# Fastest method to define whether a number is a triangular number

A triangular number is the sum of the n natural numbers from 1 to n. What is the fastest method to find whether a given positive integer number is a triangular one?

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What exactly is the aim of "fastest" here? Is something like `int n = sqrt((double) (2*k)); n*(n+1)/2 == k` not fast enough for your purposes? –  Jefromi May 26 '10 at 13:20
Testing this quickly is, one way or another, basically equivalent to testing whether an integer is a square, as others have pointed out. Here's a pretty extensive question devoted to that topic: stackoverflow.com/questions/295579/… –  Jefromi May 26 '10 at 13:26
Is this part of a larger problem you're trying to solve? If so, perhaps you'd like to explain that instead? –  Bart Kiers May 26 '10 at 13:39
@Bart: Yes, I need a fast check whether a network topology is every-to-every or not. –  psihodelia May 26 '10 at 13:54

If `n` is the `m`th triangular number, then `n = m*(m+1)/2`. Solving for `m` using the quadratic formula:

``````m = (sqrt(8n+1) - 1) / 2
``````

So `n` is triangular if and only if `8n+1` is a perfect square. To quickly determine whether a number is a perfect square, see this question: Fastest way to determine if an integer’s square root is an integer.

Note that if 8n+1 is a perfect square, then the numerator in the above formula will always be even, so there's no need to check that it is divisible by 2.

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+1 for link on how to determine if number is perfect square. –  Aryabhatta May 26 '10 at 13:26
You also need to mention that if n is triangular, then 8n+1 is a perfect square: i.e x is triangular if and only if 8x+1 is a perfect square. Having it one way is incomplete. –  Aryabhatta May 26 '10 at 13:33

An integer x is triangular exactly if 8x + 1 is a square.

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If you follow the sparky's answer you will reach the test above. The problem right now is how do you check if a number is a square easily :). See interjay's answer for this. –  Mihai Claudiu Toader May 26 '10 at 13:24
Your answer rocks! Simple and elegant. Incidentally, it can be easily demonstrated in at least two different ways. #1 is to work it out via solving the quadratic equation. #2 is to substitue n(n+1)/2 for x in your equation and factor. –  Sparky May 26 '10 at 13:35

Home work ?

Sum of numbers from 1 to N

1 + 2 + 3 + 4 + ... n-1 + n

if you add the first plus last, and then the second plus the second from last, then ...

= (1+n) + (2+n-1) + (3+n-2) + (4+n-3) + ... (n/2 + n/2+1)

= (n=1) + (n+1) + (n+1) + ... (n+1); .... n/2 times

= n(n+1)/2

This should get you started ...

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I don't know if this is the fastest, but here is some math that should get you in the right direction...

``````S = n (n + 1) / 2
2*S = n^2 + n
n^2 + n - 2*S = 0
``````

You now have a quadratic equation.

Solve for n.

If n does not have an fractional bits, you are good to go.

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