# Order of growth for loops

What would be the order of growth of the code below. My guess was, each loop's growth is linear but the if statement is confusing me. How do I include that with the whole thing. I would very much appreciate an explanatory answer so I can understand the process involved.

``````int count = 0;
for (int i = 0; i < N; i++)
for (int j = i+1; j < N; j++)
for (int k = j+1; k < N; k++)
if(a[i] + a[j] + a[k] == 0)
count++;
``````
• (The (lack of) comments & indentation of the code lines leaves doubt about what this is supposed to do.) Please be explicit about `[guess] each loop's growth is linear`. What is your question? You have one statement the cost of which can be considered constant, as its control. This is in a triply nested loop: What if all loops ran from 0 to N? What in case of the initial values from above? May 14 '16 at 14:00

There are two things that can be confusing when trying to determine the code's complexity.

1. The fact that not all loops start from 0. The second loop starts from `i + 1` and the third from `j + 1`. Does this affect the complexity? It does not. Let's consider only the first two loops. For `i = 0`, the second runs `N - 1` times, for `i = 1` it runs `N - 2` times, ..., for `i = N - 1` it runs `0` times. Add all these up:

``````0 + 1 + ... + N - 1 = N(N - 1) / 2 = O(N^2).
``````

So not starting from 0 does not affect the complexity (remember that big-oh ignores lower-order terms and constants). Therefore, even under this setting, the entire thing is `O(N^3)`.

2. The `if` statement. The `if` statement is clearly irrelevant here, because it's only part of the last loop and contains no `break` statement or other code that would affect the loops. It only affects the incrementation of a count, not the execution of any of the loops, so we can safely ignore it. Even if the count isn't incremented (an `O(1)` operation), the `if` condition is checked (also an `O(1)` operation), so the same rough number of operations is performed with and without the `if`.

Therefore, even with the `if` statement, the algorithm is still `O(N^3)`.

• Can I ask why you have divided N(N-1) by 2. Apr 16 '15 at 17:56
• @JVTura - because the sum is calculated by grouping the first term with the last, the second with the second to last etc. for `0 + 1 + 2 + 3 + 4` for example, we would group `(0 + 4) + (1 + 3) + (2 + 2) + (3 + 1) + (4 + 0)`. There are `N = 5` groups, each with sum `N - 1 = 4`. But we have to divide by 2 because each group occurs twice, so we oversum if we do not divide: `5*4 / 2 = 10`, which is correct. Apr 16 '15 at 18:01
• What would be the order of growth of this code snippet? `int sum =0; for(int n = N; n > 0; n/= 2;) for(int i = 0; i < n; i++;) sum++;` May 7 '17 at 6:24

Order of growth of the code would be O(N^3).

In general k nested loops of length N contribute growth of O(N^k).

• Does the fact that the nested loops shrink each iteration affect the outcome? I was expecting factorials or other modifier Apr 16 '15 at 17:41
• Not really. While it would affect the constant next to N^k it doesn't really affect the O notation. Apr 16 '15 at 17:42
• Maybe I went wrong then, still new to this: O(n * (n - 1) * (n-2)) = O(n^3 - 3*n^2 + 2n) Apr 16 '15 at 17:47
• You are absolutely right! Note that O(n^3 - 3*n^2 + 2n) = O(n^3) since the largest "factor" always overtakes. Apr 16 '15 at 17:48

Here are two was to find that the time complexity is Theta(N^3) without much calculation.

First, you select `i<j<k` from the range 0 through N-1. The number of ways to choose 3 objects out of N is the binomial coefficient N choose 3 = `N*(N-1)*(N-2)/(3*2*1) ~ (N^3)/6 = O(N^3)`, and more precisely Theta(N^3).

Second, an upper bound is that you choose i, j, and k from N possibilities, so there are at most `N*N*N = N^3` choices. This is O(N^3). You can also find a lower bound of the same type since you can choose i from 0 through N/3-1, j from N/3 through 2N/3-1, and k from 2N/3 through N-1. This gives you at least floor(N/3)^3 choices, which is about N^3/27. Since you have an upper bound and lower bound of the same form, the time complexity is Theta(N^3).