This is part of a divide-and-conquer strategy for counting bits, called a "population" function. The scholarly treatment of this strategy can be found in Reingold and Nievergelt, 1977.

The idea is to first sum the bits pairwise, then 4-wise, then 8-wise and so on. For example, if you have the bits `1011`

, then the first pair `10`

becomes `01`

because there is one bit and the second becomes `10`

because `10 = 2`

in binary and there are two bits in `11`

. The essential fact here is that:

```
population(x) = x - (x/2) - (x/4) - (x/8) - (x/16) - ... etc.
```

The exact algorithm you have is a variant of what is known as the "HAKMEM" algorithm (see Beeler, Gosper and Schroppel, 1972). This algorithm counts `1`

's in 4-bit fields in parallel, then these sums are converted into 8-bit sums. The last step is an operation to add these 4 bytes by multiplying by `0x01010101`

. The `0x0F0F0F0F`

mask gets the 4-wise bytes sums by masking out non-sum information. For example, lets say the 8-wise field is `10110110`

, then there are 5 bits which is equal to `0101`

, thus we will have `10110101`

. Only the last four bits are significant, so we mask out the first four, ie:

```
10110101 & 0x0F = 00000101
```

You can find an entire chapter on the minutiae of counting bits in the book "Hacker's Delight" by Henry Warren.

`O(1)`

. It's`O(log(n))`

to the number of bits whereas a straightforward loop is`O(n)`

. For a fixed integer size, both this and a straight-forward loop are`O(1)`

. – Mysticial Mar 5 '13 at 20:11