Say I'm given n=32. I want to know what log_2(n) is. In this case, log_2(32) = 5.
What is the fastest way in general to compute the log of a 2^k number?
I.e. Given n = 2^k. log_2(n) = b. Find b.
Bitwise operations are permitted.
Say I'm given n=32. I want to know what log_2(n) is. In this case, log_2(32) = 5. What is the fastest way in general to compute the log of a 2^k number? I.e. Given n = 2^k. log_2(n) = b. Find b. Bitwise operations are permitted. 


This page gives a halfdozen different ways to do that in C; it should be trivial to change them to C#. Try them all, see which is fastest for you. http://graphics.stanford.edu/~seander/bithacks.html#IntegerLogObvious However, I note that those techniques are designed to work for all 32 bit integers. If you can guarantee that the input is always a power of two between 1 and 2^31 then you can probably do better with a lookup table. I submit the following; I have not performance tested it, but I see no reason why it oughtn't to be pretty quick:
The solution relies upon the fact that the first 32 powers of two each have a different remainder when divided by 37. If you need it to work on longs then use 67 as the modulus; I leave you to work out the correct values for the array. Commenter LukeH correctly points out that it is bizarre to have a function that purportedly takes the log of a negative number ( CHALLENGE: Hypothesis: The first n powers of two each have a different modulus when divided by p, where p is the smallest prime number that is larger than n. If the hypothesis is true then prove it. If the hypothesis is false then provide a counterexample that demonstrates its falsity. 


I think that if you guarantee that
EDIT:


