I know how to find out how many bits are on in a given number (or how many elements are true in a boolean arra), using a mask and bitwise operators, going over all bits checking if they are on. Assuming the number is of arbitrary length, the algorithm runs in O(n) time, where n is the number of bits in the number. Is there an asymptotically better algorithm? I don't think that's possible, but how can I formally prove it?
I think the type of formality you're looking for is an "adversarial proof". Suppose one has an algorithm A that runs faster than O(n). Then for sufficiently large n, A must not look at some bit i. We then claim that A must be incorrect. An "adversary" will give A two strings s1 and s2 that are identical except for opposite values of bit i. The algorithm A will return the same value for s1 and s2, so the adversary has "tricked" A into giving the wrong answer. So no correct algorithm A running in o(n) time exists. 


Bit Twiddling Hacks presents a number of methods, including this one:
Examples of the algorithm in action: 128 == 10000000_{2}, 1 bit set
177 == 10110001_{2}, 4 bits set
255 == 11111111_{2}, 8 bits set
As for the language agnostic question of algorithmic complexity, it is not possible to do better than O(n) where n is the number of bits. Any algorithm must examine all of the bits in a number. What's tricky about this is when you aren't careful about the definition of n and let n be "the number of bit shifting/masking instructions" or some such. If n is the number of bits then even a simple bit mask ( So, can this be done in better than O(n) bit tests? No. 


Brian Kerninghan's algorithm to count 1bits.
Read this and other bittwiddling hacks here: Bittwiddling hacks. 


I always use this:
You have to know the size of your integers. http://graphics.stanford.edu/~seander/bithacks.html#CountBitsSetParallel 


Well, you can also use a lookup table holding the #bits for each byte and then divide the number into bytes, adding up the lookup values. It will be still O(number of bits) but with a small factor. 


The fastest way to do this calculation is with a table array edx[bl] where the bl register contains a byte value. If the number is a single byte then the answer is one instruction:
If the number has many bytes in it (say an array pointed to by ebp), then you loop through the bytes (where ecx is the number of bytes in the array containing the number):
This is the absolute fastest way to do this and will be faster than any mathematical computation. Note that the shift instructions in Art's solution are very CPU expensive. The problem with Kernighan's solution is that even when handcoded in assembly it is slower than my algorithm. If it is compiled C it will probably generate a lot of memory accesses that will slow it down even beyond the larger number of clock cycles it requires. Note that if the bytetocount mapping is inlined right next to this instruction then the whole data table will be in the CPU cache so it will be really fast. In this case, no C program will even come close (think 20x slower or more). 


Okay, there seems to be some confusion here about order statistics, asymptotic notation, "big O". It is correct that Brian Kernighan's algorithm is better in terms of number of operations. It is, however, not correct that it is asymptotically better. This can be seen from the definition of bigO. Recall that by definition a function is O(f(n)) when there exists a function g(n) such that f(n) ≤ k g(n) when n grows sufficiently large. Now, let's define w to be the number of bits set in the word, and further note that the run time for a single word, as has been observed above, is a function of the number of bits set. Call that function c(w). We know that there's a fixed word width, call it ww; clearly for any word, 0 ≤ c(w) ≤ ww, and of course, worst case is that c(w) = c(ww). So, the run time of this algorithm is, at worst, n c(ww). Thus, for n, the run time is ≤ n c(ww); that is, n ≤ n c(ww), and thus by definition, this algorithm has an asymptotic worstcase run time of O(n). 


O(n)
is minimum on sequential machine. However, ifn
is smaller than word size you can do thing in parallel. Using C instructions inO(lg n)
. Many processors can do this inO(1)
time. – zch Dec 11 '12 at 15:56O(n)
. It means that for some input it will run is less thann
time. So it can't access all data (what it exactly means depends on computation model). We flip one bit, which was not accessed. Algorithm will give the same result, but this time it isn't correct (it's off by one). Contradiction. – zch Dec 11 '12 at 16:29