I'm currently playing around with printing memory addresses in C, and I have a question re: using
long int. Namely I'm just seeing how incrementing memory addresses (viz, pointer arithmetic) differs with data types. E.g., incrementing a pointer to a char adds 1 to the memory address, whereas doing the same on an int pointer adds 4, 8 for a double, 16 for a long double, etc...
At first I did something like this:
char someChar, *pChar; float someStupidFloat, *pFloat; pChar = &someChar; pFloat = &someStupidFloat; 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
long int. That is,
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
someStupidFloat 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 => memory addresses exceeding 2^32 = max for unsigned long ints... but C was created long before that was imaginable, right? Or were they that prescient?