I have a question regarding using
long int. I've observed that incrementing memory addresses (e.g. via manual pointer arithmetic) differs by data type. For instance incrementing a char pointer adds 1 to the memory address, whereas incrementing an int pointer adds 4, 8 for a double, 16 for a long double, etc...
At first I did something like this:
char myChar, *pChar; float myFloat, *pFloat; pChar = &myChar; pFloat = &myFloat; printf( "pChar: %d\n", ( int )pChar ); printf( "pFloat: %d\n", ( int )pFloat ); pChar++; pFloat++; printf( "and then after incrementing,:\n\n" ); printf( "pChar: %d\n", (int)pChar ); printf( "pFloat: %d\n", (int)pFloat );
which compiled and executed just fine, but XCode gave me warnings for my typecasting: "Cast from pointer to integer of different size."
After some googling and binging (is the latter a word yet?), I saw some people recommend using
printf( "pChar: %ld\n", ( intptr_t )pChar ); printf( "pFloat: %ld\n", ( intptr_t )pFloat );
which indeed resolves the errors. So, I thought, from now on, I should use
intptr_t for typecasting pointers... But then after some fidgeting, I found that I could solve the problem by just replacing
printf( "pChar: %ld\n", ( long int )pChar ); printf( "pFloat: %ld\n", ( long int )pFloat );
So my question is, why is
intptr_t useful, and when should it used? It seems superfluous in this instance. Clearly, the memory addresses for
myFloat were just too big to fit in an
int... so typecasting them to
long ints solved the problem.
Is it that sometimes memory addresses are too big for
long int as well? Now that I think about it, I guess that's possible if you have > 4GB of RAM, in which case memory addresses could exceed 2^32 - 1 (max value for unsigned long ints...) but C was created long before that was imaginable, right? Or were they that prescient?