# Big-O complexity of a piece of code

I have a question in algorithm design about complexity. In this question a piece of code is given and I should calculate this code's complexity. The pseudo-code is:

for(i=1;i<=n;i++){
j=i
do{
k=j;
j = j / 2;
}while(k is even);
}


I tried this algorithm for some numbers. and I have gotten different results. for example if n = 6 this algorithm output is like below

i = 1 -> executes 1 time
i = 2 -> executes 2 times
i = 3 -> executes 1 time
i = 4 -> executes 3 times
i = 5 -> executes 1 time
i = 6 -> executes 2 times


It doesn't have a regular theme, how should I calculate this?

• worst case is O(n*log n) – sp2danny May 14 '15 at 9:05
• what is your solution buddy ? @sp2danny – Behzad Hassani May 14 '15 at 9:06
• @sp2danny I disagree : worst case is n... See my answer or @interjay one's! – Samuel Caillerie May 20 '15 at 11:36

The upper bound given by the other answers is actually too high. This algorithm has a O(n) runtime, which is a tighter upper bound than O(n*logn).

Proof: Let's count how many total iterations the inner loop will perform.

The outer loop runs n times. The inner loop runs at least once for each of those.

• For even i, the inner loop runs at least twice. This happens n/2 times.
• For i divisible by 4, the inner loop runs at least three times. This happens n/4 times.
• For i divisible by 8, the inner loop runs at least four times. This happens n/8 times.
• ...

So the total amount of times the inner loop runs is:

n + n/2 + n/4 + n/8 + n/16 + ... <= 2n


The total amount of inner loop iterations is between n and 2n, i.e. it's Θ(n).

• +1 Suprised to not see this as the accepted answer. While it's technically true that it is O(n log n), it's not really asymptotic... Also, here's a Θ if you want to edit it in – Sabre May 14 '15 at 13:33
• "The upper bound given by the other answers is actually too high." is false. A better formulation is "... is actually higher than they need to be." – Taemyr May 15 '15 at 9:38

You always assume you get the worst scenario in each level.
now, you iterate over an array with N elements, so we start with O(N) already.
now let's say your i is always equals to X and X is always even (remember, worst case every time).
how many times you need to divide X by 2 to get 1 ? (which is the only condition for even numbers to stop the division, when they reach 1).
in other words, we need to solve the equation X/2^k = 1 which is X=2^k and k=log<2>(X) this makes our algorithm take O(n log<2>(X)) steps, which can easly be written as O(nlog(n))

• I originally did the same analysis, but I think it is incomplete. While the outer loop is executed n times and the inner loop has worst-case complexity of O(log(n)), it does not follow that the overall complexity is O(n log(n)); it depends on how often the worst-case complexity of the inner loop occurs as i varies from 1 to n. My guess is that this frequency is not O(n) and that the overall complexity is actually lower (perhaps O(log(n)^2)). – Ted Hopp May 14 '15 at 9:21
• But that's an unfair request. The array is specifically [1, 2, ..., n]. I don't think O(n log(n)) necessarily follows. To take an extreme example, suppose the inner loop had worst-case behavior of O(log(i)) for exactly one value of i and O(1) for all other values. Then the fact that the outer loop executes n times would not result in an overall complexity of O(n log(n)); it would be O(n) + O(log(n)) = O(n). The actual inner loop doesn't have this extreme behavior, of course, but it's far from clear (to me) that the density of worst-case behavior warrants the conclusion of O(n log(n)). – Ted Hopp May 14 '15 at 9:28
• By that logic, you could also say that the complexity is O(2^n) and be correct. I don't think that reasoning is in the spirit of the question. – Ted Hopp May 14 '15 at 9:35
• @RobOcel: No, it's not a matter of worst vs. average. The worst-case is still O(n) (which technically means it's also O(n log n)). If n is odd it is still O(n) - you are enumerating all values from 1 to n, not just n itself. – BlueRaja - Danny Pflughoeft May 14 '15 at 14:59
• If you want to lawyer, every algorithm is O(infinity) and Omega(1), but that doesn't actually mean anything. Theta bounds are more interesting in most cases. – Kevin May 14 '15 at 18:45

For such loop, we cannot separate count of inner loop and outer loop -> variables are tighted!

We thus have to count all steps.

In fact, for each iteration of outer loop (on i), we will have

1 + v_2(i) steps


where v_2 is the 2-adic valuation (see for example : http://planetmath.org/padicvaluation) which corresponds to the power of 2 in the decomposition in prime factor of i.

So if we add steps for all i we get a total number of steps of :

n_steps = \sum_{i=1}^{n} (1 + v_2(i))
= n + v_2(n!)    // since v_2(i) + v_2(j) = v_2(i*j)
= 2n - s_2(n)    // from Legendre formula (see http://en.wikipedia.org/wiki/Legendre%27s_formula with p = 2)


We then see that the number of steps is exactly :

n_steps = 2n - s_2(n)


As s_2(n) is the sum of the digits of n in base 2, it is negligible (at most log_2(n) since digit in base 2 is 0 or 1 and as there is at most log_2(n) digits) compared to n.

So the complexity of your algorithm is equivalent to n:

n_steps = O(n)


which is not the O(nlog(n)) stated in many other solutions but a smaller quantity!

• the example provided loops n times and then in it's worst case where i is even and is the result of 2^x 1 + log_2(i) iterations to become "odd" or more accurately 1 + Omega(n) where Omega(n) returns the number of prime factors .e.g 6 = 2,3, so it's not n +... but n logn. I think you missed the for loop on line 1? – Alexander Holman Jul 27 '18 at 13:45
• @AlexanderHolman I disagree : as stated in this solution, the n_steps = 2*n - s_2(n) is an exact solution and a worst case for one iteration can be extended but this remains a worst estimation that an exact one... The sum for the loop over the i loop is indicated by the line : n_steps = \sum_{i=1}^n ... – Samuel Caillerie Aug 20 '18 at 13:59
• Yep I was wrong! At this time of night I honestly can't work out if you are right... Your magic seems to work! +1 for you :) – Alexander Holman Aug 28 '18 at 22:59

if you keep dividing with 2 (integral) you don't need to stop until you get to 1. basically making the number of steps dependent on bit-width, something you find out using two's logarithm. so the inner part is log n. the outer part is obviously n, so N log N total.
A do loop halves j until k becomes odd. k is initially a copy of j which is a copy of i, so do runs 1 + power of 2 which divides i:
• i=1 is odd, so it makes 1 pass through do loop,
That makes at most 1+log(i) do executions (logarithm with base 2).
The for loop iterates i from 1 through n, so the upper bound is n times (1+log n), which is O(n log n).