Complexity for `f(x) = 5x^2 + 4xlogx + 2`

is `O(x^2)`

because

```
O(g(x) + k(x)) = max(O(g(x), k(x))
// and O(X^2) > O(xlogx)
//additionally coeffs are disregarded
O(c*g(x)) = O(g(x))
```

So if you have a sum you just select the largest complexity as at the end of the day, when *n* goes to infinity the largest component will give the most computational load. It also doesn't matter if you have any coeffs because you try to *roughly* estimate what's going to happen.

For your other sample see reasoning below

```
for (int i = 0; i < block.length; i++)
for (int j = 0; j < block.length; j++)
for (int k = 0; k < 5; k++)
g(); //assume worst case time performance of g() is O(1)
```

First convert loops into sums and work out the sums from right to left

```
Sum (i=0,n)
Sum(j=0, n)
Sum(k=0, k=5)
1
```

Counter of O(1) from 1 to 5 is still O(1), remember you disregard coeffs

```
Sum(k=0, k=5) 1 = O(5k) = O(1)
```

So you end up with the middle sum, which counts a function of O(1) n times, this gives the complexity of O(n)

```
Sum(j=0, n) 1 = O(n)
```

Finally you get to the leftmost sum and notice that you count *n n*-times, i.e. `n+n+n...`

, which is equal to `n*n`

or `n^2`

```
Sum (i=0,n) n = O(n^2)
```

So the final answer is O(n^2).