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I had this question in interview which I couldn't answer. You have to find first unique element(integer) in the array. For example:

3,2,1,4,4,5,6,6,7,3,2,3

Then unique elements are 1, 5, 7 and first unique of 1.

The Solution required:

O(n) Time Complexity.

O(1) Space Complexity.

I tried saying:

Using Hashmaps, Bitvector...but none of them had space complexity O(1).

Can anyone tell me solution with space O(1)?

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Do the elements always appear together? –  smk Feb 23 '13 at 22:00
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@AleksandarToplek next or prev; also careful of OOB –  Jan Dvorak Feb 23 '13 at 22:02
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No....@smk The elements may not appear together....@Jan The elements can be positive/negative/Zero.... –  anup.stackoverflow Feb 23 '13 at 22:03
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If neither is true, Im gonna stick my head out and say not possible with O(n) time and O(1) space –  smk Feb 23 '13 at 22:06
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I think OP probably forgot some of the conditions on the original problem. This would have been solved by now if it were possible. Just thinking about a proof of impossibility now... –  Andrew Mao Feb 23 '13 at 22:31

3 Answers 3

up vote 9 down vote accepted

Here's a non-rigorous proof that it isn't possible: It is well known that duplicate detection cannot be better than O(n * log n) when you use O(1) space. Suppose that the current problem is solvable in O(n) time and O(1) memory. If we get the index 'k' of the first non-repeating number as anything other than 0, we know that k-1 is a repeated and hence with one more sweep through the array we can get its duplicate making duplicate detection a O(n) exercise.

Again it is not rigorous and we can get into a worst case analysis where k is always 0. But it helps you think and convince the interviewer that it isn't likely to be possible.

http://en.wikipedia.org/wiki/Element_distinctness_problem says: Elements that occur more than n/k times in a multiset of size n may be found in time O(n log k). Here k = n since we want elements that appear more than once.

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+1, nice - could you add a reference for the impossibility of O(n) time, O(1) space duplicate detection? –  us2012 Feb 24 '13 at 0:50
    
I can't find a link to the original paper (had studied it in a grad course). There's interesting information in en.wikipedia.org/wiki/Element_distinctness_problem. –  user1952500 Feb 24 '13 at 0:59

I think that this is impossible. This isn't a proof, but evidence for a conjecture. My reasoning is as follows...

First, you said that there is no bound on value of the elements (that they can be negative, 0, or positive). Second, there is only O(1) space, so we can't store more than a fixed number of values. Hence, this implies that we would have to solve this using only comparisons. Moreover, we can't sort or otherwise swap values in the array because we would lose the original ordering of unique values (and we can't store the original ordering).

Consider an array where all the integers are unique:

1, 2, 3, 4, 5, 6, 7, 8, 9, 10

In order to return the correct output 1 on this array, without reordering the array, we would need to compare each element to all the other elements, to ensure that it is unique, and do this in reverse order, so we can check the first unique element last. This would require O(n^2) comparisons with O(1) space.

I'll delete this answer if anyone finds a solution, and I welcome any pointers on making this into a more rigorous proof.

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"we can't ... swap values in the array because we would lose the original ordering of unique values." -- I believe this is disputable. –  Jan Dvorak Feb 23 '13 at 22:51
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You only need O(n) comparisons to show the first element is unique –  Jan Dvorak Feb 23 '13 at 22:51
    
Yeah but you may need O(n) times O(n) comparisons before that to show the O(n) values before it are not unique. –  G. Bach Feb 23 '13 at 22:52
    
@G.Bach O(n^2) comparisons trivially suffice. You still need a proof they're neccessary for any algorithm –  Jan Dvorak Feb 23 '13 at 22:53
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Without fiddling around with the order in which the values are stored in the array and without storing O(n) pieces of information on the worst case O(n) different values in the array, the bound of O(n^2) comparisons is tight; just take a set S of pairwise different values, put them in the first floor(n/2) places of an odd-numbered array, then a unique value k at position floor(n/2)+1, and fill the rest of the array with a random permutation of S; takes O(n^2) comparisons to see that every value in S is duplicate in the array. –  G. Bach Feb 23 '13 at 23:05

Note: This can't work in the general case. See the reasoning below.

Original idea

Perhaps there is a solution in O(n) time and O(1) extra space.

It is possible to build a heap in O(n) time. See Building a Heap.

So you built the heap backwards, starting at the last element in the array and making that last position the root. When building the heap, keep track of the most recent item that was not a duplicate.

This assumes that when inserting an item in the heap, you will encounter any identical item that already exist in the heap. I don't know if I can prove that . . .

Assuming the above is true, then when you're done building the heap, you know which item was the first non-duplicated item.

Why it won't work

The algorithm to build a heap in place starts at the midpoint of the array and assumes that all of the nodes beyond that point are leaf nodes. It then works backward (towards item 0), sifting items into the heap. The algorithm doesn't examine the last n/2 items in any particular order, and the order changes as items are sifted into the heap.

As a result, the best we could do (and even then I'm not sure we could do it reliably) is find the first non-duplicated item only if it occurs in the first half of the array.

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"This assumes that when inserting an item in the heap, you will encounter any identical item that already exist in the heap." -- I don't think that's true –  Jan Dvorak Feb 23 '13 at 23:25
    
@Jan: I'm working on a proof ... or a refutation. –  Jim Mischel Feb 23 '13 at 23:26
    
I'll be impressed to see a proof –  Jan Dvorak Feb 23 '13 at 23:27
    
Why would the heap only require O(1) space? Assuming there are O(n) pairwise different values in the array, I don't see how that would work. –  G. Bach Feb 23 '13 at 23:27
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@jim-mischel suppose the (min) heap has 1 as root and 2 as left child, and nothing more. Insert 2. You'll insert it at the end of the heap, then you'll try to sift it up, but it won't move since it's already at the right place. No clue that his brother is also a 2. –  naitoon Feb 24 '13 at 3:42

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