I've been brushing up on bit manipulation and came across this. It may not be useful to the original poster now (3 years later), but I am going to answer anyway to improve the quality for other viewers.

**What does it mean for **`n & (n-1)`

to equal zero?

We should make sure we know that since that is the only way to break the loop (`n != 0`

).
Let's say `n=8`

. The bit representation for that would be `00001000`

. The bit representation for `n-1`

(or 7) would be `00000111`

. The `&`

operator returns the bits set in both arguments. Since `00001000`

and `00000111`

do not have any similar bits set, the result would be `00000000`

(or zero).
You may have caught on that the number 8 wasn't randomly chosen. It was an example where `n`

is power of 2. All powers of 2 (2,4,8,16,etc) will have the same result.

What happens when you pass something that is not an exponent of 2? For example, when `n=6`

, the bit representation is `00000110`

and `n-1=5`

or `00000101`

.The `&`

is applied to these 2 arguments and they only have one single bit in common which is 4. Now, `n=4`

which is not zero so we increment `c`

and try the same process with `n=4`

. As we've seen above, 4 is an exponent of 2 so it will break the loop in the next comparison. **It is cutting off the rightmost bit until **`n`

is equal to a power of 2.

**What is **`c`

?

It is only incrementing by one every loop and starts at 0. `c`

is the number of bits cut off before the number equals a power of 2.

`n - 1`

is never the same as`n`

. – 0x499602D2 Mar 12 '13 at 19:24`n = n & (n - 1)`

, in other words`n &= (n-1)`

. The suggested "answered" question asked for something else, as said in its title: what does`n & (n-1)`

do. The purpose of the former one is removing the rightmost value-1 bit, whereas the latter one is to check whether n is the power of 2. I can see the point that the two expressions look similar and their truth tables are the same, but these two questions, and therefore answers, are undoubtedly different – Chris Dec 12 '17 at 22:48