

```
#include <map>
#include <set>
#include <vector>
#include <iostream>
struct StraightLine
{
double a,b,c;
StraightLine() : a(0.),b(0.),c(0.){}
bool isValid() { return a!=0. || b!= 0.; }
bool operator<(StraightLine const& other) const
{
if( a < other.a ) return true;
if( a > other.a ) return false;
if( b < other.b ) return true;
if( b > other.b ) return false;
if( c < other.c ) return true;
return false;
}
};
struct Point {
double x, y;
Point() : x(0.), y(0.){}
Point(double p_x, double p_y) : x(p_x), y(p_y){}
};
StraightLine computeLine(Point const& p1, Point const& p2)
{
StraightLine line;
if( p2.x-p1.x != 0.)
{
line.b = -1;
line.a = (p2.y - p1.y)/(p2.x - p1.x);
}
else if( p2.y - p1.y != 0. )
{
line.a = -1;
line.b = (p2.x-p1.x)/(p2.y-p1.y);
}
line.c = - line.a * p1.x - line.b * p1.y;
return line;
}
int main()
{
std::vector<Point> points(9);
for( int i = 0 ; i < 3 ; ++i )
{
for( int j = 0; j < 3 ; ++j )
{
points[i*3+j] = Point((double)i, (double)j);
}
}
size_t nbPoints = points.size();
typedef std::set<size_t> CollinearPoints;
typedef std::map<StraightLine, CollinearPoints> Result;
Result result;
for( int i = 0 ; i < nbPoints ; ++i )
{
for( int j = i + 1 ; j < nbPoints ; ++j )
{
StraightLine line = computeLine(points[i], points[j]);
if( line.isValid() )
{
result[line].insert(i);
result[line].insert(j);
}
}
}
for( Result::iterator currentLine = result.begin() ; currentLine != result.end(); ++currentLine )
{
if( currentLine->second.size() <= 2 )
{
continue;
}
std::cout << "Line";
for( CollinearPoints::iterator currentPoint = currentLine->second.begin() ; currentPoint != currentLine->second.end() ; ++currentPoint )
{
std::cout << " ( " << points[*currentPoint].x << ", " << points[*currentPoint].y << ")";
}
std::cout << std::endl;
}
return 0;
}
```