Assuming that the second `while`

loop should read `while j<=n`

, the time complexity is:

*O(n)*

And the determining factor is exactly that loop on *k*.

We have:

```
i=1
while i<=n
j=1
while j<=n
if i==j
k=1
while k<=j
k+=1
print("hello")
else
print("world")
j*=2
i*=2
```

The case `i==j`

happens exactly once per iteration of the outer loop (where *i* changes), and could be made independent of the value of *j*, and taken out of the loop on *j*:

```
i=1
while i<=n
j=1
while j<=n
if i!=j
print("world")
j*=2
k=1
while k<=i
k+=1
print("hello")
i*=2
```

This changes the order of the `print`

outputs, but that is irrelevant for determining the time complexity. We can even split that further:

```
i=1
while i<=n
j=1
while j<=n
if i!=j
print("world")
j*=2
i*=2
i=1
while i<=n
k=1
while k<=i
print("hello")
k+=1
i*=2
```

So now for one iteration of the first outer loop, its inner while-loop iterates *logn* times. Each iteration of that inner loop takes constant time. In one case (when *i* equals *j*), there is a constant amount of time less work, so we have a time complexity of *O(logn)-O(1)* = *O(logn)* for this `while`

loop.

That gives the first outer loop a time complexity of:

*O(logn) * O(logn) = O((logn)²)*

For one iteration of the second outer loop, its inner while-loop iterates *i* times, so we get a total number of iterations (when n is a power of 2) of *1 + 2 + 4 + 8 + ... + n*, which is a binary expansion -- equal to *2(2*^{logn})-1 = 2n-1, giving a time complexity of:

*O(2n-1) = O(n)*

For the overall time complexity, we take the sum, i.e.

*O((logn)²) + O(n) = O(n)*.

### Illustration

To illustrate this time complexity, have a look at this implementation, where *n* is increased in each execution, and the units of work are counted and returned. The ratio between *n* and the amount of work approaches a constant:

```
function work(n) {
var units = 0;
var i=1
while (i<=n) {
var j=1
while (j<=n) {
if (i==j) {
var k=1
while (k<=j) {
k+=1
//print("hello")
units++;
}
} else {
//print("world")
units++;
}
j*=2
}
i*=2
}
return units;
}
// Demo
setTimeout(function loop(n=1) {
var units = work(n);
console.log(`n=${n}, work=${units}, ratio=${units/n}`);
if (n < 100000000) setTimeout(loop.bind(null, n*2));
});
```

This is only an illustration, and does not count as proof.

nis greater than 0. Maybe it was intended to have`j<=n`

as end-condition of the inner`while`

? – trincot Apr 11 '19 at 11:15