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This is probably a Microsoft interview question.

Find the kth smallest element (ignoring duplicates) out of an sorted array.
[EDIT]: The array may contain duplicates(not specified).

Thought a bunch of times, but still questioning myself: Does there still exist a better solution?

Approach 1:

Take a max heap & insert first k unique elements[can be easily checked]. Heapify the heap.
Now, when a new element is smaller than the head of the heap,replace head with this new element heapify it. At the last, the head of the heap indicates kth smallest element if size of the heap is k else kth smallest element doesn't exist.

Time complexity: O(NlogK)
Space complexity: O(K)

Approach 2[A better approach]:

The elements may be duplicated right. So, check for unique elements by comparing with its previous elements & stop if unique variables found so far counts to k.
Time complexity: O(N)
Space complexity: O(1)

Approach 3[A better approach(may be)]:

A modified version of quick sort partition algorithm can also be used. But possibly it will lead to a worst case as the array is already sorted.
here two questions arise:
1. Does it work if the array contain duplicates?
2. Would it be better than my second apporach?


I was wondering that does there exist any O(logn) solution?

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Maybe I'm missing something, but isn't the "k-th smallest element of an sorted array" is just the k-th element of the array? The array is sorted... –  kennytm Jun 21 '12 at 17:23
    
if the array is sorted, why not take the element at k-th position? –  0605002 Jun 21 '12 at 17:23
    
@KennyTM .. Aint that easy.. It can hav duplicates.. –  bragboy Jun 21 '12 at 17:24
    
KennyTM, FlopCoder: {1,1,1,1,2,2,3,4,5,6}. Your algorithm incorrectly returns 1 for k = 3. –  Nick Miceli Jun 21 '12 at 17:24
3  
@Bragboy, ngmiceli: You didn't mention "unique elements" :) The default interpretation is to include duplicates, e.g. C++ says 1 is the correct answer for the 3rd smallest element. –  kennytm Jun 21 '12 at 17:30

2 Answers 2

up vote 8 down vote accepted

Here's an O(kLogN) solution:

Using a variation of Binary Search to find the last occurrence of a given value,

  1. Get 1st value - O(1).
  2. Search for last occurrence of this value O(logN), then look at next element to get 2nd value - O(1).
  3. Repeat until kth value is found.
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2  
This is not better than O(n) which is same as O(k) –  amit.codename13 Jun 21 '12 at 17:55
    
+1 - This is a great answer is certainly it is what the interviewer was looking for. It should be noted, though, that for some values of k and n, it is slower than the O(n) solution. –  cheeken Jun 21 '12 at 17:58
1  
@amit.codename13, generally, yes, but that's another option, which will work much better for a variety of inputs. –  unkulunkulu Jun 21 '12 at 18:01
    
Given that the value of k has an upperbound of N, I agree with @amit.codename13 in that this is O(N logN) and in the worst case just comparing the values in place would be O(N). That said, this is an interview question. They want you to come up with these kinds of out-of-the-box solutions. And for very large N and relatively small k there is a real world performance gain. That said, If I was actually paying someone to do this (not testing their abilities) I'd definitely raise my eyebrow that they didn't just scan the list in O(N) time. –  acattle Jun 22 '12 at 1:19
1  
@acattle - If this was for a real project, I'd wonder why someone didn't build a separate index of unique values, allowing for O(1) lookup. –  mbeckish Jun 22 '12 at 12:39

There appear to be two different interpretations of k-th smallest element. I am assuming it means "the k-th smallest element, ignoring duplicates."

The best solution is O(n) time and O(1) space, as you describe in approach 2. We can prove this.

  • We cannot improve upon O(1) space (at least not in O-notation).
  • Consider an approach that runs in less than O(n). Such an approach must not consider each element in the array. Consider one such missed element. It it not known if this element is or is not a duplicate of the value previous to it or after it¹, and this information is required for asserting which value in the array corresponds to the k-th smallest.

¹ It is possible to infer the values of a arbitrarily long subsequence of a sorted array in the special case that two non-adjacent array elements have the same value: all of the interim elements must share that value. But this is not a typical case, so I'm ignoring it.

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2  
the second statement contains a fallacy. That's exactly the only possible point of such a problem is that we should try hard to skip analysing those lengthy sequences of equal numbers. –  unkulunkulu Jun 21 '12 at 17:45
    
I mean, what if majority of the array is filled with 5s and the algorithm magically skips all the 5s surrounded by other 5s, the second statement doesn't show any contradiction. –  unkulunkulu Jun 21 '12 at 17:47
    
@unkulunkulu You are right that that is the only point of the problem. However, since we are not guaranteed our input data contains duplicates, we cannot make guarantees about the runtime based on optimizations that depend upon their presence. –  cheeken Jun 21 '12 at 17:57
    
check my second comment, your statement doesn't show contradiction for the case when all the skipped elements are in segments of equality. I support your idea that there's no general solution that is always better than O(n) (there is a solution that is better than O(n) for special class of inputs though), I'm just saying your proof looks wrong to me. –  unkulunkulu Jun 21 '12 at 18:04
    
@unkulunkulu I agree it doesn't demonstrate a contradiction in that case (which is why I made a footnote stating that I'm ignoring that case). Apologies if things are unclear. –  cheeken Jun 21 '12 at 18:08

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