So I have about this code:
uint32_t s1 = 0xFFFFFFFFU;
uint32_t s2 = 0xFFFFFFFFU;
v = s1 * s2; /* Only need the low 32 bits of the result */
In all the followings I assume the compiler couldn't have any preconceptions on the range of
s2, the initializers only serving for an example above.
If I compiled this on a compiler with an integer size of 32 bits (such as when compiling for x86), no problem. The compiler would simply use
uint32_t typed values (not being able to promote them further), and the multiplication would simply give the result as the comment says (modulo
UINT_MAX + 1 which is 0x100000000 this case).
However if I compiled this on a compiler with an integer size of 64 bits (such as for x86-64), there might be undefined behavior from what I can deduce from the C standard. Integer promotion would see
uint32_t can be promoted to
int (64 bit signed), the multiplication would then attempt to multiply two
int's, which, if they happen to have the values shown in the example, would cause an integer overflow, which is undefined behavior.
Am I correct with this and if so how would you avoid it in a sane way?
I spotted this question which is similar, but covers C++: What's the best C++ way to multiply unsigned integers modularly safely?. Here I would like to get an answer applicable to C (preferably C89 compatible). I wouldn't consider making a poor 32 bit machine potentially executing a 64 bit multiply an acceptable answer though (usually in code where this would be of concern, 32 bit performance might be more critical as typically those are the slower machines).
Note that the same problem can apply to 16 bit unsigned ints when compiled with a compiler having a 32 bit int size, or unsigned chars when compiled with a compiler having a 16 bit int size (the latter might be common with compilers for 8 bit CPUs: the C standard requires integers to be at least 16 bits, so a conforming compiler is likely affected).