Unary negation of unsigned integer 4

If x is an unsigned int type is there a difference in below statements. return (x & 7);

and return (-x & 7);

I understand negating usigned value give a value of max_int - value. But is there a difference in the return value (i.e. true/false) among the above two statements under any specific boundary conditions OR are they both same functionally ?

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You could test for yourself rather easily, couldn't you? In general, yes, there's a difference. –  Jonathan Leffler Nov 29 '13 at 21:32

Test code:

``````#include <stdio.h>

static unsigned neg7(unsigned x) { return -x & 7; }

static unsigned pos7(unsigned x) { return +x & 7; }

int main(void)
{
for (unsigned i = 0; i < 8; i++)
printf("%u: pos %u; neg %u\n", i, pos7(i), neg7(i));
return 0;
}
``````

Test results:

``````0: pos 0; neg 0
1: pos 1; neg 7
2: pos 2; neg 6
3: pos 3; neg 5
4: pos 4; neg 4
5: pos 5; neg 3
6: pos 6; neg 2
7: pos 7; neg 1
``````

For the specific case of 4 (and also 0), there isn't a difference; for other values, there is a difference. You can extend the range of the input, but the outputs will produce the same pattern.

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This also shows that, contrary to what the OP believes, the `&` operator does not return a boolean true/false. –  Jongware Nov 29 '13 at 22:04

Firstly, negating an `unsigned int` value produces `UINT_MAX - original_value + 1`. (For example, `0` remains `0` under negation). The alternative way to describe negation is full inversion of all bits followed by increment.

It is not clear why you'd even ask this question, since it is obvious that basically the very first example that comes to mind - an `unsigned int` value `1` - already produces different results in your expression. `1u & 7` is `1`, while `-1u & 7` is `7`. Did you mean somethig else, by any chance?

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If you ask specifically for true/false (i.e. is zero / not zero) and two's complement then there is indeed no difference. (You do however return not just a simple truth value but allow different bit patterns for `true`. As long as the caller does not distinguish, that is fine.)

Consider how a two's complement negation is formed: invert the bits then increment. Since you take only the least significant bits, there will be no carry in for the increment. This is a necessity, so you can't do this with anything but a range of least significant bits.

Let's look at the two cases:

First, if the three low bits are zero (for a `false` equivalent). Inverting gives all ones, incrementing turns them to zero again. The fourth and more significant bits might be different, but they don't influence the least significant bits and they don't influence the result since they are masked out. So this stays.

Second, if the three low bits are not all zero (for a `true` equivalent). The only way this can change into `false` is when the increment operation leaves them at zero, which can only happen if they were all ones before, which in turn could only happen if they were all zeros before the inversion. That can't be, since that is the first case. Again, the more significant bits don't influence the three low bits and they are masked out. So the result does not change.

But again, this only works when the caller considers only the truth value (all bits zero / not all bits zero) and when the mask allows a range of bits starting from the least significant without a gap.

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