How for given unsigned integer x
find the smallest n, that 2 ^ n
≥ x
in O(1)? in other words I want to find the index of higher set bit in binary format of x
(plus 1 if x
is not power of 2) in O(1) (not depended on size of integer and size of byte).

If you have no memory constraints, then you can use a lookup table (one entry for each possible value of If you want a practical solution, most processors will have some kind of "find highest bit set" opcode. On x86, for instance, it's 


In



You can use precalculated tables. If your number is in [0,255] interval, simple table look up will work. If it's bigger, then you may split it by bytes and check them from high to low. 


Perhaps this link will help. Warning : the code is not exactly straightforward and seems rather unmaintainable.



As has been mentioned, the length of the binary representation of x + 1 is the n you're looking for (unless x is in itself a power of two, meaning 10.....0 in a binary representation). I seriously doubt there exists a true solution in O(1), unless you consider translations to binary representation to be O(1). 


Some math to transform the expression:
This is obviously O(1). 


For a 32 bit int, the following pseudocode will be O(1).
It doesn't matter how big x is, it always checks all 32 bits. Thus constant time. If the input can be any integer size, say the input is n digits long. Then any solution reading the input, will read n digits and must be at least O(n). Unless someone comes up solution without reading the input, it is impossible to find a O(1) solution. 


After some search in internet I found this 2 versions for 32 bit unsigned integer number. I have tested them and they work. It is clear for me why second one works, but still now I'm thinking about first one... 1.
2.
edit: First one in clear as well. 


It's a question about finding the highest bit set (as lshtar and Oli Charlesworth pointed out). Bit Twiddling Hacks gives a solution which takes about 7 operations for 32 Bit Integers and about 9 operations for 64 Bit Integers. 


Ok, since so far nobody has posted a compiletime solution, here's mine. The precondition is that your input value is a compiletime constant. If you have that, it's all done at compiletime.
'twas fun to do that. 


An interesting question. What do you mean by not depending on the size of int or the number of bits in a byte? To encounter a different number of bits in a byte, you'll have to use a different machine, with a different set of machine instructions, which may or may not affect the answer. Anyway, based sort of vaguely on the first solution proposed by Mihran, I get:
This works within the constraint that the input value must be exactly
representable in a The only other constant time (with respect to the number of bits) I can think of is:
, which has the same constraint with regards to FWIW, I find the O(1) on the number of bits a bit illogical, for the reasons I specified above: the number of bits is just one of the many "constant factors" which depend on the machine on which you run. Anyway, I came up with the following purely integer solution, which is O(lg 1) for the number of bits, and O(1) for everything else:
A good compiler should be able to inline the recursive calls, resulting in close to optimal code. 

