# Is ones complement distributive?

I know it's associative and commutative:

That is,

``````(~x1 + ~x2) + ~x3 = ~x1 + (~x2 + ~x3)
``````

and

``````~x1 + ~x2 = ~x2 + ~x1
``````

However, for the cases I tried, it doesn't seem to be distributive, i.e,

``````~x1 + ~x2 != ~(x1 + x2)
``````

Is this true? Is there a proof?

I have C code as follows:

``````int n1 = 5;
int n2 = 3;
result = ~n1 + ~n2 == ~(n1 + n2);

int calc = ~n1;
int calc0 = ~n2;
int calc1 = ~n1 + ~n2;
int calc2 = ~(n1 + n2);

printf("(Part B: n1 is %d, n2 is %d\n", n1, n2);
printf("Part B: (calc is: %d and calc0 is: %d\n", calc, calc0);
printf("Part B: (calc1 is: %d and calc2 is: %d\n", calc1, calc2);
printf("Part B: (~%d + ~%d) == ~(%d + %d) evaluates to %d\n", n1, n2, n1, n2, result);
``````

Which gives the following output:

``````Part B: (n1 is 5, n2 is 3
Part B: (calc is: -6 and calc0 is: -4
Part B: (calc1 is: -10 and calc2 is: -9
Part B: (~5 + ~3) == ~(5 + 3) evaluates to 0
``````
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This doesn't look like distributive rule. And distribute of what over what? –  nhahtdh Jun 18 '12 at 1:27
Then perhaps distributive is not the right word? I was just wondering if the inequality could be proven. That is, is the sum of ones' complement of 2 numbers equal to the ones complement of the sum? –  user1317750 Jun 18 '12 at 1:41
What does `+` mean? Is it OR, or is it ADD? –  nhahtdh Jun 18 '12 at 2:10
My apologies, I'm adding 2 binary numbers. –  user1317750 Jun 18 '12 at 2:43
Then you can check my answer. –  nhahtdh Jun 18 '12 at 2:44

From De Morgan's laws:

`````` ~(x1 + x2) = ~x1 * ~x2
``````
-

Check out the Wikiepdia article on Ones' complement. Addition in one's complement has end-carry around where you must add the overflow bit to the lowest bit.

Since `~` (NOT) is equivalent to `-` (NEGATE) in ones' complement, we can re-write it as:

``````-x1 + -x2 = -(x1 + x2)
``````

which is correct.

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But this equality doesn't hold. I ran a C program and I get false for every number I've tried. I read somewhere that ones complement was not distributive, but how to prove this? –  user1317750 Jun 18 '12 at 2:58
@user1317750: At least Intel uses 2's complement in the representation of negative numbers (not sure about others), so of course it is wrong. I don't know distributive rule of what operator over what operator, so I cannot say anything here. –  nhahtdh Jun 18 '12 at 3:32
If x and y are represented as 32 bit integers, and if you take the ones complement of x and the ones complement of y, and add them together, do you get the same result as adding x and y, getting z, and taking the ones complement of z. By ones complement, I just mean flipping the bits. –  user1317750 Jun 18 '12 at 12:38
@user1317750: They should always be equal, if you do the addition correctly. If you can find any counter example, try to post it here (I don't think there will be any, though). –  nhahtdh Jun 18 '12 at 12:40
I have added the C code to my original post. –  user1317750 Jun 18 '12 at 22:44

One's compliment is used to represent negative and positive numbers in fixed-width registers. To distribute over addition the following must apply: `~a + ~b` = `~(a + b)`. The OP states `+` represents adding 'two binary numbers'. This itself is vague, however if we take it to mean adding unsigned binary numbers, then no, one's compliment is not distributive.

Note that there are two zeroes in one's compliment: all bits are ones or all bits are zeroes.

Check to see that `~0 + ~0 != ~(0 + 0)`: `~0` is zero. However, `~0` is represented by all ones. Adding it to itself is doubling it -- the same as a left shift -- and thus introduces a zero in the right hand digit. But that is no longer one of the two zeroes.

However, `0` is zero, and `0 + 0` is also zero, and thus so is `~(0 + 0)`. But the left side isn't zero, so to distribution does not hold.

On the other hand... Consider two's compliment: flip all bits and add one. If care is taken to treat negatives in one's compliment specially, then that version of 'binary addition' is similar to two's compliment and is distributive as you end up with a familiar quotient ring just like in two's compliment.

The aforementioned Wikipedia article has more details on handling addition to allow for expected arithmetic behavior.

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