# Bitmask to flip bits … without XOR?

Pretty simple, really. I want to negate an integer which is represented in 2's complement, and to do so, I need to first flip all the bits in the byte. I know this is simple with XOR--just use XOR with a bitmask 11111111. But what about without XOR? (i.e. just AND and OR). Oh, and in this crappy assembly language I'm using, NOT doesn't exist. So no dice there, either.

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Even a "crappy assembly language" should have some way of doing NOT. Maybe it's called something else? –  pavium May 29 '11 at 1:50
It might help if you listed all of the the operations actually available in this "crappy assembly language". It is provably impossible to do what you are trying to do with just AND and OR. –  Nemo May 29 '11 at 1:55
Yeah, I'm dumb. All I had to do was subtract the integer from 0 ... which negates it. Clearly. –  Asker Jun 6 '11 at 5:42

You can't build a NOT gate out of AND and OR gates.

As I was asked to explain, here it is nicely formatted. Let's say you have any number of `AND` and `OR` gates. Your inputs are `A`, 0 and 1. You have six possibilities as you can make three pairs out of three signals (pick one that's left out) and two gates. Now:

``````Operation  Result
A AND A    A
A AND 1    A
A AND 0    0
A OR A     A
A OR 1     1
A OR 0     A
``````

So after you fed any of your signals into the first gate, your new set of signals is still just A, 0 and 1. Therefore any combination of these gates and signals will only get you A, 0 and 1. If your final output is A, then this means that for both values of A it won't equal !A, if your final output is 0 then A = 0 is such a value that your final value is not !A same for 1.

Edit: that monotony comment is also correct! Let me repeat here: if you change any of the inputs of AND / OR from 0 to 1 then the output won't decrease. Therefore if you claim to build a NOT gate then I will change your input from 0 to 1 , your output also can't decrease but it should -- that's a contradiction.

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Do you think you could explain why? –  Asker May 29 '11 at 1:41
but you can out of NAND and NOR gates.....since both are universal gates. –  Mitch Wheat May 29 '11 at 1:47
Why? Well, say you have A, 0, 1 AND, OR... now combine 'em you will immediately see. A AND A is A, A AND 0 is 0, A AND 1 is A, A OR A is A, A OR 1 is 1, A OR 0 is A. You want to combine these signals and gates and get to A but as you can see after the first step you still only have A, 0, 1 signals and it's impossible to break out of this circle. –  chx May 29 '11 at 1:48
Because AND and OR are monotone functions, and the composition of monotone functions is a monotone function, and NOT is not a monotone function. (A "monotone function" is one which, when you increase one of its inputs, the output stays the same or increases.) –  Nemo May 29 '11 at 1:52
NOT is a function defined by its inputs and outputs and you can meticulously inspect the inputs and the outputs. Nothing to believe. –  chx May 29 '11 at 1:58

Does `(foo & ~bar) | (~foo & bar)` do the trick?

Edit: Oh, NOT doesn't exist. Didn't see that part!

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Unfortunately I don't get NOT either. –  Asker May 29 '11 at 1:41