9

I'm currently reading (for the second time) "Hacking : The Art of Exploitation" and have stumbled on something.

The book suggests two different ways to exploit these two similar programs : auth_overflow and auth_overflow2

In the first one, there is a password checking function layed out like this

int check_authentication(char *password) {
    int auth_flag = 0;
    char password_buffer[16];

    strcpy(password_buffer, password);
    ...
}

Inputing more than 16 ASCII characters will change the value of auth_flag to something greater than 0, thus bypassing the check, as shown on this gdb output:

gdb$ x/12x $esp
0xbffff400: 0xffffffff  0x0000002f  0xb7e0fd24  0x41414141
0xbffff410: 0x41414141  0x41414141  0x41414141  0x00000001
0xbffff420: 0x00000002  0xbffff4f4  0xbffff448  0x08048556

password_buffer @ 0xbffff40c
auth_flag @ 0xbffff41c

The second program inverts the two variables :

int check_authentication(char *password) {
    char password_buffer[16];
    int auth_flag = 0;

    strcpy(password_buffer, password);
    ...
}

The author then suggests than it's not possible to overflow into auth_flag, which I really believed. I then proceeded to overflow the buffer, and to my surprise, it still worked. The auth_flag variable was still sitting after the buffer, as you can see on this gdb output:

gdb$ x/12x $esp
0xbffff400: 0xffffffff  0x0000002f  0xb7e0fd24  0x41414141
0xbffff410: 0x41414141  0x41414141  0x41414141  0x00000001
0xbffff420: 0x00000002  0xbffff4f4  0xbffff448  0x08048556

password_buffer @ 0xbffff40c
auth_flag @ 0xbffff41c

I'm wondering if gcc is not reordering local variables for alignement/optimization purposes.

I tried to compile using -O0 flag, but the result is the same.

Does one of you knows why is this happening ?

Thanks in advance.

  • 3
    "Reordering" somehow implies that you expect there to be an initial "order". C++ does not actually specify any kind of order of storage of local variables, whose storage is called "automatic" -- i.e. don't ask don't tell. – Kerrek SB Aug 11 '16 at 8:32
  • I expected the compiler (with its optimizations disabled) to leave the ordering as declared in the code. But I don't know much about compilers. The author of the book seems to expect the same behavior too. I still managed to make it work like I wanted by declaring both variables volatile. – rgehan Aug 11 '16 at 8:38
  • 2
    Well, your expectations are unfortunately uncorrelated with the language rules. (Sorry, you said C, not C++, but the same point applies.) "Reality different from personal expectations" would be an appropriate summary of your experience :-) Automatic storage is just "automatically there", with very few guaranteed specifics. – Kerrek SB Aug 11 '16 at 8:40
  • You're totally right. I find it weird that the first example of the book is based on something inaccurate. I managed to make it work as they expected, but if it's not a general rule then it shouldn't be presented like so – rgehan Aug 11 '16 at 8:42
  • 2
    There might not even be order: On some system auth_flag might not even be in memory, it could be in the CPU register, making the exploit impossible. It seems that author of the book is using a very specific system, and compiler with very specific behaviour. – user694733 Aug 11 '16 at 8:43
11

The compiler authors are completely free to implement any allocation scheme for local variables with automatic storage. auth_flag could be set before or after password_buffer on the stack, it could be in a register, it could be elided completely if proper analysis of the code allows it. There might not even be a stack... The only guarantee the Standard gives you is this:

strcpy(password_buffer, password); invokes undefined behavior if the source string including its null terminator is longer than the destination array password_buffer. Whether this undefined behavior fits your needs is completely outside of the language specification.

As a matter of fact, some implementors purposely complicate the task of would be hackers by randomizing the behavior in cases such as the posted code.

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  • That's what Kerrek SB and user694733 pointed out. I didn't consider that the output from a compiler could be totally different from the one of another compiler. This totally makes sense. Thanks :) – rgehan Aug 11 '16 at 9:06
0

I had the same problem. In order to fix this, put the two variables in a struct. In a struct the fields are always located as defined in the struct. Be aware that the order is reversed.

struct myStruct {
       int auth_flag;
       char password_buffer[16];
};
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