Questions about stack allocations in C

Question

The following snippet is intentionally accessing the next sizeof(int) bytes following t[4], so I am aware of the mistake that is being made here. I am just doing this as an experiment to see how the compiler handles the stack allocations.

int t[5], i;

for (i = 0; i <= 5; i++) {
   t[i] = 0;
}

When executing this code on Windows, using a ported version of the GNU C Compiler, the program always gets stuck in an infinite loop. I am sure that this could only happen because t and i are allocated sequentially on the stack one after the other and t[5] points to to the same address as the i variable. Therefore, when executing t[5] = 0 the program actually sets the value of i to zero.

However, when compiling this with a different version of the GNU C Compiler, I never get the infinite loop. The address of t[5] is not the same as the address of i.

My question is, why this different behavior? I know you should not assume anything about the outcome of this, but is it not the case that stack allocations should happen in the same way?

What I am really curious about is how does the compiler manage those stack allocations. Is there any padding? Is the order always the same as in the source code? Obviously this has nothing to do with the C standard and there are differences between implementations, or even different versions of the same compiler. I am curious though what are the possible outcomes and considerations in this particular case.

Answer 1

You are dealing with undefined behaviour. The compiler isn't required to lay out automatic variables sequentially (as they appear in the source code). Some of them might be in registers or they might be ordered in a different way, if, for example, smaller offsets are cheaper.

Such a requirement exists only for the members of a struct (with the members having arbitrary padding in between).

Is there any padding?

Yes, the compiler would honour the alignment requirements of each type and place the variables accordingly.

Is the order always the same as in the source code?

No, but this is the thing many exploits rely on. A buffer overflow may overwrite an adjacent variable and compromise the execution of the entire program.

Answer 2

Another people said why you are getting this behaviour from standard point of view, I will say what potentially could happen after your code compiled optimised and executed.

First : loop might be unrolled and executed 6 times:

t[0] = 0;
t[1] = 0;
t[2] = 0;
t[3] = 0;
t[4] = 0;
t[5] = 0;
i = 6;

It is allowed optimisation and that is what could happen. More: if i is not used later it can be removed altogether.

Second : Compiler might keep i in register without doing any stack allocation.

Third : It might place variable in any order on stack. There is no actual requirements on order in which varaibles are kept in memory (and on their locality too).

How to know what happen? Look at the generated assembly. It is the only way to know what happens.

BTW: Infinite loop does not always happens on Windows. In fact I weren't able to force your code verbatim to be an infinite loop.

Answer 3

Accessing t[5] is an Undefined Behaviour. The last item is t[4] (t[0],t[1],t[2],t[3],t[4]) there is no t[5].

By Undefined Behaviour, anything may happen. It may gives expected results or totally messed up.

My question is, why this different behavior?

As I wrote before, it is UB you can not expect anything. Even you may get another result in the same machine if you try it many times.