Very good question, which exposes the differences between C89, C99 and C++. So this is some commentary on these Standards.
In C89, where n is an int:
is not well defined for all n: there's no restriction on the conversion of signed or unsigned int except that the representation of a non-negative signed int is identical to that of an unsigned int of the same value, provided that value is representable.
This was considered a defect, and in C99, unfortunately there is a faulty attempt to restrict the encoding to two's complement, one's complement, or signed magnitude with the same number of bits. Unfortunately the C committee didn't have much mathematical knowledge and completely botched the specification: on the one hand it is ill-formed due to circular definition and therefore non-normative, and on the other hand, if you excuse this fault, it is a gross overconstraint, which, for example, excludes a BCD representation (used in C on old IBM mainframes), and also allows the programmer to hack the value of an integer by fiddling bits of the representation (which is very bad).
C++ went to some trouble to provide a better specification, however it suffers the same circular definition fault.
Roughly speaking, the representation of a value v is an array of unsigned char with sizeof(v) elements. An unsigned char has a power of two number of elements, and is required to be big enough to ensure it faithfully encodes any aliased data structure. The number of bits in an unsigned char is well defined as the binary log of the number of values representable.
The number of bits of any unsigned value is similarly well defined if it has a power of two number of values from 0 to 2^n-1, by via the canonical positional encoding scheme.
Unfortunately, the committee wanted to ask if there were any "holes" in the representation. For example could you have a 31 bit integer on a x86 machine? I say unfortunately, because this is a badly formed question, and the answer is similarly improper.
The proper way to ask this question is to ask if the representation is full. It is not possible to talk about "the bits of a representation" for signed integers because the specification does not go from the representation to the values, it goes the other way. This may confuse a lot of programmers who incorrectly think a representation is a mapping from underlying bits to some value: a representation is a mapping from the values to the bits.
A representation is full if it is a surjection, that is, it is onto the whole range of the representation space. If the representation is full then there are no "holes", that is, unused bits. However that is not all. A representation of 255 values to an array of 8 bits cannot be full, yet there are no bits which are unused. There are no holes.
The problem is this: consider an unsigned int, then there are TWO distinct bitwise representations. There is the well defined array of log base 2 bits determined from the canonical encoding, and then there is the array of bits of the physical representation given by the aliasing of an array of unsigned char. Even if this representation is full there is no correspondence between the two kinds of bits.
We all know that the "high order bits" of the logical representation can be at one end of the physical representation on some machines and the other on other machines: it's called endian-ness. But in fact there's no reason the bits couldn't be permuted in any order at all, in fact there's no reason the bits should line up at all! Just consider adding 1 modulo the maximum value plus 1 as the representation to see this.
So now the problem is that for signed integers there is no canonical logical representation, rather there are several common ones: two's complement, for example. However as above this is unrelated to the physical representation. The C committee just couldn't understand that the correspondence between the values and physical representation cannot be specified by talking about bits. It must be specified entirely by talking about the properties of functions.
Because this was not done, the C99 standard contains non-normative gibberish and consequently all of the rules for behaviour of signed and unsigned integer conversions are non-normative gibberish as well.
Therefore it is not clear that
will actually produce the desired result for negative values.