# x+y-z between -1 and 1 [closed]

Let `[a_1 a_2 ... a_n]` be a list of distinct integers in the range `[1,10n]`. Give an algorithm that returns `true` if there are three distinct elements `x,y,z` such that `-1 <= x+y-z <= 1`, and `false` otherwise.

A brute force algorithm (checking all possible combinations of `x+y-z`, runs in time `O(n^3)`. Are there more efficient algorithms?

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Are you having a specific problem while trying to implement this, or are you just posting your homework problem verbatim? –  Wiseguy Oct 12 '12 at 19:26
What have you tried so far? –  japreiss Oct 12 '12 at 19:26
Nope, I don't have a problem with implementing the brute force algo. I was wondering whether there are more efficient algorithms. –  John Oct 12 '12 at 19:47
Why the down & close votes? :\ –  amit Oct 12 '12 at 19:59
@amit: It is an algorithm problem phrased as a general programming question, so it is hard to see what the user is looking for. Additionally people tend to close questions that they think can't be answered. Too localized is the primary reason right now, I disagree but can see where they are coming from. –  Guvante Oct 12 '12 at 20:30

## closed as too localized by Bart Kiers, Mark, Pondlife, Jon Lin, S.L. BarthOct 12 '12 at 21:30

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Yes, there is. Here is an `O(n^2)` worst case algorithm that uses `O(n)` additional space.

The idea is to check for all possible pairs (instead of triples), and iteratively marks which elements you have already seen, and compare against them the sum of each pair.
For each pair, check its sum has matching element which is exactly the sum (`x+y-z == 0`) or an element you can get to if you add 1 (`x+y+1-z == 0 -> x+y-z = -1`) or you can get to if you reduce 1 (`x+y-1-z == 0 -> x + y - z == 1`)

Pseudo code:

``````mark = new boolean[10n]; //all initialized to false
sort arr //O(nlogn)
for each i in n,1: (reverse order)
for each j in 1,i-1:
//neglected range check, make sure it is done
if (mark[arr[i]+arr[j]] || mark[arr[i]+arr[j]+1] || mark[arr[i]+arr[j]-1]):
return true
mark[arr[i]] = true
return false
``````

Note that we iterate `i` from `n` to 1, because `z > x` and `z > y` - and we want to make sure we are checking all pairs with element that is already in the list if it is there

Correctness Proof:
If there is a solution `x+y-z = 0` - then `z > x` and `z > y` (all elements are positive distinct integers).
Without loss of generality, let's assume `x > y`. So, when iterating `arr[i]=x` in outer loop, there is some `j<i` such that `arr[j]=y`. Also, since `z>x` - `mark[z] == true` - since we marked it when we previously iterated it.
Thus: The algorithm will find `mark[arr[x] + arr[y]] == true`, and yield `true`.
similar proof for the `+-1` cases.

If the algorithm yielded true, then it found one of the conditions true. Let's assume it is `mark[arr[i] + arr[j]]` (The proof for the other cases will be similar).
So, we found out `mark[arr[i] + arr[j]] == true` - so we inserted it since there is some element `z` such that `z = arr[i] + arr[j]`, and the algorithm is correct for this case.

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Nice algorithm! It's interesting whether there exists an `O(n log n)` algorithm. –  John Oct 12 '12 at 20:23