I want to write a function that returns the nearest upper power of 2 number. For example if my input is 789, the output should be 1024. Is there any way of achieving this without using any loops but just using some bitwise operators?

Check the Bit twidding hacks. You need to get the base 2 logarithm, then add 1 to that. 


This works by finding the number you'd have raise 2 by to get x (take the log of the number, and divide by the log of the desired base, see wikipedia for more). Then round that up with ceil to get the nearest whole number power. This is a more general purpose (i.e. slower!) method than the bitwise methods linked elsewhere, but good to know the maths, eh? 





I think this works, too:
And the answer is 


If you're using GCC, you might want to have a look at Optimizing the next_pow2() function by Lockless Inc.. This page describes a way to use builtin function By the way, if you're not going to use assembler instruction and 64bit data type, you can use this



For IEEE floats you'd be able to do something like this.
If you need an integer solution and you're able to use inline assembly, BSR will give you the log2 of an integer on the x86. It counts how many right bits are set, which is exactly equal to the log2 of that number. Other processors have similar instructions (often), such as CLZ and depending on your compiler there might be an intrinsic available to do the work for you. 


If you do not want to venture into the realm of undefined behaviour the input value must be between 1 and 2^63. The macro is also useful to set constant at compile time. 


Many processor architectures support 


in python3.x .... this should work



For completeness here is a floatingpoint implementation in bogstandard C.



One more, although I use cycle, but thi is much faster than math operands power of two "floor" option:
power of two "ceil" option:



If you need it for OpenGL related stuff:


