I ran the following program on my computer (64-bit Intel running Linux).

#include <stdio.h>

void test(int argc, char **argv) {
    printf("[test] Argc Pointer: %p\n", &argc);
    printf("[test] Argv Pointer: %p\n", &argv);

int main(int argc, char **argv) {
    printf("Argc Pointer: %p\n", &argc);
    printf("Argv Pointer: %p\n", &argv);
    printf("Size of &argc: %lu\n", sizeof (&argc));
    printf("Size of &argv: %lu\n", sizeof (&argv));
    test(argc, argv);
    return 0;

The output of the program was

$ gcc size.c -o size
$ ./size
Argc Pointer: 0x7fffd7000e4c
Argv Pointer: 0x7fffd7000e40
Size of &argc: 8
Size of &argv: 8
[test] Argc Pointer: 0x7fffd7000e2c
[test] Argv Pointer: 0x7fffd7000e20

The size of the pointer &argv is 8 bytes. I expected the address of argc to be address of (argv) + sizeof (argv) = 0x7ffed1a4c9f0 + 0x8 = 0x7ffed1a4c9f8 but there is a 4 byte padding in between them. Why is this the case?

My guess is that it could be due to memory alignment, but I am not sure.

I notice the same behaviour with the functions I call as well.

  • 15
    Why not? They could be 174 bytes apart. An answer will depend on your operating system and/or a wrapper library that does setup for main.
    – aschepler
    Feb 8 '20 at 15:38
  • 2
    @aschepler: It should not depend on any wrapper that does setup for main. In C, main can be called as a regular function, so it needs to receive arguments like a regular function and must obey the ABI. Feb 8 '20 at 15:52
  • @aschelper: I notice the same behaviour for other functions as well.
    – letmutx
    Feb 8 '20 at 15:55
  • 4
    It's an interesting 'thought experiment', but really, there is nothing that should be more than a 'I wonder why'. These addresses can change depending on the os, compiler, compiler version, processor architecture and in no way should be depended upon in 'real life'.
    – Neil
    Feb 9 '20 at 12:31
  • 2
    the result of sizeof must be printed using %zu
    – phuclv
    Feb 10 '20 at 3:22

On your system, the first few integer or pointer arguments are passed in registers and have no addresses. When you take their addresses with &argc or &argv, the compiler has to fabricate addresses by writing the register contents to stack locations and giving you the addresses of those stack locations. In doing so, the compiler chooses, in a sense, whatever stack locations happen to be convenient for it.

  • 7
    Note that this could happen even if they are passed on the stack; the compiler has no obligation to use the incoming-value slot on the stack as the storage for the local objects the values go into. It might make sense to do this is the function is eventually going to tail-call and needs the current values of these objects to produce the outgoing arguments for the tail-call. Feb 8 '20 at 16:39

Why are the addresses of argc and argv 12 bytes apart?

From the perspective of the language standard, the answer is "no particular reason". C does not specify or imply any relationship between the addresses of function parameters. @EricPostpischil describes what is probably happening in your particular implementation, but those details would be different for an implementation in which all arguments are passed on the stack, and that is not the only alternative.

Moreover, I'm having trouble coming up with a way in which such information could be useful within a program. For example, even if you "know" that the address of argv is 12 bytes before the address of argc, there's still no defined way to compute one of those pointers from the other.

  • 7
    @R..GitHubSTOPHELPINGICE: Computing one from the other is partially defined, not well defined. The C standard is not strict on how the conversion to uintptr_t is performed, and it certainly does not define relationships between the addresses of parameters or where arguments are passed. Feb 8 '20 at 17:04
  • 6
    @R..GitHubSTOPHELPINGICE: The fact that you can round-trip means that g(f(x)) = x, where x is a pointer, f is convert-pointer-to-uintptr_t, and g is convert-uintptr_t-to-pointer. Mathematically and logically, it does not imply that g(f(x)+4) = x+4. For example, if f(x) were x² and g(y) were sqrt(y), then g(f(x)) = x (for real non-negative x), but g(f(x)+4) ≠ x+4, in general. In the case of pointers, the conversion to uintptr_t might give an address in the high 24 bits and some authentication bits in the low 8 bits. Then adding 4 just screws up the authentication; it does not update… Feb 9 '20 at 0:43
  • 5
    … the address bits. Or the conversion to uintptr_t might give a base address in the high 16 bits and an offset in the low 16 bits, and adding 4 to the low bits might carry into the high bits, but the scaling is wrong (because the address represented is not base•65536+offset but rather is base•64+offset, as it was in some systems). Quite simply, the uintptr_t you get from a conversion is not necessarily a simple address. Feb 9 '20 at 0:45
  • 4
    @R..GitHubSTOPHELPINGICE from my reading of the standard, there is only a weak guarantee that (void *)(uintptr_t)(void *)p will compare equal to (void *)p. And it is worthwhile to note that the committee has commented on nearly this exact issue, concluding that "implementations ... may also treat pointers based on different origins as distinct even though they are bitwise identical." Feb 9 '20 at 8:21
  • 5
    @R..GitHubSTOPHELPINGICE: Sorry, I missed that you were adding a value calculated as the different of two uintptr_t conversions of addresses rather than a different of pointers or a “known” distance in bytes. Sure, that is true, but how is it useful? It remains true that “there's still no defined way to compute one of those pointers from the other” as the answer states, but that calculation does not calculate b from a but rather calculates b from both a and b, since b must be used in the subtraction to calculate the amount to add. Computing one from the other is not defined. Feb 9 '20 at 12:12

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