# Total number of possible triangles from n numbers

If `n` numbers are given, how would I find the total number of possible triangles? Is there any method that does this in less than `O(n^3)` time?

I am considering `a+b>c`, `b+c>a` and `a+c>b` conditions for being a triangle.

• Hint: sort the numbers, and for each couple `(a,b) (b≥a)` find all `c`s that satisfy `b≤c≤a+b`. – Benoit Nov 13 '11 at 8:44
• but in worst case, even in avg case we will get O(n^3) complexity ? Or may be i am mis-understood. Can u elaborate ? – peeyush Nov 13 '11 at 8:54

## 8 Answers

Assume there is no equal numbers in given n and it's allowed to use one number more than once. For example, we given a numbers {1,2,3}, so we can create 7 triangles:

1. 1 1 1
2. 1 2 2
3. 1 3 3
4. 2 2 2
5. 2 2 3
6. 2 3 3
7. 3 3 3

If any of those assumptions isn't true, it's easy to modify algorithm.

Here I present algorithm which takes O(n^2) time in worst case:

1. Sort numbers (ascending order). We will take triples ai <= aj <= ak, such that i <= j <= k.
2. For each i, j you need to find largest k that satisfy ak <= ai + aj. Then all triples (ai,aj,al) j <= l <= k is triangle (because ak >= aj >= ai we can only violate ak < a i+ aj).

Consider two pairs (i, j1) and (i, j2) j1 <= j2. It's easy to see that k2 (found on step 2 for (i, j2)) >= k1 (found one step 2 for (i, j1)). It means that if you iterate for j, and you only need to check numbers starting from previous k. So it gives you O(n) time complexity for each particular i, which implies O(n^2) for whole algorithm.

C++ source code:

``````int Solve(int* a, int n)
{
int answer = 0;
std::sort(a, a + n);

for (int i = 0; i < n; ++i)
{
int k = i;

for (int j = i; j < n; ++j)
{
while (n > k && a[i] + a[j] > a[k])
++k;

answer += k - j;
}
}

return answer;
}
``````

Update for downvoters:

This definitely is O(n^2)! Please read carefully "An Introduction of Algorithms" by Thomas H. Cormen chapter about Amortized Analysis (17.2 in second edition). Finding complexity by counting nested loops is completely wrong sometimes. Here I try to explain it as simple as I could. Let's fix i variable. Then for that i we must iterate j from i to n (it means O(n) operation) and internal while loop iterate k from i to n (it also means O(n) operation). Note: I don't start while loop from the beginning for each j. We also need to do it for each i from 0 to n. So it gives us n * (O(n) + O(n)) = O(n^2).

• so your while loop runs for free ? have you counted complexity of while loop, since only 2 for will give O(n^2) – peeyush Nov 22 '11 at 7:58
• Guys, please read my update and look more careful. It is O(n^2). – Wisdom's Wind Nov 22 '11 at 12:59
• What you have done is just dishonest and not very smart. – Wisdom's Wind Nov 23 '11 at 13:41
• can't we use binary search to find the value of 'k'? this would reduce time complexity to nlogn? – Shivendra Jul 4 '13 at 18:22
• @Wisdom'sWind Your solution is a piece of art. Down voters try understanding the way k is being moved. It's not reinitialized in the while loop every time, that's how the algorithm achieved O(n^2) complexity – Soumen Feb 19 '14 at 8:05

If you use a binary sort, that's O(n-log(n)), right? Keep your binary tree handy, and for each pair (a,b) where a b and c < (a+b).

• so can I expect O(n^2 logn) complexity here, right ? – peeyush Nov 19 '11 at 6:51
• this will always evaluate to false, see my answer – artistoex Nov 19 '11 at 15:27
• @artistoex - if you are referring to your paragraph about inequalities and symmetry, that has some serious flaws. Is it some sort of joke? – David Winant Nov 20 '11 at 1:04
• @david actually no, not a joke :-) yes, that was a bit rash. – artistoex Nov 20 '11 at 8:51
• @david: Sorry, but this is not an answer and `O(n-log(n))` stuff is incorrect. – Cartesius00 Nov 22 '11 at 8:43

There is a simple algorithm in `O(n^2*logn)`.

• Assume you want all triangles as triples `(a, b, c)` where `a <= b <= c`.
• There are 3 triangle inequalities but only `a + b > c` suffices (others then hold trivially).

And now:

• Sort the sequence in `O(n * logn)`, e.g. by merge-sort.
• For each pair `(a, b), a <= b` the remaining value `c` needs to be at least `b` and less than `a + b`.
• So you need to count the number of items in the interval `[b, a+b)`.

This can be simply done by binary-searching a+b (`O(logn)`) and counting the number of items in `[b,a+b)` for every possibility which is b-a.

All together `O(n * logn + n^2 * logn)` which is `O(n^2 * logn)`. Hope this helps.

• david already gave same approach before this. – peeyush Nov 22 '11 at 9:40
• Yes, but complexity is right here. BTW, @cartesius00, you know the index of b, no need to binary-search it. – Snicolas Dec 13 '13 at 12:24

Let a, b and c be three sides. The below condition must hold for a triangle (Sum of two sides is greater than the third side)

``````i) a + b > c
ii) b + c > a
iii) a + c > b
``````

Following are steps to count triangle.

1. Sort the array in non-decreasing order.

2. Initialize two pointers ‘i’ and ‘j’ to first and second elements respectively, and initialize count of triangles as 0.

