# Asymptotic Complexity for an Algorithm

``````i <-- 0
while(i < n)
someWork(...)
i <-- i^2
done
``````

Can someone confirm that the worst case time complexity (Big-O) of this loop is `O(log n)` if:

1. `someWork(...)` is an `O(1)` algorithm

2. `someWork(...)` is an `O(n)` algorithm

Also, what is the worst case time complexity (Big-O) if `someWork(...)` does exactly `i` operations? `someWork(...)` does more work as `i` increases. Your answer should be something like sigma(f(i)).

Thank you very much for any help.

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Actually, this is an infinite loop, as `i` will always remain `0`. – Don Roby Jul 4 '14 at 22:12
If you correct as suggested by Don Robby, i.e. add something to take care of when n < 2 and initialize i = 2 (or any number > 2 but less than n). 1. Some work is O(1) then is is O(log n) 2. Some work is O(n) then it is O(n log n) If some work in O(i) then O((log n) pow x) where x is either 1 or 2. – Vishal Kumar Jul 4 '14 at 22:45
Thanks for the responses so far, both of you. So would I be correct to reason that there is no Big-O because the program never terminates for all three situations? – user3806623 Jul 4 '14 at 23:03

First: if (as mentioned) `0 <= i <= 1` holds, the algorithm will never terminate.

So: Let `i > 1`.

In every round of the loop the exponent of `i` will be doubled. So in the `k`-th round the number will be `i^(2^k)`. The loop keeps going as long as `i^(2^k) < n` holds, which is equivalent to `k < log log n`. Exactly it is `log_2 log_i n`, but due to all logarthms are equal exept for a constant factor, I just write `log log n`. Notice: if `i` is not constant, `1/log log i` has to be multiplied to the complexity.

So the complexity of the algorithm is

1. `O(log log n)`, if `someWork()` is in `O(1)`
2. `O(n log log n)`, if `someWork()` is in `O(n)`

If `someWork()` does `O(i^(2^k))` operations in round `k` you get a total complexity of

``````O( i + i^2 + i^(2^2) + i^(2^3) + ... + i^(2^(log log n)) )
``````

This simplifys to `O(i * i^(2^(log log n)) ) = O(i * n)` or `O(n)` if `i` is constant.

To see the simplification take a look at the following:
The number `i + i^2 + i^4 + i^8` can be written in `i`-ary as `100 010 110`. So you can see that

``````i + i^(2^1) + i^(2^2) + ... + i^(2^k) < i * i^(2^k)
``````

holds, since it is equal to `100 010 110 < 1 000 000 000`.

Edit:
I'm not sure what you mean by sigma notation but maybe it is this:

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