# How to calculate Big O of this algorithm?

I want to calculate Big O of `x++` in below algorithm.

``````for (int i = 2;i < n;i*=2)
for(int j = i;j < m;j*=j)
x++;
``````

I think a lot about it, but I can't solve it. How can I solve it?

-
Big-O notation in terms of which variable? `m` or `n`? –  Oli Charlesworth Nov 30 '11 at 15:20
In both of them.It depends on both of them. –  MoeinHm Nov 30 '11 at 15:20
The asymptotic behaviour is really only affected by `m`. As soon as `n` exceeds `m` then the runtime won't increase. –  Oli Charlesworth Nov 30 '11 at 15:23
"I think a lot about it" - what have you thought so far? –  AakashM Nov 30 '11 at 15:27

``````O(lg(n) * lg(lg(m)))
``````

at most `lg(n)` for outer loop and `lg(lg(m))` for the other.

EDIT: more help to prove:

lets change the variables :

``````nn = lg(n);
mm = lg(m);
``````

the code will become:

``````for (int i = 1;i < nn;i++)
for(int j = i;j < mm;j *= 2)
x++;
``````

now the runtime will be `O(nn * lg(mm))`.

EDIT(2): the bound can become tighter(because we have `j = i` in the second loop, not `j = 1`)

if `nn >= mm` then `(x++) = theta(mm * lg(mm)) = theta(lg(m) * lg(lg(m)))`

and

if `nn < mm` then `(x++) = theta(nn * lg(mm)) = theta(lg(n) * lg(lg(m)))`

-
Are you sure we can't get a tighter bound by knowing that it uses `j=i` instead of `j=1`? –  missingno Nov 30 '11 at 15:45

`O(log(n) * log log(m))` the inner gets executed log log m times.

-
This implies that it's `O(log(n))` if `m` is fixed. But this is not the case. –  Oli Charlesworth Nov 30 '11 at 15:31

Obviously, the outer loop is O(log2(n)) as i is doubled with each iteration from 2 until n exclusive. So:

2x < n
⇔ log2(2x) < log2(n)
x < log2(n)

So it requires at most log2(n) iterations of the outer loop until `i < n` is no longer fulfilled, thus O(log(n)).

The inner is a little tricky as the current value of i of the outer loop is used to initialize j of the inner loop. Additionally, j is multiplied with itself (i. e. j2) with every iteration. So:

j2x < m
⇔ logj(j2x) < logj(m)
⇔ 2x < logj(m)
⇔ log2(2x) < log2(logj(m))
x < log2(logj(m))

So it requires at most log2(logj(m)) iterations of the inner loop until the condition `j < m` is no longer fulfilled, thus O(log(log(m))). And if we ignore the bases, we can estimate the total complexity at O(log(n)·log(log(m))).

-