```
x ^= x >> 16;
x ^= x >> 8;
x ^= x >> 4;
x ^= x >> 2;
x ^= x >> 1;
return (~x) & 1;
```

Assuming you know ints are 32 bits.

Let's see how this works. To keep it simple, let's use an 8 bit integer, for which we can skip the first two shift/XORs. Let's label the bits *a* through *h*. If we look at our number we see:

( *a* *b* *c* *d* *e* *f* *g* *h* )

The first operation is `x ^= x >> 4`

(remember we're skipping the first two operations since we're only dealing with an 8-bit integer in this example). Let's write the new values of each bit by combining the letters that are XOR'd together (for example, *ab* means the bit has the value *a* xor *b*).

( *a* *b* *c* *d* *e* *f* *g* *h* )
xor
( *0* *0* *0* *0* *a* *b* *c* *d* )

The result is the following bits:

( *a* *b* *c* *d* *ae* *bf* *cg* *dh* )

The next operation is `x ^= x >> 2`

:

( *a* *b* *c* *d* *ae* *bf* *cg* *dh* )
xor
( 0 0 *a* *b* *c* *d* *ae* *bf* )

The result is the following bits:

( *a* *b* *ac* *bd* *ace* *bdf* *aceg* *bdfh* )

Notice how we are beginning to accumulate all the bits on the right-hand side.

The next operation is `x ^= x >> 1`

:

( *a* *b* *ac* *bd* *ace* *bdf* *aceg* *bdfh* )
xor
( 0 *a* *b* *ac* *bd* *ace* *bdf* *aceg* )

The result is the following bits:

( *a* *ab* *abc* *abcd* *abcde* *abcdef* *abcdefg* *abcdefgh* )

We have accumulated all the bits in the original word, XOR'd together, in the least-significant bit. So this bit is now zero if and only if there were an even number of 1 bits in the input word (even parity). The same process works on 32-bit integers (but requires those two additional shifts that we skipped in this demonstration).

The final line of code simply strips off all but the least-significant bit (`& 1`

) and then flips it (`~x`

). The result, then, is 1 if the parity of the input word was even, or zero otherwise.

Count the number of set bits in a 32-bit integerWhat is the fastest way for bit operations to calculate a parity?