Find missing element

I saw the following question:

Given an array A of integers, find an integer k that is not present in A. Assume that the integers are 32-bit signed integers.

How to solve it?

Thank you

//// update -- This is the provided solution - but I don't think it is correct //// Consider a very simple hash function F(x)=x mod (n+1). we can build a bit-vector of length n+1 that is initialized to 0 and for every element in A, we set bit F(A[i]) to 1.Since there are only n elements in the array, we can find the missing element easily.

I think the above solution is wrong.

For example, A [ 2, 100, 4 ], then both 4 and 100 will match to the same place.

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@leppie, Obviously, they are different. – q0987 Jan 22 '11 at 20:26
And is this homework or an interview question? – Henk Holterman Jan 22 '11 at 20:27
@leppie, I have to say you may read the question careful. your original solution has nothing to do with this question at all. – q0987 Jan 22 '11 at 20:31
@q0987: OK, I think I get it. You want an optimal solution for finding an integer not in a set/array A? If so, define the question better. I would be seriously upset if I was asked such a vague and ambiguous question in an interview. – leppie Jan 22 '11 at 20:34
@q0987 Regarding the update: It mentions "the missing element". That is totally different to the question you asked. The solution you post finds the missing number from the range 1..n+1. Voting to close as not a real question. – marcog Jan 22 '11 at 20:46

If I'm interpreting the question correctly, (find any integer not in A) and `n` is the number of elements in A, then the answer is correct as given.

The fact that the hash function can have collisions doesn't really matter; By the pigeonhole principle in reverse, there will be some bit in the bit vector that is not set - because it has more bits than there are elements in A. The corresponding value is an integer not in A. In the case where the hash function has collisions, there will actually be more than one bit not set, which works in favor of the algorithm's correctness rather than against it.

To illustrate, here's how your example would work out:

``````A = [2, 100, 4]
n = length(A) = 3
f(x) = x mod 4
map(f,A) = [2, 0, 0]
``````

so the final bit vector will be:

``````[1,0,1,0]
``````

From there, we can arbitrarily choose any integer corresponding to any 0 bit, which in this case is any odd number.

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and as I understood your solution is exactly the solution from the book. They are both, of course, correct. – Max Jan 22 '11 at 21:41
Yes, that's what I was getting at - the solution quoted in the question is exactly right, I was just illustrating it because the question presented `A=[2,100,4]` as a possible counterexample. – mokus Jan 22 '11 at 22:02
``````max (items) + 1
``````

springs to mind. Of course it would fail if one of the elements was 2^31-1 and another was -(2^32).

Failing that, sort them and look for an interval.

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good try. This was listed as one of the solution but it doesn't work always. - thx – q0987 Jan 22 '11 at 20:34
OK, some sequences are not going to have gaps, but assuming that there does exist a number not in the array (like, if its less than 16GB in size) then max+1 will work instead. Or have I missed something subtle? – Paul Johnson Jan 22 '11 at 20:37

Since there appear to be no upperbounds or other constraints:

``````for (int i = int.MinValue; i <= int.MaxValue; i++)
{
if (! A.Contains(i))
{
// found it !
break;
}
}
``````
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