I had the following question in an interview and I believe I gave a working implementation but I was wondering if there was a better implementation that was quicker, or just a trick I missed.

Given 3 unsigned 30-bit integers, return the number of 30-bit integers that when compared with any of the original numbers have the same position bits set to 1. That is we enumerate all the 0s

Let me give an example, but lets use 4bit for clarity.

Given:

A = 1001
B = 0011
C = 0110

It should return 8 since there are 8 4bit ints that are in the set. The set being:

0011
0110
0111
1001
1011
1101
1110
1111

Now how I worked it out was to take each number and enumerate the set of possibilites and then count all the distinct values. How I enumerated the set was to start with the number, add one to it and then OR it with itself until I reached the mask. With the number itself being in the set and the mask (being all set to 1) also in the set. So for example to enumerate the set of 1001:

1001 = the start
1011 = (1001 + 1) | 1001
1101 = (1011 + 1) | 1001
1111 = (1101 + 1) | 1001 (this is the last value as we have reached our mask)

So do that for each number and then count the uniques.

This is it in python code (but language doesn't really matter as long as you can do bitwise operations, hence why this question is tagged for c/c++ as well):

def count_anded_bitmasks( A, B, C ):
andSets = set(
enumerate_all_subsets(A) +
enumerate_all_subsets(B) +
enumerate_all_subsets(C)
)
return len(andSets)

def enumerate_all_subsets( d ):
andSet = []
n = d
andSet.append(n)
n = (n + 1) | d
andSet.append(n)
return andSet

Now this works and gives the correct answer but I'm wondering if I have missed a trick. Since the question was to only ask the count and not enumerate all the values perhaps there is a much quicker way. Either by combining the numbers first, or getting a count without enumeration. I have a feeling there is. Since numbers that contain lots of zeros the enumeration rises exponentially and it can take quite a while.

If you have A B and C, the count of the set of numbers which has bits set to 1 where A or B or C has corresponding bits set to 1.

Some people don't understand the question (didn't help that I didn't ask it correctly first of). Let's use the given A B and C values above:

A:

1001
1011
1101
1111

B:

0011
0111
1011
1111

C:

0110
0111
1110
1111

Now combine those sets and count the distinct entries. That is the answer. Is there a way to do this without enumerating the values?

edit: Sorry for the mistake the question. Fixed now.

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I'm sorry I confused. Firstly you use & in the example and than | in your code. Secondly why isn't 1000 a solution in your example? Could you please clarify, I'm eager to understand :) –  ther May 1 '12 at 17:11
Am I missing something here? When 0001 is ANDed with either A or B above, it gives a true. Why isn't that considered a possible solution? –  chrisaycock May 1 '12 at 17:11
@JohnDibling Not really. The best solution for this might not be the shortest. –  Pubby May 1 '12 at 17:14
Wouldn't 0101 work? The first 1 matches C, and the second matches A and B. –  David Thornley May 1 '12 at 17:18
The question is a lot more confusing after your update. I now have absolutely no idea what you're asking. –  interjay May 1 '12 at 17:43

N = 4

def supers(number):
zeros = sum(1 for bit in xrange(N) if (number >> bit) & 1 == 0)
return 2**zeros

def solve(a,b,c):
total = supers(a) + supers(b) + supers(c)
total -= supers(a | b) # counted twice, remove one
total -= supers(b | c) # counted twice, remove one
total -= supers(a | c) # counted twice, remove one
total += supers(a | b | c) # counted three times, removed three times, add one

print solve(0b1001,0b0011,0b0110)

## Explanation

Let S(n) be the set produce by the number n.

supers(n) returns |S(n)| the size of the set for the number n. supers is not a great name, but I had trouble coming up with a better one

The trick is to realize that S(a) ^ S(b) = S(a | b). As a result, using supers I can figure out the size of all those sets.

To figure out the rest, draw a venn diagram of the sets.

