I've spent some time poring over the standard references, but I've not been able to find an answer to the following:

- is it technically guaranteed by the C/C++ standard that, given a signed integral type S and its unsigned counterpart U, the absolute value of each possible S is always less than or equal to the maximum value of U?

The closest I've gotten is from section *6.2.6.2* of the C99 standard (the wording of the C++ is more arcane to me, I assume they are equivalent on this):

For signed integer types, the bits of the object representation shall be divided into three groups: value bits, padding bits, and the sign bit. (...) Each bit that is a value bit shall have the same value as the same bit in the object representation of the corresponding unsigned type (if there are M value bits in the signed type and Nin the unsigned type, then M≤N).

So, in hypothetical 4-bit signed/unsigned integer types, is anything preventing the unsigned type to have 1 padding bit and 3 value bits, and the signed type having 3 value bits and 1 sign bit? In such a case the range of unsigned would be [0,7] and for signed it would be [-8,7] (assuming two's complement).

In case anyone is curious, I'm relying at the moment on a technique for extracting the absolute value of a negative integer consisting of first a cast to the unsigned counterpart, and then the application of the unary minus operator (so that for instance -3 becomes 4 via cast and then 3 via unary minus). This would break on the example above for -8, which could not be represented in the unsigned type.

EDIT: thanks for the replies below Keith and Potatoswatter. Now, my last point of doubt is on the meaning of "subrange" in the wording of the standard. If it means a strictly "less-than" inclusion, then my example above and Keith's below are not standard-compliant. If the subrange is intended to be potentially the whole range of unsigned, then they are.

`intN_t`

resp.`uintN_t`

. Unfortunately, they are not guaranteed to be provided. – Daniel Fischer Jul 7 '12 at 11:06