OK, let's go through the code line by line:

### Line 1:

```
i = i - ((i >> 1) & 0x55555555);
```

First of all, the significance of the constant `0x55555555`

is that, written using the Java / GCC style binary literal notation),

```
0x55555555 = 0b01010101010101010101010101010101
```

That is, all its odd-numbered bits (counting the lowest bit as bit 1 = odd) are `1`

, and all the even-numbered bits are `0`

.

The expression `((i >> 1) & 0x55555555)`

thus shifts the bits of `i`

right by one, and then sets all the even-numbered bits to zero. (Equivalently, we could've first set all the odd-numbered bits of `i`

to zero with `& 0xAAAAAAAA`

and *then* shifted the result right by one bit.) For convenience, let's call this intermediate value `j`

.

What happens when we subtract this `j`

from the original `i`

? Well, let's see what would happen if `i`

had only *two* bits:

```
i j i - j
----------------------------------
0 = 0b00 0 = 0b00 0 = 0b00
1 = 0b01 0 = 0b00 1 = 0b01
2 = 0b10 1 = 0b01 1 = 0b01
3 = 0b11 1 = 0b01 2 = 0b10
```

Hey! We've managed to count the bits of our two-bit number!

OK, but what if `i`

has more than two bits set? In fact, it's pretty easy to check that the lowest two bits of `i - j`

will still be given by the table above, *and so will the third and fourth bits*, and the fifth and sixth bits, and so and. In particular:

despite the `>> 1`

, the lowest two bits of `i - j`

are not affected by the third or higher bits of `i`

, since they'll be masked out of `j`

by the `& 0x55555555`

; and

since the lowest two bits of `j`

can never have a greater numerical value than those of `i`

, the subtraction will never borrow from the third bit of `i`

: thus, the lowest two bits of `i`

also cannot affect the third or higher bits of `i - j`

.

In fact, by repeating the same argument, we can see that the calculation on this line, in effect, applies the table above to *each* of the 16 two-bit blocks in `i`

*in parallel*. That is, after executing this line, the lowest two bits of the new value of `i`

will now contain the *number* of bits set among the corresponding bits in the original value of `i`

, and so will the next two bits, and so on.

### Line 2:

```
i = (i & 0x33333333) + ((i >> 2) & 0x33333333);
```

Compared to the first line, this one's quite simple. First, note that

```
0x33333333 = 0b00110011001100110011001100110011
```

Thus, `i & 0x33333333`

takes the two-bit counts calculated above and throws away every second one of them, while `(i >> 2) & 0x33333333`

does the same *after* shifting `i`

right by two bits. Then we add the results together.

Thus, in effect, what this line does is take the bitcounts of the lowest two and the second-lowest two bits of the original input, computed on the previous line, and add them together to give the bitcount of the lowest *four* bits of the input. And, again, it does this in parallel for *all* the 8 four-bit blocks (= hex digits) of the input.

### Line 3:

```
return (((i + (i >> 4)) & 0x0F0F0F0F) * 0x01010101) >> 24;
```

OK, what's going on here?

Well, first of all, `(i + (i >> 4)) & 0x0F0F0F0F`

does exactly the same as the previous line, except it adds the adjacent *four-bit* bitcounts together to give the bitcounts of each *eight-bit* block (i.e. byte) of the input. (Here, unlike on the previous line, we can get away with moving the `&`

outside the addition, since we know that the eight-bit bitcount can never exceed 8, and therefore will fit inside four bits without overflowing.)

Now we have a 32-bit number consisting of four 8-bit bytes, each byte holding the number of 1-bit in that byte of the original input. (Let's call these bytes `A`

, `B`

, `C`

and `D`

.) So what happens when we multiply this value (let's call it `k`

) by `0x01010101`

?

Well, since `0x01010101 = (1 << 24) + (1 << 16) + (1 << 8) + 1`

, we have:

```
k * 0x01010101 = (k << 24) + (k << 16) + (k << 8) + k
```

Thus, the *highest* byte of the result ends up being the sum of:

- its original value, due to the
`k`

term, plus
- the value of the next lower byte, due to the
`k << 8`

term, plus
- the value of the second lower byte, due to the
`k << 16`

term, plus
- the value of the fourth and lowest byte, due to the
`k << 24`

term.

(In general, there could also be carries from lower bytes, but since we know the value of each byte is at most 8, we know the addition will never overflow and create a carry.)

That is, the highest byte of `k * 0x01010101`

ends up being the sum of the bitcounts of all the bytes of the input, i.e. the total bitcount of the 32-bit input number. The final `>> 24`

then simply shifts this value down from the highest byte to the lowest.

**Ps.** This code could easily be extended to 64-bit integers, simply by changing the `0x01010101`

to `0x0101010101010101`

and the `>> 24`

to `>> 56`

. Indeed, the same method would even work for 128-bit integers; 256 bits would require adding one extra shift / add / mask step, however, since the number 256 no longer quite fits into an 8-bit byte.