Starting with the original answer, which explains how a NOR gate can be implemented using AND and NOT:

You are asking for a NOR bitwise operation:

```
r = not (a or b)
```

Also, you can use De Morgan's law, that says that it's equivalent to:

```
r = (not a) and (not b)
```

The poster than translates that pseudo-code into the Python you posted. For some reason he used `^ 0b11111111`

to do a binary NOT, rather than simply `~`

, which is what I would have chosen. If we switch `(a ^ 0b11111111)`

to the simpler `~`

then we get:

```
bin(~a & ~b)
```

That expression is how you write "(not a) and (not b)" in Python. `~`

means NOT and `&`

means AND.

A binary NOT flips all of the bits in a number. 0 becomes 1 and 1 becomes 0. The direct way to do that is with `~`

. An indirect way to flip all the bits in a number is to XOR it with all 1 bits. That has the same effect, it's just longer to write.

Or actually, to be more precise, it has *almost* the same effect. `^ 0b11111111`

flips the first eight bits of the number because there are eight 1's. Whereas `~`

flips *all* of the bits. If you're interested in only the first 8 bits then you can add `& 0b11111111`

, which truncates the results to 8 bits:

```
>>> bin((~a & ~b) & 0b11111111)
'0b10011100'
```

In my opinion this is better than the mysterious `^ 0b11111111`

.

original posing if it will help– user2849377 Oct 5 '13 at 21:31`bin(~(a|b) & 0xff)`

– Maxime Oct 6 '13 at 11:58