# How to make a bitwise NOR gate

I'm trying to understand the code from an answer I received earlier today:

``````a=0b01100001
b=0b01100010

bin((a ^ 0b11111111) & (b ^ 0b11111111))
``````

This is my understanding:

• `bin` means that the result will be in binary form.
• `a` is the processes going through the gate
• `0b` means base 2 form

Could someone explain the rest? I am confused about `11111111`. `&` is the and gate (confused why this separates the two). And how would you change this to work for any other gate, e.g. XOR, NAND, or...?

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Please add the code example including the name assignments for a and b. –  dansalmo Oct 5 '13 at 21:22
stackoverflow.com/questions/19197495/… original posing if it will help –  user2849377 Oct 5 '13 at 21:31
I have edited my answer (stackoverflow.com/a/19197816/1787973) in order to add this solution: `bin(~(a|b) & 0xff)` –  Maxime Oct 6 '13 at 11:58

``````a ^ 0b11111111      #exclusive or's each bit in a with 1, inverting each bit

>>> a=0b01100001
>>> bin(a ^ 0b11111111)
'0b10011110'

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

This is different than using the ~ operator since ~ returns a negative binary result.

``````>>> bin(~a & ~b)
'-0b1100100
``````

The reason is the ~ operator inverts all bits used in representing the number, including the leading 0's that are not typically displayed, resulting in a 2's complement negative result. By using ^ and the 8 bit binary mask, only the first 8 bits are inverted.

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thank you very much very helpful –  user2849377 Oct 5 '13 at 21:52
Thank you for this explanation, I have updated my answer in order to link to yours: stackoverflow.com/a/19197816/1787973 –  Maxime Oct 6 '13 at 12:04

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`.

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Not quite. `bin(~a&~b)` results in `'-0b1100100'`, whereas `bin((a ^ 0b11111111) & (b ^ 0b11111111))` gives the result `'0b10011100'` which is what the OP expected/desired. –  Tim Pietzcker Oct 5 '13 at 21:51

The `^` is the XOR operator. XOR means Exclusive OR. One of the operand to `^` is a sequence of ones. This essentially means every bit in the other operand (viz., either `a` or `b`) will be flipped. Once the two individual XOR operations are done, their results are OR-ed.

Looking outside of bits, and bitwise operations, if you see it from the realm of logic operations, the code is in essence doing `(! A ) ^ (! B)` which per DeMorgan's law is identically the same as `! (A v B)` which is the NOR operation.

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