# Algorithm to find 100 closest stars to the origin

First let me phrase the proper question:

Q: There is a file containing more than a million points (x,y) each of which represents a star. There is a planet earth at (a,b). Now, the task is to build an algorithm that would return the 100 closest stars to earth. What would be the time and space complexities of your algorithm.

This question has been asked many times in various interviews. I tried looking up the answers but could not find a satisfactory one.

One way to do it which I thought might be using a max heap of size 100. Calculate distances for each star and check if the distance is lesser than the root of the max heap. If yes, replace it with the root and call heapify.

P.S: This is not a homework question.

-
possible duplicate of Find the x smallest integers in a list of length n –  hugomg Feb 8 '12 at 22:16
Yes, pity. It's an interesting question, but already answered here. –  Daniel Fischer Feb 8 '12 at 22:21
@missingno: It is kind of similar but that question can easily be solved by the solution which I have provided above. Here, there is some extra calculations required and I wanted to know if there is a way to minimize them. –  noMAD Feb 8 '12 at 22:31

You can actually do this in time O(n) and space O(k), where k is the number of closest points that you want, by using a very clever trick.

The selection problem is as follows: Given an array of elements and some index i, rearrange the elements of the array such that the ith element is in the right place, all elements smaller than the ith element are to the left, and all elements greater than the ith element are to the right. For example, given the array

``````40  10  00  30  20
``````

If I tried to select based on index 2 (zero-indexed), one result might be

``````10  00  20  40  30
``````

Since the element at index 2 (20) is in the right place, the elements to the left are smaller than 20, and the elements to the left are greater than 20.

It turns out that since this is a less strict requirement than actually sorting the array, it's possible to do this in time O(n), where n is the number of elements of the array. Doing so requires some complex algorithms like the median-of-medians algorithm, but is indeed O(n) time.

So how do you use this here? One option is to load all n elements from the file into an array, then use the selection algorithm to select the top k in O(n) time and O(n) space (here, k = 100).

But you can actually do better than this! For any constant k that you'd like, maintain a buffer of 2k elements. Load 2k elements from the file into the array, then use the selection algorithm to rearrange it so that the smallest k elements are in the left half of the array and the largest are in the right, then discard the largest k elements (they can't be any of the k closest points). Now, load k more elements from the file into the buffer and do this selection again, and repeat this until you've processed every line of the file. Each time you do a selection you discard the largest k elements in the buffer and retain the k closest points you've seen so far. Consequently, at the very end, you can select the top k elements one last time and find the top k.

What's the complexity of the new approach? Well, you're using O(k) memory for the buffer and the selection algorithm. You end up calling select on a buffer of size O(k) a total of O(n / k) times, since you call select after reading k new elements. Since select on a buffer of size O(k) takes time O(k), the total runtime here is O(n + k). If k = O(n) (a reasonable assumption), this takes time O(n), space O(k).

Hope this helps!

-
Thanks, I did learn a few things :) –  noMAD Feb 8 '12 at 22:35
To this I would add one more optimization. Before adding a new element to the buffer, discard if it is larger than the k'th largest found in previous iterations. And in this "larger than" test, you can first check whether any single coordinate is larger before you test the actual distance. This doesn't change the big-O at all, but it avoids a lot of distance calculations, and the square root operation is fairly slow. So you get a better constant. –  btilly Feb 8 '12 at 22:40
@btilly: you can always avoid the sqrt operation, since sqrt is a monotonic function. Points that minimize distance also minimize distance squared (the square cancels out the sqrt). –  Rob Neuhaus Feb 8 '12 at 23:03
@rrenaud you're right. However multiplication is still more expensive than comparison, so avoiding squaring is still worthwhile. –  btilly Feb 9 '12 at 16:08
Excellent algorithm and explanation. –  Håvard Geithus Jul 28 '12 at 16:40

It's a famous question and there has been lot's of solution for that: http://en.wikipedia.org/wiki/K-nearest_neighbor_algorithm

if you did not find it useful, there are some other resources such as Rurk's computational geometry book.

-
The query point is already known in this case, so we dont even have to go to knn. –  Sid Datta Feb 8 '12 at 23:43

Your algorithm is correct. Just remember that time complexity of your program is O(n . log 100 ) = O(n), unless number of closest points to find can vary.

-