# Checking parity of a number in Python

I am trying to understand bitwise operation. The parity is 1 if the number of 1s in the bit is odd and 0 otherwise.

In the following code:

``````def parity(x):
res = 0
while x:
res ^= x & 1
x >>= 1
return result
``````

This gives the correct result, but I am not sure how the bitwise tricks work. I tried to write down the bit changes using the number, but still don't get the intuition of solving this problem.

Why would we check `XOR` with `x & 1` and what do they even mean?

• `x & 1` does a bitwise AND of `x` and `1`. In other words, its value is the low-order bit of `x`, either `0` or `1`. This is then XORed into `res`. Then `x` is right-shifted by one, and the process is repeated until all bits have been handled. – Tom Karzes Aug 18 at 22:42
• What's the significance of XOR here? – Dawn17 Aug 18 at 22:45
• @Dawn17 The exclusive-OR ensures that the result cycles between 0 and 1 as the loop shifts through the bits of x. Trace the state of res on a small input x and you will start to see the pattern. – Matthew E. Miller Aug 18 at 22:55
• @Dawn17 You're trying to compute parity by determining whether there's an even vs. odd number of `1` bits. XOR does exactly that: If you XOR a `0` into your parity, the parity is unchanged. If you XOR a `1` into your parity, the parity is complemented (`0` becomes `1` and `1` becomes `0`). You can easily work this out on paper. – Tom Karzes Aug 18 at 23:39
• @Dawn17 To put it another way, parity is (or can be) defined to be the XOR of all the bits. – Tom Karzes Aug 18 at 23:51

In this code, the first initialization of 'res' is to set our res-state as even. This make sense because we haven't evaluated any bits yet and 0 is even.

Then we move to the while loop where we shift through the bits of x.

Now, we evaluate each bit of x by AND-comparing it with 1 to tell us if it is also a 1 (`x&1`). Then with the results of that comparison, we compare against the current res-state (`res^=(x&1)`).

• If res is even (0) and x-bit is 1, res evaluates to odd (1).
• If res is odd (1) and x-bit is 1, res evaluates to even (0).
• Else res does not change.

And in this way we can ensure res flips between even and odd according to the parity of x.

``````res x  XOR out