# How to know that a triangle triple exists in our array?

I was stuck in solving the following interview practice question:
I have to write a function:

``````int triangle(int[] A);
``````

that given a zero-indexed array A consisting of `N` integers returns `1` if there exists a triple (P, Q, R) such that `0 < P < Q < R < N`.

``````A[P] + A[Q] > A[R],
A[Q] + A[R] > A[P],
A[R] + A[P] > A[Q].
``````

The function should return `0` if such triple does not exist. Assume that `0 < N < 100,000`. Assume that each element of the array is an integer in range `[-1,000,000..1,000,000]`.

For example, given array `A` such that

``````A[0]=10, A[1]=2, A[2]=5, A[3]=1, A[4]=8, A[5]=20
``````

the function should return `1`, because the triple `(0, 2, 4)` fulfills all of the required conditions.

For array `A` such that

``````A[0]=10, A[1]=50, A[2]=5, A[3]=1
``````

the function should return `0`.

If I do a triple loop, this would be very very slow (complexity: `O(n^3)`). I am thinking maybe to use to store an extra copy of the array and sort it, and use a binary search for a particular number. But I don't know how to break down this problem.
Any ideas?

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(0, 2, 4) doesn't fit: 0 + 2 is not > 4. –  Vlad Mar 22 '11 at 12:32
He is mentioning the index numbers as the answer ... 10 , 5 , 8 –  user506710 Mar 22 '11 at 12:33

First of all, you can sort your sequence. For the sorted sequence it's enough to check that `A[i] + A[j] > A[k]` for `i < j < k`, because `A[i] + A[k] > A[k] > A[j]` etc., so the other 2 inequalities are automatically true.

(From now on, `i < j < k`.)

Next, it's enough to check that `A[i] + A[j] > A[j+1]`, because other `A[k]` are even bigger (so if the inequality holds for some `k`, it holds for `k = j + 1` as well).

Next, it's enough to check that `A[j-1] + A[j] > A[j+1]`, because other `A[i]` are even smaller (so if inequality holds for some `i`, it holds for `i = j - 1` as well).

So, you have just a linear check: you need to check whether for at least one `j` `A[j-1] + A[j] > A[j+1]` holds true.

Altogether `O(N log N) {sorting} + O(N) {check} = O(N log N)`.

Addressing the comment about negative numbers: indeed, this is what I didn't consider in the original solution. Considering the negative numbers doesn't change the solution much, since no negative number can be a part of triangle triple. Indeed, if `A[i]`, `A[j]` and `A[k]` form a triangle triple, then `A[i] + A[j] > A[k]`, `A[i] + A[k] > A[j]`, which implies `2 * A[i] + A[j] + A[k] > A[k] + A[j]`, hence `2 * A[i] > 0`, so `A[i] > 0` and by symmetry `A[j] > 0`, `A[k] > 0`.

This means that we can safely remove negative numbers and zeroes from the sequence, which is done in `O(log n)` after sorting.

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Nice job. [15chars] –  st0le Mar 22 '11 at 12:56
@st0le: thanks! –  Vlad Mar 22 '11 at 13:09
Thanks for sharing the idea Vlad. This really helps to break down the problem into an easier task. Thanks ! –  all_by_grace Mar 22 '11 at 15:19
@useless: Nope. Obviously if a triple exists in the sorted array, it must exist in the original array (just map the indices back and sort them). You can see that the problem is symmetric w.r.t. index swapping. –  Vlad Apr 17 '13 at 10:11
"it's enough to check that A[i] + A[j] > A[k] for i < j < k, because A[i] + A[k] > A[k]" If A[i] is negative, A[i] + A[k] < A[k] ... –  Chan Le Feb 26 at 15:14

In Java:

``````public int triangle2(int[] A) {

if (null == A)
return 0;
if (A.length < 3)
return 0;

Arrays.sort(A);

for (int i = 0; i < A.length - 2 && A[i] > 0; i++) {
if (A[i] + A[i + 1] > A[i + 2])
return 1;
}

return 0;

}
``````
-

Do a quick sort first, this will generally take nlogn. And you can omit the third loop by binary search, which can take log(n). So altogether, the complexity is reduced to n^2log(n).

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Yeah, I have tried this previously. And still got a timeout error :-) It expects a better solution than n^2 log(n). –  all_by_grace Mar 22 '11 at 12:38

``````def check_triangle (_array)
for p in 0 .. _array.length-1
for q in p .. _array.length-1
for r in q .. _array.length-1
return true if _array[p] + _array[q] > _array[r] && _array[p] + _array[r] > _array[q] && _array[r] + _array[q] > _array[p]
end
end
end

return false
end
``````

Just port it in the language of your choice

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In the question time complexity is not mentioned but in a real quiestion on Codility there is a requirement that a solution must be O(NlogN) so your solution is not suitable. –  skwllsp Nov 13 '13 at 17:20

Here is an implementation of the algorithm proposed by Vlad. The question now requires to avoid overflows, therefore the casts to `long long`.

``````#include <algorithm>
#include <vector>

int solution(vector<int>& A) {

if (A.size() < 3u) return 0;

sort(A.begin(), A.end());

for (size_t i = 2; i < A.size(); i++) {
const long long sum = (long long) A[i - 2] + (long long) A[i - 1];
if (sum > A[i]) return 1;
}

return 0;

}
``````
-

``````function solution(\$A) {
\$cnt = count(\$A);
sort(\$A, SORT_NUMERIC);
return max(\$A[0]*\$A[1]*\$A[\$cnt-1], \$A[\$cnt-1]*\$A[\$cnt-2]*\$A[\$cnt-3]);
}
``````
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and the triangle one: rationalplanet.com/php-related/… –  Alexander Missa Feb 20 at 12:10

Python:

``````def solution(A):
A.sort()
for i in range(0,len(A)-2):
if A[i]+A[i+1]>A[i+2]:
return 1
return 0
``````

Sorting: Loglinear complexity O(N log N)

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