You cannot do what you want in a portable way, because the C language standard does not specify the stack, program area, and heap as distinct areas. Their location can depend on the processor architecture, the operating system, the loader, the linker, and the compiler. Trying to guess where a pointer is pointing is breaking the abstraction provided by C, so you probably you shouldn't be doing that.
Nevertheless, there are ways to write code that will make a correct guess for a specific environment. You do that by examining the addresses of existing objects, and looking for patterns. Consider the following program.
printf("stack2: %15p\n", &stack2);
main(int argc, char *argv)
void *heap = malloc(1);
void *heap2 = malloc(1);
printf("program: %15p\n", main);
printf("heap: %15p\n", heap);
printf("heap2: %15p\n", heap2);
printf("stack: %15p\n", &stack);
By examining its output you can see a pattern, such as the following on x64 Linux.
From the above you can determine that (probably) the heap grows up from 0x1675010, anything below it is program code (or static data, which you didn't mention), and that the stack grows in an unpredictable manner (probably due to stack randomization) around a very large address, like 0x7fff282c783c.
Compare this with the output under 32-bit Intel Linux:
Microsoft Windows and the 32-bit Microsoft C compiler:
gcc under Windows Cygwin:
gcc under Intel 32-bit FreeBSD:
gcc under Intel 64-bit FreeBSD:
gcc under SPARC-64 FreeBSD:
PowerPC running MacOS X:
PowerPC running Linux:
StrongARM running NetBSD:
and ARMv6 running Linux:
As you can see the possibilities are endless.