functioning of bitwise and

This question was asked in an interview, can someone tell what does the following code do? It gives output 15 for 150, 3 for 160, 15 for 15. What mathematical operation is it performing on 'n'.

``````int foo(int n)
{
int t,count=0;
t=n;
while(n)
{
count=count+1;
n=(n-1)&t;
}
return count;
}
``````
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Why don't you compile it, run it, and find out? –  Oli Charlesworth Jul 15 '12 at 17:29
@OliCharlesworth I did that, for input 150 it gives 15 and for 160 its 3. I wanted to ask what mathematical operation is it doing on 'n'. –  Vanya Jul 15 '12 at 17:33
Ok, but your question is essentially "what does this arbitrary bit of undocumented code do?", which is not really suitable for Stack Overflow. The behaviour of bitwise operators can be found at e.g. Wikipedia (en.wikipedia.org/wiki/Bitwise_operators). –  Oli Charlesworth Jul 15 '12 at 17:34
I know the functioning of bitwise operators, but was is the function computing as in lcm or hcf or something else –  Vanya Jul 15 '12 at 17:39

It seems to calculate the number `max(n**2-1, 0)`, where n is the number of `1` bits in a number's binary representation:

``````    0     0 0b0
1     1 0b1
2     1 0b10
3     3 0b11
4     1 0b100
5     3 0b101
6     3 0b110
7     7 0b111
8     1 0b1000
9     3 0b1001
10     3 0b1010
11     7 0b1011
12     3 0b1100
13     7 0b1101
14     7 0b1110
15    15 0b1111
16     1 0b10000
17     3 0b10001
18     3 0b10010
19     7 0b10011
20     3 0b10100
21     7 0b10101
22     7 0b10110
23    15 0b10111
24     3 0b11000
25     7 0b11001
26     7 0b11010
27    15 0b11011
28     7 0b11100
29    15 0b11101
30    15 0b11110
31    31 0b11111
32     1 0b100000
33     3 0b100001
34     3 0b100010
35     7 0b100011
36     3 0b100100
37     7 0b100101
38     7 0b100110
39    15 0b100111
40     3 0b101000
41     7 0b101001
42     7 0b101010
43    15 0b101011
44     7 0b101100
45    15 0b101101
46    15 0b101110
47    31 0b101111
48     3 0b110000
49     7 0b110001
50     7 0b110010
51    15 0b110011
52     7 0b110100
53    15 0b110101
54    15 0b110110
55    31 0b110111
56     7 0b111000
57    15 0b111001
58    15 0b111010
59    31 0b111011
60    15 0b111100
61    31 0b111101
62    31 0b111110
63    63 0b111111
64     1 0b1000000
65     3 0b1000001
66     3 0b1000010
67     7 0b1000011
68     3 0b1000100
69     7 0b1000101
70     7 0b1000110
71    15 0b1000111
72     3 0b1001000
73     7 0b1001001
74     7 0b1001010
75    15 0b1001011
76     7 0b1001100
77    15 0b1001101
78    15 0b1001110
79    31 0b1001111
80     3 0b1010000
81     7 0b1010001
82     7 0b1010010
83    15 0b1010011
84     7 0b1010100
85    15 0b1010101
86    15 0b1010110
87    31 0b1010111
88     7 0b1011000
89    15 0b1011001
90    15 0b1011010
91    31 0b1011011
92    15 0b1011100
93    31 0b1011101
94    31 0b1011110
95    63 0b1011111
96     3 0b1100000
97     7 0b1100001
98     7 0b1100010
99    15 0b1100011
``````
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It is easier to find out the "mathematical operation", when function is changed to recursive:

``````int foo(int n, int t)
{
if( n )
return foo( (n-1) & t ) + 1
else
return 0;
}
``````

So formula is:

``````F(0,t) = 0
F(n,t) = F( (n-1) & t, t ) + 1

foo(n) = F(n,n)
``````

I don't have any idea, is that wellknown formula for counting something, or not.

You may find answer from math.stackexchange.com

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That is a method known as Brian Kernighan's way to count set bits :

``````unsigned int v; // count the number of bits set in v
unsigned int c; // c accumulates the total bits set in v
for (c = 0; v; c++)
{
v &= v - 1; // clear the least significant bit set
}
``````

Brian Kernighan's method goes through as many iterations as there are set bits. So if we have a 32-bit word with only the high bit set, then it will only go once through the loop.

Published in 1988, the C Programming Language 2nd Ed. (by Brian W. Kernighan and Dennis M. Ritchie) mentions this in exercise 2-9. On April 19, 2006 Don Knuth pointed out to me that this method "was first published by Peter Wegner in CACM 3 (1960), 322. (Also discovered independently by Derrick Lehmer and published in 1964 in a book edited by Beckenbach.)"

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