Efficient way to count number of 1s in the binary representation of a number in O(1) if you have enough memory to play with. This is an interview question I found on an online forum, but it had no answer. Can somebody suggest something, I cant think of a way to do it in O(1) time?

That's the Hamming weight problem, a.k.a. population count. The link mentions efficient implementations. Quoting:



I've got a solution that counts the bits in
In worst case (when the number is 2^n  1, all 1's in binary) it will check every bit. Edit: Just found a very nice constanttime, constant memory algorithm for bitcount. Here it is, written in C:
You can find proof of its correctness here. 





I saw the following solution from another website:



Please note the fact that: n&(n1) always eliminates the least significant 1. Hence we can write the code for calculating the number of 1's as follows:
The complexity of the program would be: number of 1's in n (which is constantly < 32). 


That will be the shortest answer in my SO life: lookup table. Apparently, I need to explain a bit: "if you have enough memory to play with" means, we've got all the memory we need (nevermind technical possibility). Now, you don't need to store lookup table for more than a byte or two. While it'll technically be Ω(log(n)) rather than O(1), just reading a number you need is Ω(log(n)), so if that's a problem, then the answer is, impossible—which is even shorter. Which of two answers they expect from you on an interview, no one knows. There's yet another trick: while engineers can take a number and talk about Ω(log(n)), where n is the number, computer scientists will say that actually we're to measure running time as a function of a length of an input, so what engineers call Ω(log(n)) is actually Ω(k), where k is the number of bytes. Still, as I said before, just reading a number is Ω(k), so there's no way we can do better than that. 


Below will work as well.



There's only one way I can think of to accomplish this task in O(1)... that is to 'cheat' and use a physical device (with linear or even parallel programming I think the limit is O(log(k)) where k represents the number of bytes of the number). However you could very easily imagine a physical device that connects each bit an to output line with a 0/1 voltage. Then you could just electronically read of the total voltage on a 'summation' line in O(1). It would be quite easy to make this basic idea more elegant with some basic circuit elements to produce the output in whatever form you want (e.g. a binary encoded output), but the essential idea is the same and the electronic circuit would produce the correct output state in fixed time. I imagine there are also possible quantum computing possibilities, but if we're allowed to do that, I would think a simple electronic circuit is the easier solution. 


I have actually done this using a bit of sleight of hand: a single lookup table with 16 entries will suffice and all you have to do is break the binary rep into nibbles (4bit tuples). The complexity is in fact O(1) and I wrote a C++ template which was specialized on the size of the integer you wanted (in # bits)… makes it a constant expression instead of indetermined. fwiw you can use the fact that (i & i) will return you the LS onebit and simply loop, stripping off the lsbit each time, until the integer is zero — but that’s an old parity trick. 


The function takes an



I came here having a great belief that I know beautiful solution for this problem. Code in C:
But after I've taken a little research on this topic (read other answers:)) I found 5 more efficient algorithms. Love SO! There is even a CPU instruction designed specifically for this task: Description and benchmarking of many algorithms you can find here. 


The following is a C solution using bit operators:
The following is a Java solution using powers of 2:



In python or other convert to bin string then split it with '0' to get ride of 0s then combin and get the len. ;) len(''.join(str(bin(122011)).split('0')))1 


thats it? 


protected by Samuel Liew Sep 11 at 6:20
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