`O(n!)`

isn't equivalent to `O(n^n)`

. It is asymptotically less than `O(n^n)`

.

`O(log(n!))`

is equal to `O(n log(n))`

. Here is one way to prove that:

Note that by using the log rule `log(mn) = log(m) + log(n)`

we can see that:

```
log(n!) = log(n*(n-1)*...2*1) = log(n) + log(n-1) + ... log(2) + log(1)
```

**Proof that **`O(log(n!)) ⊆ O(n log(n))`

:

```
log(n!) = log(n) + log(n-1) + ... log(2) + log(1)
```

Which is less than:

```
log(n) + log(n) + log(n) + log(n) + ... + log(n) = n*log(n)
```

So `O(log(n!))`

is a subset of `O(n log(n))`

**Proof that **`O(n log(n)) ⊆ O(log(n!))`

:

```
log(n!) = log(n) + log(n-1) + ... log(2) + log(1)
```

Which is greater than (the left half of that expression with all `(n-x)`

replaced by `n/2`

:

```
log(n/2) + log(n/2) + ... + log(n/2) = floor(n/2)*log(floor(n/2)) ∈ O(n log(n))
```

So `O(n log(n))`

is a subset of `O(log(n!))`

.

Since `O(n log(n)) ⊆ O(log(n!)) ⊆ O(n log(n))`

, they are equivalent big-Oh classes.

`n!`

is exactly what it is. Strange notation though... – leppie Nov 14 '11 at 6:55