one way to get that is for the natural numbers (1,..n) we factorise each and see if they have any repeated prime factors , but that would take a lot of time for large n. So is there any better way to get the squarefree numbers from 1,,n ?

You could use erastophenes sieve's modified version: Take a bool array 1..n; precalc all squares that are less than n; that's O(sqrt(N)); foreach square and its multiples make the bool array entry false... 


The most direct thing that comes to mind is to list the primes up to n and select at most one of each. That's not easy for large n (e.g. here's one algorithm), but I'm not sure this problem is either. 


From http://mathworld.wolfram.com/Squarefree.html



You should probably look into the sieve of Atkin. Of course this eliminates all nonprimes (not just perfect squares) so it might be more work than you need. 


Googling a little bit I've found this page where a J program is explained. A part from the complex syntax, the algorithm allows to check whether a number is squarefree or not:
You could implement the algorithm in your preferred language and iterate it on any number from 1 to n. 


http://www.marmet.org/louis/sqfgap/ Check out the section "Basic algorithm: the sieve of Eratosthenes", which is what Armen suggested. The next section is "Improvements of the algorithm". Also, FWIW, the Moebius function and squarefree numbers are related. 


I have found a better algorithm to calculate how many squarefree numbers in a interval such as [n,m]. We can get prime that less than 

