This is a bit simplified, but hopefully will get across the meaning of Big-O:

Big-O is about the question "how many times does my code do something?", answering it in algebra, and then asking "which term matters the most in the long run?"

For your first example - the number of times the `print`

statement is called is `5n`

times. `n`

times in the outer loop times `5`

times in the inner loop. What matters most in the long run? In the long run only `n`

matters, as the value of `5`

never changes! So the overall Big-O complexity is `O(n)`

.

For your second example - the number of times the print statement is called is very large, but constant. The outer loop runs `12345`

times, the inner loop runs one time, then `16`

times, then `7625597484987`

... all the way up to `12345^12345^12345`

. The innermost loop goes up in a similar fashion. What we notice is all of these are constants! The number of times the print statement is called doesn't actually vary *at all*. When an algorithm runs in *constant time*, we represent this as `O(1)`

. Conceptually this is similar to the example above - just as `5n / 5 == n`

, `12345 / 12345 == 1`

.

The two examples you have chosen only involve stripping out the constant factors (which we always do in Big-O, they never change!). Another example would be:

```
def more_terms(n):
for i in range(n):
for j in range(n):
print(n)
print(n)
for k in range(n):
print(n)
print(n)
print(n)
```

For this example, the print statement is called `2n^2 + 3n`

times. For the first set of loops, `n`

times for the outer loop, `n`

times for the inner loop and then `2`

times inside the inner lop. For the second set, `n`

times for the loop and `3`

times each iteration. First we strip out the constants, leaving `n^2 + n`

, now what matters in the long run? When `n`

is `1`

, neither really matter. But the bigger `n`

gets, the bigger the difference is, `n^2`

grows much faster than `n`

- so this function has complexity `O(n^2)`

.