3. Fix ‘i’ and ‘j’ and find the rightmost index ‘k’ (or largest ‘arr[k]‘) such that ‘arr[i] + arr[j] > arr[k]‘. The number of triangles that can be formed with ‘arr[i]‘ and ‘arr[j]‘ as two sides is ‘k – j’. Add ‘k – j’ to count of triangles.

Let us consider ‘arr[i]‘ as ‘a’, ‘arr[j]‘ as b and all elements between ‘arr[j+1]‘ and ‘arr[k]‘ as ‘c’. The above mentioned conditions (ii) and (iii) are satisfied because ‘arr[i] < arr[j] < arr[k]'. And we check for condition (i) when we pick 'k'

4.Increment ‘j’ to fix the second element again.

Note that in step 3, we can use the previous value of ‘k’. The reason is simple, if we know that the value of ‘arr[i] + arr[j-1]‘ is greater than ‘arr[k]‘, then we can say ‘arr[i] + arr[j]‘ will also be greater than ‘arr[k]‘, because the array is sorted in increasing order.

5.If ‘j’ has reached end, then increment ‘i’. Initialize ‘j’ as ‘i + 1′, ‘k’ as ‘i+2′ and repeat the steps 3 and 4.

Time Complexity: O(n^2). The time complexity looks more because of 3 nested loops. If we take a closer look at the algorithm, we observe that k is initialized only once in the outermost loop. The innermost loop executes at most O(n) time for every iteration of outer most loop, because k starts from i+2 and goes upto n for all values of j. Therefore, the time complexity is O(n^2).

I have worked out an algorithm that runs in O(n^2 lgn) time. I think its correct... The code is wtitten in C++...

``````int Search_Closest(A,p,q,n)  /*Returns the index of the element closest to n in array
A[p..q]*/

{
if(p<q)
{
int r = (p+q)/2;
if(n==A[r])
return r;
if(p==r)
return r;
if(n<A[r])
Search_Closest(A,p,r,n);
else
Search_Closest(A,r,q,n);
}
else
return p;
}

int no_of_triangles(A,p,q) /*Returns the no of triangles possible in A[p..q]*/
{
int sum = 0;
Quicksort(A,p,q);  //Sorts the array A[p..q] in O(nlgn) expected case time
for(int i=p;i<=q;i++)
for(int j =i+1;j<=q;j++)
{
int c = A[i]+A[j];
int k = Search_Closest(A,j,q,c);
/* no of triangles formed with A[i] and A[j] as two sides is (k+1)-2 if A[k] is small or equal to c else its (k+1)-3. As index starts from zero we need to add 1 to the value*/
if(A[k]>c)
sum+=k-2;
else
sum+=k-1;
}
return sum;
}
``````

Hope it helps........

• it's same as david answered. – peeyush Nov 20 '11 at 13:39
• I had a similar solution, except I was searching for the closest pair of sides, not the closest single side. The problem with these solutions is that they produce/count same triangles multiple times (e.g. triplets 3<4+5, 4<3+5 and 5<3+4 describe the same triangle but are all counted). Once you try to eliminate duplicate triangles, you instantly hit O(nnn) complexity. – Alexey Frunze Nov 21 '11 at 8:32
• that's why we remove duplicacy prior to checking the condition. Like once we have 3,4,5; we never go back to 4,5,3. Like i=0; i<n;i++ then j=i+1;j<n;j++ – peeyush Nov 22 '11 at 7:52
• @Peeyush: I ran the above code as-is and mine with duplicates suppressed. The above code clearly produced more solutions than there really were. – Alexey Frunze Nov 22 '11 at 13:24

possible answer

Although we can use binary search to find the value of 'k' hence improve time complexity!

• This does not provide an answer to the question. To critique or request clarification from an author, leave a comment below their post. – Shai Jul 4 '13 at 18:53
• @Shai it is the link to counting number of triangles from an array! – Shivendra Jul 5 '13 at 8:50
• @shivi they too have given this SO link as reference ... one more loop now ;) – cbinder Jan 31 '15 at 18:43
``````N0,N1,N2,...Nn-1
sort
X0,X1,X2,...Xn-1 as X0>=X1>=X2>=...>=Xn-1
choice X0(to Xn-3) and choice form rest two item x1...
choice case of (X0,X1,X2)
check(X0<X1+X2)
OK is find and continue
NG is skip choice rest
``````
• what about complexity ? choice function chooses X0 , X1 and X2, due to this, it remains O(n^3), though for some cases because of skipping we can save time, but not always. – peeyush Nov 14 '11 at 6:11
• If all is OK combination(worst case?), all combinations must be examined (unskipable) as you might think,　but (X0, X1, X2) as if the skip when NG, (X0, Xn-2, Xn -1) is OK when check process skip able. so you can something skip any case. – BLUEPIXY Nov 14 '11 at 12:58
• so do you think that skipping few cases will reduce the complexity ? – peeyush Nov 15 '11 at 16:01
• Well, I think the effect is lost and the procedure is too complex. – BLUEPIXY Nov 15 '11 at 21:44

It seems there is no algorithm better than O(n^3). In the worst case, the result set itself has O(n^3) elements.

For Example, if n equal numbers are given, the algorithm has to return n*(n-1)*(n-2) results.

• funny, could have been much funnier, c>d and c>a-b doesn't imply d>a-b :-). – peeyush Nov 19 '11 at 16:21
• @peeyush omg, that's a bit embarrassing :-) – artistoex Nov 19 '11 at 17:07
• @peeyush now, that's a valid result (so I hope) :-) – artistoex Nov 19 '11 at 17:47
• I removed the former part of my answer so as not to cause confusion. – artistoex Nov 20 '11 at 10:02
• @peeyush n^logn is way more than any polynomial – artistoex Nov 21 '11 at 6:48