Is there any efficient way to find the number of divisors of a number (say n) which are not smaller than another number (say m). n can be up to 10^12. i thought about sieve algorithm & then find the number of divisors. my method check all the numbers from m to square root of n. But i think there is another way(efficient) to do that .
Following is an example program that computes the number of divisors of n that are larger than m. The largeDivs() code runs in time O(c) if there are c divisors. largeDivs() also starts with a representation of n as a factored number, with nset being a list of pairs of form (p_i, k_i) such that n = Product{p_i**k_i for i in 1..h}. Some example output is shown after the program. The check() routine is used to demonstrate that largeDivs() produces correct results. check() takes a long time for smaller values of m.
Example output:



It's easy to find the divisors of a number if you know the prime factors; just take all possible combinations of the multiplicities of all the factors. For n as small as 10^12, trial division should be a sufficiently fast factorization method, as you only have to check potential factors up to 10^6. Edit: add discussion about "all possible combinations" and factoring by trial division. Consider the number 24505 = 5 * 13 * 13 * 29. To enumerate its divisors, take all possible combinations of the multiplicities of all the factors:
It's also not hard to factor a number by trial division. Here's the algorithm, which you can translate to your favorite language; it's plenty fast enough for numbers up to 10^12:
Let's look at the factorization of 24505. Initially f is 2, but 24505 % 2 = 1, so f is incremented to 3. Then f = 3 and f = 4 also fail to divide n, but 24505 % 5 = 0, so 5 is a factor of 24505 and n is reduced to 24505 / 5 = 4901. Now f = 5 is unchanged, but it fails to divide n, likewise 6, 7, 8, 9, 10, 11 and 12, but finally 4901 % 13 = 0, so 13 is a factor of 4901 (and also 24505), and n is reduced to 4901 / 13 = 377. At this point f = 13 is unchanged, and 13 is again a divisor, this time of the reduced n = 377, so another factor of 13 is output and n is reduced to 29. At this point 13 * 13 = 169 is greater than 29, so the I discuss these kinds of algorithms in my essay Programming with Prime Numbers. 


It depends on the application, but if performance is such an issue I'd use a pregenerated hash table. Obviously 10^12 entries might be impractical (or at least undesirable) to store in memory, so I'd do division tests up to the k^{th} prime number, generating hash table entries only for numbers not divisible by those first k prime numbers. For example, though crudely written and untested, this should give you an idea:


