# Big O notation for triangular numbers?

What's the correct big O notation for an algorithm that runs in triangular time? Here's an example:

``````func(x):
for i in 0..x
for j in 0..i
do_something(i, j)
``````

My first instinct is `O(n²)`, but I'm not entirely sure.

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You are right... O((n+1) choose 2) = O(n^2) by definition. – Protostome Jul 5 '10 at 12:11

Yes, N*(N+1)/2, when you drop the constants and lower-order terms, leaves you with N-squared.

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Yeah, `O(n^2)` is definitly correct. If I recall correctly, O is anyway always an upper bound, so `O(n^3)` should IMO also be correct, as would `O(n^n)` or whatever. However `O(n^2)` seems to be the most tight one that is easily deductable.

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If you think about it mathematically, the area of the triangle you are computing is `((n+1)^2)/2`. This is therefore the computational time: O(((n+1)^2)/2)

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The computation time increases by the factor of N*(N + 1)/2 for this code. This is essentially O(N^2).

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when the input increases from N to 2N then running time of your algorithm will increase from t to 4t

thus running time is proportional to the square of the input size

so algorithm is O( n^2 )

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O(!n) handles cases for a factorial computation (triangular time).

It can also be represented as O(n^2) to me this seems to be a bit misleading as the amount being executed is always going to be half as much as O(n^2) would perform.

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By definition, `O(0.5 * n^2) == O(n^2)` (an equality that holds for any non-zero constant factor, in fact), so from a strictly theoretical perspective this is not misleading. :-) – Gijs Nov 4 '12 at 23:46
-1. A Factorial is not the same as a triangular number. – gilly3 Feb 6 '13 at 19:33