You can do this using strict C, but you need to take certain precautions to ensure compliance with the standard. I will explain these below, but the precautions you need to take are:
(0) Ensure there is no padding by including this declaration:
extern int CompileTimeAssert[
sizeof(some_struct) == NumberOfMembers * sizeof(char *) ? 1 : -1];
(1) Initialize the pointer from the address of the structure, not the address of a member:
char **p = (char **) (char *) &struct1;
(I suspect the above is not necessary, but I would have to insert more reasoning from the C standard.)
(2) Increment the pointer in the following way, instead of using
++ or adding one:
p = (char **) ((char *) p + sizeof(char *));
Here are explanations.
The declaration in (0) acts as a compile-time assertion. If there is no padding in the struct, then the size of the struct equals the number of members multiplied by the size of a member. Then the ternary operator evaluates to 1, the declaration is valid, and the compiler proceeds. If there is padding, the sizes are not equal, the ternary operator evaluates to -1, and the declaration is invalid because an array cannot have a negative size. Then the compiler reports an error and terminates.
Thus, a program containing this declaration will compile only if the struct does not have padding. Additionally, the declaration will not consume any space (it only declares an array that is never defined), and it may be repeated with other expressions (that evaluate to an array size of 1 if their condition is true), so different assertions may be tested with the same array name.
Items (1) and (2) deal with the problem that pointer arithmetic is normally guaranteed to work only within arrays (including a notional sentinel element at the end) (per C 2011 6.5.6 8). However, the C standard makes special guarantees for character types, in C 2011 220.127.116.11 7. A pointer to the struct may be converted to a pointer to a character type, and it will yield a pointer to the lowest addressed byte of the struct. Successive increments of the result, up to the size of the object, yield pointers to the remaining bytes of the object.
In (1), we know from C 2011 18.104.22.168 7, that
(char *) &struct1 is a pointer to the first byte of
struct1. When converted to
(char **), it must be a pointer to the first member of
struct1 (in particular thanks to C 2011 6.5.9 6, which guarantees that equal pointers point to the same object, even if they have different types).
Finally, (2) works around the fact that array arithmetic is not directly guaranteed to work on our pointer. That is,
p++ would be incrementing a pointer that is not strictly in an array, so the arithmetic is not guaranteed by 6.5.6 8. So we convert it to a
char *, for which increments are guaranteed to work by 22.214.171.124 7, we increment it four times, and we convert it back to
char **. This must yield a pointer to the next member, since there is no padding.
One might claim that adding the size of
char ** (say 4) is not the same as four increments of one
char, but certainly the intent of the standard is to allow one to address the bytes of an object in a reasonable way. However, if you want to avoid even this criticism, you can change
+ sizeof(char *) to be
+1+1+1+1 (on implementations where the size is 4) or
+1+1+1+1+1+1+1+1 (where it is 8).