The reason for supporting the notation is historical. Before the first C standard (C89/C90), you couldn't use prototypes in C; prototypes were one of the biggest and most important features of Standard C. All function declarations, therefore, were written the 'empty parentheses' style (when they were written at all; most functions that returned
int were not declared at all). The type
void was also added in C89/C90, though some compilers supported it before the standard was finalized.
Because it was crucial to the success of C89/C90 that existing code should mostly continue to work, the empty parentheses style had to be allowed by the standard. So, your code might have been written in pre-standard C as:
int fun(); /* This declaration would probably have been absent */
fun(12, 13.22, 1234567, "wow", 'c');
return 0; /* This was required until C99 to give reliable exit status */
fun(i, d, l, s, c) /* No return type - implicitly returns int */
long l; /* Defined out of sequence - bad style, but legal */
char c; /* Passed as int; converted to char in function */
char *s; /* Should define all pointer arguments */
double d; /* No definition of i; it was an int by default */
printf("This is what happened to those arguments:\n");
printf("i = %d\n", i);
printf("d = %f\n", d);
printf("l = %ld\n", l);
printf("s = [%s]\n", s);
printf("c = %c\n", c);
/* No return statement - don't use the value from the function */
For the curious: you could omit the
char *s; line in the function definition, and it still compiled and produced the same output. It was a bad idea to try that, though. You could replace the line
int fun(); with
static fun(); and the code compiles cleanly when no diagnostics are requested.
You get no warnings even now if you compile this file (
old31.c) with GCC 9.3.0 using:
$ gcc -std=c90 -o old31 old31.c
Your example as written is skirting around the backwards compatibility provisions. Using
void means it was new code (it would not have been valid in many pre-standard C compilers because it used
void). And new code should not exploit the backwards-compatibility provisions without a good reason. That was true in 1991 as well as in the current millennium (but in 1991, there were a lot more good reasons to exploit the backwards-compatibility provisions). Good pre-standard code usually listed all parameters in the order they were used. Omitted definitions and out of sequence definitions were not entirely satisfactory.
- What can be done with those arguments?
In the code in the question, nothing can be done with the arguments. The caller pushes the values onto the stack, and pops them off when the function returns. The called function is unaware of their existence and can do nothing with them.
- Is it possible to access those arguments within the function?
No — not using any standard mechanism.