Both @LaC's and @MizardX's solution are very interesting, but you can combine them to get even better solution.

The problem with @LaC's solution is that you get random choices rejected. The more points you have already generated the harder it gets to generate new ones. If there is only one available position left you have slight chance of randomly choosing it (1/(n*m)).

In the @MizardX's solution you never get rejected choices, however if you directly implement the "Remove every point from L which are linear to P-Q." step you'll get worse complexity (O(n^5)).

Instead it would be better to use a bitmap to find which points from L are to be removed. The bitmap would contain a value indicating whether a point is free to use and what is its location on the L list or a value indicating that this point is already crossed out. This way you get worst-case complexity of O(n^4) which is probably optimal.

EDIT:

I've just found that question: Generate Non-Degenerate Point Set in 2D - C++
It's very similar to this one. It would be good to use solution from this answer Generate Non-Degenerate Point Set in 2D - C++. Modifying it a bit to use radix or bucket sort and adding all the n^2 possible points to the P set initially and shufflying it, one can also get worst-case complexity of O(n^4) with a much simpler code. Moreover, if space is a problem and @LaC's solution is not feasible due to space requirements, then this algorithm will just fit in without modifications and offer a decent complexity.

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