Because here the loops are simple, it's easy to count all actions done.

The `a[i] *= 2`

is done `N`

times.

The `d[i][j] = a[i] * c[j]`

is done:

- when
`i==0`

: 0 times
- when
`i==1`

: 1 times
- ...
- when
`i==N-1`

: `N`

-1 times.

The total is: `N + 0 + 1 + ... + N-1`

= `N + (N-1)(N-2)/2`

= `(1/2)(N^2) - N/2 + 1`

.

**For **`O()`

we consider only the highest power and ignore constant coefficients, here it is `O(N^2)`

.

Why this? We want to know what happens when `N`

is big.

E.g: `N = 1,000`

=> exact number is `(1/2)(N^2) - N/2 + 1`

= `499,501`

.

`N = 10,000`

=> exact number is `(1/2)(N^2) - N/2 + 1`

= `49,995,001`

.

We see that for `N`

10 times bigger, result is about 100 times bigger. It is `O(N^2)`

.

**We can do shorter, rereading the code:**

There is a loop on `N`

, and inside a loop limited by `i`

and `i`

is varying like N. It is a `O(N^2)`

process.

`i`

is not a free parameter but a loop variable. What should`O(N*i)`

complexity mean?