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Given n points, choose a point in the given list such that the sum of distances to this point is minimum ,compared to all others.

Distance is measured in the following manner.

For a point (x,y) all 8 adjacent points have distance 1.



More clearer explanation.

A function foo is defined as

foo(point_a,point_b) = max(abs(point_a.x - point_b.x),abs(point_a.y - point_b.y))

Find a point x such that sum([foo(x,y) for y in list_of_points]) is minimum.



12 -14
-3 3
-14 7
-14 -3
2 -12
-1 -6


-1 -6

Eg: Distance between (4,5) and 6,7) is 2.

This can be done in O(n^2) time, by checking the sum of each pair. Is there any better algorithm to do it?

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Just for reference: A clone of this question is posted on Programming puzzles and Code golf. –  Paŭlo Ebermann Aug 15 '11 at 2:57
looks like variation on smalles circle problem, which is O(n) –  TMS Aug 15 '11 at 12:05
This is a copy of a question on interviewstreet.com -- I'm not sure if the guys running it would like this here. –  Nabb Aug 16 '11 at 8:24
Btw this is not called 'median', it's called 'Fermat point'. And we want to find that point in the list closest to it. –  smci Aug 26 '12 at 3:19

2 Answers 2

Update: it sometimes fails to find the optimum, I'll leave this here till I find the problem.

this is O(n): nth is O(n) (expected, not worst), iterating over the list is O(n). If you need strict O() then pick the middle element with sorting but then it's going to be O(n*log(n)).

Note: it's easy to modifiy it to return all the optimal points.

import sys

def nth(sample, n):
    pivot = sample[0]
    below = [s for s in sample if s < pivot]
    above = [s for s in sample if s > pivot]
    i, j = len(below), len(sample)-len(above)
    if n < i:      return nth(below, n)
    elif n >= j:   return nth(above, n-j)
    else:          return pivot

def getbest(li):
    ''' li is a list of tuples (x,y) '''
    l = len(li)
    lix = [x[0] for x in li]
    liy = [x[1] for x in li]

    mid_x1 = nth(lix, l/2) if l%2==1 else nth(lix, l/2-1)
    mid_x2 = nth(lix, l/2)
    mid_y1 = nth(liy, l/2) if l%2==1 else nth(liy, l/2-1)
    mid_y2 = nth(liy, l/2)

    mindist = sys.maxint
    minp = None
    for p in li:
        dist = 0 if mid_x1 <= p[0] <= mid_x2 else min(abs(p[0]-mid_x1), abs(p[0]-mid_x2))
        dist += 0 if mid_y1 <= p[1] <= mid_y2 else min(abs(p[1]-mid_y1), abs(p[1]-mid_y2))
        if dist < mindist:
            minp, mindist = p, dist
    return minp

It's based on the solution of the one dimensional problem - for a list of numbers find a number for which the sum distance is the minimum.

The solution for this is the middle element of the (sorted) list or any number between the two middle elements (including these two elements) if there are an even number of elements in the list.

Update: my nth algorithm seems to be very slow, probably there is a better way to rewrite it, sort outperforms it with < 100000 elements, so if you do speed comparison, just add sort(lix); sort(liy); and

def nth(sample, n):
    return sample[n]

For anyone out there who wants to test his solution, here is what I use. Just run a loop, generate input and compare your solution with the output of bruteforce.

import random
def example(length):
    l = []
    for x in range(length):
        l.append((random.randint(-100, 100), random.randint(-100,100)))
    return l

def bruteforce(li):
    bestsum = sys.maxint
    bestp = None
    for p in li:
        sum = 0
        for p1 in li:
            sum += max(abs(p[0]-p1[0]), abs(p[1]-p1[1]))
        if sum < bestsum:
            bestp, bestsum = p, sum
    return bestp
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how is nth O(n)? is it expected to recurse a fixed number of times? –  andrew cooke Aug 14 '11 at 23:58
no, but the processed list shrinks exponentially. en.wikipedia.org/wiki/… –  Karoly Horvath Aug 15 '11 at 0:07
cute, thanks. i'm about to post a fixed "brain dead" version. could you have a look at it again? –  andrew cooke Aug 15 '11 at 0:10
What's the point with mid_x1 <= p[0] <= mid_x1? Should be just p[0] == mid_x1. Plus can you further explain getbest? I don't understand what you are doing. –  Evpok Aug 15 '11 at 0:12
@yi_H Since the metric considered is Dinf, shouldn't dist be the max of the x- and y-distances to the median set instead of their sum? –  Evpok Aug 15 '11 at 0:38

I can imagine a scheme better than O(n^2), at least in the common case.

Build a quadtree out of your input points. For each node in the tree, compute the number and average position of the points within that node. Then for each point, you can use the quadtree to compute its distance to all other points in less than O(n) time. If you're computing the distance from a point p to a distant quadtree node v, and v doesn't overlap the 45 degree diagonals from p, then the total distance from p to all the points in v is easy to compute (for v which are more horizontally than vertically separated from p, it is just v.num_points * |p.x - v.average.x|, and similarly using y coordinates if v is predominately vertically seperated). If v overlaps one of the 45 degree diagonals, recurse on its components.

That should beat O(n^2), at least when you can find a balanced quadtree to represent your points.

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