Update: Sorry I forgot to put n^n inside the O()
My attempt was to solve this recurrence relation:
T(n) = nT(n1) +1
T(0) = 1;
Using the iteration method I got the n^n but Im not sure if this is the way to prove it.
Update: Sorry I forgot to put n^n inside the O() My attempt was to solve this recurrence relation:
Using the iteration method I got the n^n but Im not sure if this is the way to prove it. 

I assume that you want to prove that the function Definition: A function So, we have to compare
As you can see, the first line ( So, we can  look at the definition  say, that there exists 


Remark: The following is an answer to the original Question which was: "Prove that n! = n^n" I can prove that it's not true pretty easily: take n = 5.



It is not true that n! = n^n, and therefore you will not be able to prove that. Furthermore, the solution to your recurrence relation is neither n! or n^n. (It satisfies T(1) = 1*1+1 = 2, which is neither 1! nor 1^1.) What exactly are you trying to do, and why? 





for The actual stirling approximation is What is your mathematical background? Do you want a complex analytic proof or something more combinatorial in nature? 


O(n!)
andO(n^n)
are equivalent? That's not the case. – Nikita Rybak Feb 15 '11 at 2:46T(n) = n T(n1)
 i.e., drop the+1
. – Dan Breslau Feb 15 '11 at 2:47O(n!)
andO(n^n)
.n!
isO(n^n)
(almost trivially, by the definition), but not the other way around. Is this what you are trying to show? – BlueRaja  Danny Pflughoeft Feb 15 '11 at 2:49T(n) = nT(n1) +1
would not ben!
.n!
would beT(n) = nT(n1)
– user470379 Feb 15 '11 at 3:33