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I was asked the above question in an interview and interviewer is very certain of the answer. But i am not sure. Can anyone help me here?
This question already has an answer here: I was asked the above question in an interview and interviewer is very certain of the answer. But i am not sure. Can anyone help me here? 

marked as duplicate by UmNyobe, borrible, S.L. Barth, dav_i, Mad Scientist Mar 3 '14 at 9:47This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question. 


Sure. The obvious brute force method is just a big lookup table with one entry for every possible value of the input number. That's not very practical if the number is very big, but is still enough to prove it's possible. Edit: the notion has been raised that this is complete nonsense, and the same could be said of essentially any algorithm. To a limited degree, that's a fair statement  but the limitations are so severe that for most algorithms it remains utterly meaningless. My original point (at least as well as I remember it) was that population counting is about equivalent to many other operations like addition and subtraction that we normally assume are O(1). At the hardware level, circuitry for a singlecycle This is a decided contrast to many other algorithms. For one obvious example, let's consider sorting. For even the most trivial sort most people can imagine  2 items, 8 bits apiece, we're already at a 64 kilobyte lookup table to get constant complexity. Long before we can do even a fairly trivial sort (e.g., 100 items) we need a lookup table that contains far more data items than there are atoms in the universe. Looking at it from the opposite direction, it's certainly true that at some point, essentially nothing is O(1) any more. Let's consider the most trivial operations possible. For an Nbit CPU, bitwise Nonetheless, if I specify a bitwise On reasonable hardware, doing a bitwise Nonetheless, unless you have very specific instructions to say you're going to be dealing with utterly immense operands, you're typically going to treat every one of these as a constant complexity operation. Looked at in these terms, a POPCNT instruction falls about halfway between bitwise _{1. You might wonder how it could possibly be simpler than an add when it actually includes an add after doing some other operations. If so, kudos  it's an excellent question.} _{The answer is that it's because it only needs a much smaller adder. For example, a 64bit CPU needs one halfadder and 63 fulladders. In the simple implementation, you carry out the addition bitwise  i.e., you add bit0 of one operand to bit0 of the other. That generates an output bit, and a carry bit. That carry bit becomes an input to the addition for the next pair of bits. There are some tricks to parallelize that to some degree, but the nature of the beast (so to speak) is bitserial.} _{With a POPCNT instruction, we have an addition after doing the individual table lookups, but our result is limited to the size of the input words. Given the same size of inputs (64 bits) our final result can't be any larger than 64. That means we only need a 6bit adder instead of a 64bit adder.} _{Since, as outlined above, addition is basically bitserial, this means that the addition at the end of the POPCNT instruction is fundamentally a lot faster than a normal add. To be specific, it's logarithmic on the operand size, whereas simple addition is roughly linear on the operand size.} 


If the bit size is fixed (e.g. natural word size of a 32 or 64bit machine), you can just iterate over the bits and count them directly in O(1) time (though there are certainly faster ways to do it). For arbitrary precision numbers (BigInt, etc.), the answer must be no. 


Some processors can do it in one instruction, obviously for integers of limited size. Look up the POPCNT mnemonic for further details. For integers of unlimited size obviously you need to read the whole input, so the lower bound is O(n). The interviewer probably meant the bit counting trick (the first Google result follows): http://www.gamedev.net/topic/547102bitcountingtricknewtome/ 

