# How many 1s in an n-bit integer?

An interesting problem I ran into today: what is the fastest way to count the number of 1s in an n-bit integer? Is it possible to beat O(n)?

For example:

``````42 = 0b101010 => 3 ones
512 = 0b1000000000 => 1 one
``````

Clearly, the naive algorithm is to simply count. But, are there any tricks to speed it up?

(This is merely an academic question; there is no expected performance gain by implementing such a strategy.)

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It's not worth a full answer, but this problem is called "population count". –  David Wolever Oct 23 '09 at 4:25

See the fabulous Bit Twiddling Hacks article.

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+1 excellent reference for this sort of thing. –  Stephen Canon Oct 23 '09 at 4:19
Great article - thanks very much. –  carl Oct 23 '09 at 4:24
You're welcome. We should thank Delicious and its bookmark tagging capability for allowing me to pull out the link in a jiffy! –  Ates Goral Oct 23 '09 at 4:46

Probably the fastest way on x86 processors would be to use the POPCNT class of instructions.

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If they have POPCNT, that is; only the most recent Intel processors do. –  Stephen Canon Oct 23 '09 at 4:18

The fastest way (without using special processor features or storing pre-calculated answers) is to AND your value with value - 1 in a loop until it's 0. The number of iterations is the number of 1's.

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You mean 2^n, don't you? –  Basilevs Oct 23 '09 at 4:40
I'm not sure I follow. Where do you think I mean 2^n? –  On Freund Oct 23 '09 at 4:45
This is only "the fastest way" when you know that the number of 1 is low. If the number of 1's is high, this method becomes extremely slow. The best way of solving this problem by actually counting the 1's is the well-known shift-and-add method that does the job in `log n` operations guaranteed. (Of course, in practice a byte-wise table-based method might prove the best, which is probably what you call "pre-calculating") –  AndreyT Oct 23 '09 at 5:31
Actually, this algorithm's worst case running time is log n, just like the constant running time of the naive approach. As I mentioned in my answer, the number of iterations equals the number of 1's, and since there cannot be more than log n 1's, and each iteration takes constant time, the running time cannot be more than log n. –  On Freund Oct 23 '09 at 5:46
@On Freund: You missed the fact that in this thread `n` stands for the number of bits in the number (see the OP), not for the number itself. Your algorithm takes O(n) time, while shift-and-add approach takes O(log n). –  AndreyT Oct 23 '09 at 6:41

If you have a finite number of bits (eg 32 bits) you can precalcualte it and then just look up the value in an array.

A slightly more practical way is to do this for each byte or word (only takes 256/64k bytes) and then add the results for each byte/word in the value

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Except it would be hard with 32 bits… Assuming you used 1 bit per value… Would require 512 megs of storage :( Byte/word precalculation would be better. –  David Wolever Oct 23 '09 at 4:27
David, you can't have 1 bit per value if you need to store a bitcount from 0 through 32 inclusive so it's worse than that. –  paxdiablo Oct 23 '09 at 4:32
Works pretty well 8 or 16 bits at a time though. –  hobbs Oct 23 '09 at 5:45