I have an array of points, and my goal is to pick two so that I maximize the area of the rectangle formed by the two points (one representing the low left corner and the other one the right top corner).

I could do this in O(n^2) by just doing two for loops and calculating every single possible area, but I think there must be a more efficient solution:

max_area = 0
for p1 in points:
    for p2 in points:
       area = p2[0]p2[1] + p1[0]p1[1] - p2[1]p1[0] - p2[0]p1[1]
       if area > max_area:
           max_area = area

It's clear that I want to maximize the area of the second point with the origin (0,0) (so p2[0]p2[1]), but I'm not sure how to go forward with that.

  • 2
    Can you please post what have you tried til now?
    – Zakk
    Sep 21 '21 at 21:58
  • yes, sorry, I added some more info
    – Trevor2001
    Sep 21 '21 at 22:07
  • On inspection, seems like a problem that would benefit from spacial partitioning. Maybe k-d trees?
    – Neil
    Sep 22 '21 at 2:43

Yes, there's an O(n log n)-time algorithm (that should be matched by an element distinctness lower bound).

It suffices to find, for each p1, the p2 with which it has the largest rectangular area, then return the overall largest. This can be expressed as a 3D extreme point problem: each p2 gives rise to a 3D point (p2[0], p2[1], p2[0] p2[1]), and each p1 gives rise to a 3D vector (-p1[0], -p1[1], 1), and we want to maximize the dot product (technically plus p1[0] p1[1], but this constant offset doesn't affect the answer). Then we "just" have to follow Kirkpatrick's 1983 construction.


Say you have a rectangle formed by four points: A (top left), B (top right), C (bottom right) and D (bottom left).

The idea is to find two points p1 and p2 that are the closest to B and D respectively. This means that p1 and p2 are the furthest possible from each other.

def nearest_point(origin, points):
    nearest = None
    mindist = dist(origin, points[0])

    for p in points[1:]:
        d = dist(origin, p)
        if mindist > d:
            mindist = d
            nearest = p

    return nearest

Call it for B and D as origins:

points = [...]

p1 = nearest_point(B, points)  # one for loop
p2 = nearest_point(D, points)  # one for loop

Note that there can be multiples closest points which are equally distant from the origin (B or D). In this case, nearest_point() should return an array of points. You have to do two nested for loops to find the furthest two points.

  • I think this method have the same problem than the one of Ripi2 (see my comment). The algorithm will likely optimize the perimeter and nor the area. Sep 22 '21 at 0:10
  • @JérômeRichard: not even the perimeter. And "the furthest possible from each other" is not true. Sep 23 '21 at 12:06
  • @YvesDaoust Why isn't it true?
    – Zakk
    Sep 23 '21 at 18:35
  • It is not difficult to find configurations such that P1 and P2 are the closest to B and D, but there are other points that are furthest from each other. (For instance points very close to A and C.) Sep 23 '21 at 20:29
  • @YvesDaoust OP's question is: maximize the area of the rectangle formed by the two points (one representing the low left corner and the other one the right top corner).
    – Zakk
    Sep 23 '21 at 20:35

Divide and conquer.

Note: This algorithm presumes that the rectangle is axis-aligned.

  • Step 1: Bucket the points into a grid of 4x4 buckets. Some buckets may get empty.
  • Step 2: Using the corners of the buckets, calculate maximum areas by opposite corners between not empty buckets. This may result in several pairs of buckets, because your work with corners, not points.
    Notice also that you use left corners for left buckets, and so for bottom, right, top corners for those b,r,t buckets. That's why an even number is used for the size of the grid.
  • Step 3: Re-bucket each bucket selected in step 2 as a new, smaller, 4x4 grid.
  • Repeat steps 2 & 3 until you get only a pair of buckets that contain only a point in each bucket.

I have not calculated the complexity of this algorithm. Seems O(n log(n)).

  • 1
    The distance is not sufficient to find the best solution. I think your algorithm is good to find the rectangle with the biggest perimeter (linear) but not the biggest area (non-linear). Sep 22 '21 at 0:06
  • I've edited my answer to calculate areas instead of distances.
    – Ripi2
    Sep 22 '21 at 0:10

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