This is not possible if you want to remain fully portable.
The range of
unsigned int is only specified to at least cover the non-negative values of
int. The standard allows for implementations where
UINT_MAX == INT_MAX. The same applies to all other non-fixed-width integer types.
Given that the range of
unsigned int may be smaller than that of
int, the pigeonhole principle applies: you have no way of redistributing all values of
int to corresponding but different values of
unsigned int unless
unsigned int can store at least as many different values as
To quote N4140 (roughly C++14):
3.9.1 Fundamental types [basic.fundamental]
1 [...] For narrow character types, all bits of the object representation participate in the value representation. For unsigned narrow character types, all possible bit patterns of the value representation represent numbers. These requirements do not hold for other types. [...]
3 For each of the standard signed integer types, there exists a corresponding (but different) standard unsigned integer type: "
unsigned char", "
unsigned short int", "
unsigned int", "
unsigned long int", and "
unsigned long long int", each of which occupies the same amount of storage and has the same alignment requirements (3.11) as the corresponding signed integer type47; that is, each signed integer type
has the same object representation as its corresponding unsigned integer type. [...] The range of non-negative values of a signed integer type is a
subrange of the corresponding unsigned integer type, and the value representation of each corresponding signed/unsigned type shall be the same. [...]
This guarantees that you don't have a problem for
unsigned char. There is no possibility for
unsigned char to have any kind of padding bits. It wouldn't make sense for
unsigned char to have padding bits: given
unsigned char c;, how would you access those padding bits?
reinterpret_cast<unsigned char &>(c)? That obviously just gives you
c. The only thing similar to padding bits that is possible for
unsigned char is something that's completely transparent to the program, for instance when ECC memory is used.
For all the other non-fixed-width integer type, from
long long, the standard meaning of "subrange" allows for an equal range.
I think I vaguely recall reading that there may have been ancient CPUs that did not provide any native unsigned operations. This would make it very tricky for implementations to properly implement unsigned division, unless they declared that the would-be-sign-bit of unsigned types would be treated as a padding bit. This way, they could simply use the CPU's signed division instruction for either signed or unsigned types.