why the result is “2” of unsigned int (1) - unsigned int (0xFFFFFFFF)

Question

Please look at the following codes:

#include <stdlib.h>
#include <stdio.h>


int main()
{
    unsigned int a = 1;
    unsigned int b = -1;

    printf("0x%X\n", (a-b));

    return 0;
}

The result is 0x2.

I　think the integer promotion should not happen because the type of both of "a" and "b" are unsigned int. But the result beats me.... I don't know the reason.

By the way, I know the arithmetic result should be 2 because 1-(-1)=2. But the type of b is unsigned int. When assign the (-1) to b, the value of b is 0xFFFFFFFF actually. It is the maximum value of unsigned int. When one small unsigned value subtract one big value, the result is not that I expect.

From the answer below, I think maybe the overflow is a good explanation。 Now I writes other test codes. It proves the overflow answer is right.

#include <stdlib.h>
#include <stdio.h>

int main()
{
    unsigned int c = 1;
    unsigned int d = -1;


    printf("0x%llx\n", (unsigned long long)c-(unsigned long long)d);

    return 0;
}

The result is "0xffffffff00000002". It is I expect.

Answer 1

unsigned int a = 1;

This initializes a to 1. Actually, since 1 is of type int, there's an implicit int-to-unsigned conversion, but it's a trivial conversion that doesn't change the value or representation).

unsigned int b = -1;

This is more interesting. -1 is of type int, and the initialization implicitly converts it from int to unsigned int. Since the mathematical value -1 cannot be represented as an unsigned int, the conversion is non-trivial. The rule in this case is (quoting section 6.3.1.3 of the C standard):

the value is converted by repeatedly adding or subtracting one more than the maximum value that can be represented in the new type until the value is in the range of the new type.

Of course it doesn't actually have to do it that way, as long as the result is the same. Adding UINT_MAX+1 ("one more than the maximum value that can be represented in the new type") to -1 yields UINT_MAX. (That addition is defined mathematically; it's not itself subject to any type conversions.)

In fact, assigning -1 to an object of any unsigned type is a good way to get the maximum value of that type without having to refer to the *_MAX macros defined in <limits.h>.

So, assuming a typical 32-bit system, we have a == 1 and b == 0xFFFFFFFF.

printf("0x%X\n", (a-b));

The mathematical result of the subtraction is -0xFFFFFFFE, but that's obviously outside the range of unsigned int. The rules for unsigned arithmetic are similar to the rules for unsigned conversion; the result is 2.

Answer 2

Who says you're suffering integer promotion? Let's pretend that your integers are two's complement (likely, though not mandated by the standard) and they're only four bits wide (not possible according to the standard, I'm just using this to simplify things).

int   unsigned-int  bit-pattern
---   ------------  -----------
  1              1         0001
 -1             15         1111
                         ------
  (subtract with borrow) 1 0010
   (only have four bits)   0010  -> 2

You can see here that you can get the result you see without any promotion to signed or wider types.

Answer 3

There should be a compiler warning that you probably ignored or turned off, but it's still possible to store -1 in an unsigned integer. Internally, -1 is stored on a 32-bit machine as 0xffffffff. So if you subtract 0xffffffff from 1, you end up with -0xfffffffe, which is 2. (There are no negative numbers, a negative number is the maximum integer value plus one minus the number).

Bottom line - signed or unsigned doesn't matter at all, it only comes to play when you compare values.

And mathematically speaking, 1 - (-1) = 1+1.

Answer 4

If you subtract a negative number, it is the equivalent of adding a positive number.

a = 1
b = -1

(a-b) = ?
((1)-(-1)) = ?
(1-(-1)) = ?
(1+1) = ?
2 = ?

At first you might think that this isn't allowed, since you specified an unsigned int; however, you are also converting signed int (the -1 constant) to an unsigned int. So, you are effectively storing the exact same bits into the unsigned int (0xFFFF).

Then, in the expression, you take the negative of the 0xFFFF value, which of course forces the number to be signed. In effect, you are circumventing the unsigned directive at ever step.