# Find all differences in an array in O(n)

Question: Given a sorted array A find all possible difference of elements from A.

My solution:

``````for (int i=0; i<n-1; ++i) {
for (int j=i+1; j<n; ++j) {
System.out.println(Math.abs(ai-aj));
}
}
``````

Sure, it's O(n^2), but I don't over count things at all. I looked online and I found this: http://www.careercup.com/question?id=9111881. It says you can't do better, but at an interview I was told you can do O(n). Which is right?

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I would be wary of taking a job at this company... They'll probably expect you to solve NP-complete problems in P time... ;-) – R.. Dec 10 '11 at 6:47
My guess would be that either you or the interviewer overlooked or overheard an additional condition. – Jens Gustedt Dec 10 '11 at 8:40
Define n to be the number of differences (size of output rather than size of input). Hey presto - it's now O(n). – Steve314 Dec 10 '11 at 10:49
for sorted array it's trivial to find duplicate elements, if the previous element is equal to the current == duplication. perhaps the question was not properly asked? – bestsss Dec 16 '11 at 21:27
@bestsss This question has nothing to do with looking for duplicates. – WisaF Dec 17 '11 at 19:13

A first thought is that you aren't using the fact that the array is sorted. Let's assume it's in increasing order (decreasing can be handled analogously).

We can also use the fact that the differences telescope (i>j):

``````a_i - a_j = (a_i - a_(i-1)) + (a_(i-1) - a_(i-2)) + ... + (a_(j+1) - a_j)
``````

Now build a new sequence, call it s, that has the simple difference, meaning `(a_i - a_(i-1))`. This takes only one pass (`O(n)`) to do, and you may as well skip over repeats, meaning skip `a_i` if `a_i = a_(i+1)`.

All possible differences `a_i-a_j` with `i>j` are of the form `s_i + s_(i+1) + ... + s_(j+1)`. So maybe if you count that as having found them, then you did it in `O(n)` time. To print them, however, may take as many as `n(n-1)/2` calls, and that's definitely `O(n^2)`.

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Ok. I see how this uses the fact that the array is sorted because you don't have to worry about absolute values. I still don't think it's really O(n), but it's probably what he had in mind. Thanks – WisaF Dec 10 '11 at 20:18

For example for an array with the elements {21, 22, ..., 2n} there are n⋅(n-1)/2 possible differences, and no two of them are equal. So there are O(n2) differences.

Since you have to enumerate all of them, you also need at least O(n2) time.

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That's what the answer in the link I gave said, but the interviewer was pretty insistent that there's a O(n) solution. – WisaF Dec 10 '11 at 5:22
Since `a[last] - a[first]` is the largest possible difference, it is also (one less than) the maximum possible number of difference values. So that's linear in something, just not in the size of the original array. Maybe there's a way to check whether each difference in turn actually occurs in time linear to the number of potential differences, but I can't think of it ATM. – Steve314 Dec 10 '11 at 11:03
Yes, O(n^2) is the worst case, but note that some differences may appear multiple times. A problem comes up: is there an output-sensitive algorithm, with O(k) time complexity (or similar), where k is the number of unique differences? This means for example, for special inputs where k=O(n), the algorithm would take just O(n). – Ambroz Bizjak Dec 11 '11 at 18:39
For example, for inputs of the form [i, i, ..., i], where i!=0, there are exactly n-1 differences. – Ambroz Bizjak Dec 11 '11 at 18:47
Sorry, there's really just one difference, that being zero... – Ambroz Bizjak Dec 11 '11 at 18:53

sorted or unsorted doesn't matter, if you have to calculate each difference there is no way to do it in less then n^2,

the question was asked wrong, or you just do O(n) and then print 42 the other N times :D

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If the interviewer is fond of theoretical games, perhaps he was thinking of using a table of inputs and results? Any problem with a limit on the size of the input, and that has a known solution, can be solved by table lookup. Given that you have first created and stored that table, which might be large.

So if the array size is limited, the problem can be solved by table lookup, which (given some assumptions) can even be done in constant time. Granted, even for a maximum array size of two (assuming 32-bit integers) the table will not fit in a normal computer's memory, or on the disks. For larger max sizes of the array, you're into "won't fit in the known universe" size. But, theoretically, it can be done.

(But in reality, I think that Jens Gustedt's comment is more likely.)

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You can get another counter-example by assuming the array contents are random integers before sorting. Then the chance that two differences, Ai - Aj vs Ak - Al, or even Ai - Aj vs Aj - Ak, are the same is too small for there to be only O(n) distinct differences Ai - Aj.

Given that, the question to your interviewer is to explain the special circumstances that allow an O(n) solution. One possibility is that the array values are all numbers in the range 0..n, because in this case the maximum absolute difference is only n.

I can do this in O(n lg n) but not O(n). Represent the array contents by an array of size n+1 with element i set to 1 where there is a value i in the array. Then use FFT to convolve the array with itself - there is a difference Ai - Aj = k where the kth element of the convolution is non-zero.

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