```
T(n) = n log n + (n-1) log (n-1) + ... + 1 log 1 + T(0)
< n log n + (n-1) log n + ... 1 log n + T(0)
= ( n + n-1 + n-2 + ... + 1) log n + T(0)
= n(n+1)/2 * log n + T(0)
```

So it is in `O(n^2 log n)`

, if `T(0)`

is also in `O(n^2 log n)`

.

Other way:

```
T(n) = n log n + (n-1) log (n-1) + ... + 1 log 1 + T(0)
< n log n + n log (n-1) + ... + n log 1 + T(0)
= n (log n + log (n-1) + ... + log 1) + T(0)
= n log (n!) + T(0)
< n log (n^n) + T(0)
= n * n * log n + T(0)
= n^2 log n
```

**Edit:**

You can also see a lower bound by the same way:

```
T(n) = n log n + (n-1) log (n-1) + ... + 1 log 1 + T(0)
> n log n/2 + (n-1) log n/2 + ... + n/2 log n/2 + (n/2-1) log 1 + ... 1 log 1 + T(0)
= ( n(n+1)/2-n/4(n/2+1) ) log n/2 + T(0)
= (3/8 n^2 + 1/4 n) log n/2 + T(0)
= (3/8 n^2 + 1/4 n) log n - (3/8 n^2 + 1/4 n) log 2
= 3/8 n^2 log n + 1/4 n log n - (3/8 n^2 + 1/4 n) log 2
```

So T(n) is in Ω`(n^2 log n)`

.

Together you get Θ`(n^2 log n)`

(as long as `T(0)`

is in `O(n^2 log n)`

)