# How to find the greatest possible euclidean distance we can achieve by moving using given set of vectors

That's a problem from Polish Olympiad in Informatics, called Pionek (PIO).

Given a set of not unique vectors, find the greatest possible euclidean distance in reference to (0,0) point you can achieve by moving using vectors from the set. Every vector can be used only once. Return square of found distance.

1. For every vector `[x, y]` from set, we know that `10^-4 <= x,y <= 10^4`

2. For n, number of vectors in set, the inequality `n <= 200 000` is satisfied

3. Memory limit is `128MB`

Example input:

``````5 -> number of vectors
2 -2 -> [x, y] vector
-2 -2
0 2
3 1
-3 1
``````

We will achieve the best result by choosing vectors [0,2], [3,1], [2, -2]. Our final destination point will be (5, 1), so the square of euclidean distance from (0,0) to (5,1) is 26, and that's valid result for this input.

I wrote below brute force solution:

``````#include <iostream>
#include <vector>

using namespace std;

long long solve(const vector<pair<int, int>>& points, int i, int x, int y) {
if (i == points.size())
return 1LL * x * x + 1LL * y * y;

long long ans = 0;
ans = max(solve(points, i + 1, x, y), solve(points, i + 1, x + points[i].first, y + points[i].second));
return ans;
}

int main()
{
ios_base::sync_with_stdio(false);
cin.tie(nullptr);
cout.tie(nullptr);

int n;
cin >> n;

vector<pair<int, int>> points(n);
for (int i = 0; i < n; ++i)
cin >> points[i].first >> points[i].second;

cout << solve(points, 0, 0, 0);
}
``````

Of course, it's too slow (most of test cases require execution time below 0.5s or below 1.5s). I can use memoization, but then I exceed the memory limit.

Except above brute force, I have no idea what could I do. How can we solve it with acceptable time complexity, like O(nlogn)?

• Sort first?!!!? Commented Jun 9 at 18:32
• It would help if you described what you mean with "brute force", because that's sometimes not totally clear. Commented Jun 9 at 18:36
• @UlrichEckhardt The brute force solution provided here is just trying all subsets of the vectors. Commented Jun 9 at 18:38
• @AhmedAEK This problem was from a contest (so it is certainly solvable) and there is a clear O(N log N) solution. Commented Jun 9 at 19:18
• Note that, though perhaps obvious, for any collection of vectors, the end point is the same for all orderings of those vectors. Commented Jun 9 at 22:02

1. You sort all vectors so that they increase in angle. `atan2()` helps you there.