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 


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. 


In



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


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. 


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). 


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. 


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. 