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A = int('111111111111111111111110011111', 2) B = int('111111111111111111111100111111', 2) C = int('111111111111111111111101101111', 2) print solve([A, B, C]) Should print 8 but prints 1073741816 –  dalore May 1 '12 at 18:29
@dalore, I see the problem being described now is different then the one when I wrote this. –  Winston Ewert May 1 '12 at 19:04
@dalore, should be correct now, If I understand your problem. –  Winston Ewert May 1 '12 at 19:22
Yep this works for the test cases I wrote. Accepting this answer and later today I'm going to go through it to make sure I understand it. It looks like you're counting bits (a theory I had but couldn't make it work), but then removing bits you have already counted in others? –  dalore May 2 '12 at 6:49
@dalore, added a bit of explanation –  Winston Ewert May 2 '12 at 16:47

EDIT: updated requirement: Given 3 unsigned 30-bit integers, return the number of 30-bit integers that when compared with any of the original numbers have the same position bits set to 1. That is we enumerate all the 0s

OK that's a bit tougher. It's easy to calculate for one number, since in that case the number of possible integers depends only on the number of zero bits, like this:

// Count bits not set
const size_t NUMBITS=30;
size_t c;
size_t v = num;
for (c=NUMBITS; v; v >>= 1)
c -= v & 1;

return c;

Naively you might try extending this to three integers by doing it for each and summing the results, however that would be wrong because the possibilities need to be unique, e.g. given

A = 1001
B = 0011
C = 0110

You would count e.g. 1111 three times rather than once. You should subtract the number of combinations that are shared between any two numbers, but not subtract any combination twice. This is simply a C++ translation of Winston Ewert's answer!

size_t zeroperms(size_t v)
{
// Count number of 0 bits
size_t c = 1;
for (c=NUMBITS; v; v >>= 1)
c -= v & 1;
// Return number of permutations possible with those bits
return 1 << c;
}

size_t enumerate(size_t a, size_t b, size_t c)
{
size_t total = zeroperms(a) + zeroperms(b) + zeroperms(c);
total -= zeroperms(a | b); // counted twice, remove one
total -= zeroperms(b | c); // counted twice, remove one
total -= zeroperms(a | c); // counted twice, remove one
total += zeroperms(a | b | c); // counted three times, removed three times, add one
}
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Sorry I got the question slightly wrong, I've edited it now. –  dalore May 1 '12 at 17:52
OK I've updated my answer to the new requirements. –  smocking May 1 '12 at 18:45
This reports 3 for 1111, 1111, 1111 –  Winston Ewert May 1 '12 at 19:29
Darn messed up for c=0. Fixed. –  smocking May 1 '12 at 19:38
Cleaned up the code a bit with a loop and changed it to 30 bits now –  smocking May 1 '12 at 19:51

### Trick 1:

The total answer is the union of each individual 30 bit number. This translates to the bitwise union operator, OR. This means we can do D = A | B | C With your 4 bit example, we arrive at D = 1111 Now we only need to work with 1 number

### Trick 2:

A little bit of maths tells us that for every 1 we double our possible set of numbers. This means all you need to do is raise 2 to the power of the number of 1s. Count the 1s with a loop, shifting down each time

bits = 0
D = 0b1111 #our number from trick 1
for i in range(4): #here 4 is the number of bits
if D & 1:
bits += 1
D >>= 1 #drop off the smallest number
print 2 ** bits

in this case it will print 16

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Aren't you mistakenly including 0 in your count? –  smocking May 1 '12 at 17:47
Trick 1 is slightly wrong, || in C++ is boolean or, not bitwise or. –  Daniel Roethlisberger May 1 '12 at 17:57
@DanielRoethlisberger Oops, how embarrassing –  Andrew Brock May 1 '12 at 17:59
Should print 8 for the 4bit example –  dalore May 1 '12 at 18:31
@dalore we are both wrong, 2^4 is 16, thanks tho –  Andrew Brock May 1 '12 at 18:33