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I am allocating 12 char string on the stack, or equivalently it is 12 bytes.

Dissembling with gdb (under Linux) reveals that to allocate space for string on the stack, esp is moved by -24 (down the stack).

push   %ebp
mov    %esp,%ebp
sub    $0x18,%esp

Why is it moved by 24 (0x18)?

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This would be easier to answer if you showed the C code –  Andreas Brinck Nov 24 '10 at 19:34
I guess hard to say without seeing your input code. –  Jan Thomä Nov 24 '10 at 19:35
F() { array[12] ...}, above assembly is the call to his function –  newprint Nov 24 '10 at 20:07

2 Answers 2

up vote 6 down vote accepted

Some of it could be space for outgoing parameters, if your function calls others; some of it could be temporary space for values spilled out of registers; some of it could be padding. It will be very dependent on compiler version and optimisation flags.

Here's some simple nonsense code for illustration:

extern int foo(int a, int b);

int bar(int c)
    char s[12];

    s[0] = foo(c, 123);
    return 456;

Here it is compiled with no optimisation using gcc 4.3.2 on a Debian Lenny machine:

    pushl   %ebp
    movl    %esp, %ebp
    subl    $24, %esp
    movl    $123, 4(%esp)
    movl    8(%ebp), %eax
    movl    %eax, (%esp)
    call    foo
    movb    %al, -12(%ebp)
    movl    $456, %eax

Like your code, it's allocating 24 bytes. Here's what they're used for:

     Stack while running bar()
    :                         :
    | incoming parameter: c   | 8(%ebp)
    +-------------------------+            ---
    | return address          | 4(%ebp)     ^
    +-------------------------+             |
    | old %ebp                | (%ebp)      |
    +-------------------------+             |  bar()'s stack
    | s[8]..s[11]             | -4(%ebp)    | frame: 32 bytes
    +-------------------------+             |
    | s[4]..s[7]              | -8(%ebp)    |
    +-------------------------+             |
    | s[0]..s[3]              | -12(%ebp)   |
    +-------------------------+             |     Stack while running foo()
    | (unused)                | 8(%esp)     |    :                         :
    +-------------------------+             |    +-------------------------+
    | outgoing parameter: 123 | 4(%esp)     |    | incoming parameter: b   |
    +-------------------------+             |    +-------------------------+
    | outgoing parameter: c   | (%esp)      v    | incoming parameter: a   |
    +-------------------------+            ---   +-------------------------+
                                                 | return address          |
                                                 | old %ebp                |
                                                 : locals for foo()        :

A bit of experiment will show that if s[] is increased, it will eat into the unused space; e.g. if it is 13 bytes, the stack frame is the same size, but s[] will start one byte earlier (at -13(%ebp)) - up to 16 bytes, where all of the allocated stack will actually be used. If s is declared as s[17], the compiler will allocate 40 bytes of stack instead of 24.

This is because the compiler is keeping the total size of the stack frame (everything on the left of the above diagram, except the incoming parameter, which is really at the bottom of the caller's stack frame) rounded up to a multiple of 16 bytes. (See the gcc documentation for the -mpreferred-stack-boundary option.)

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WOW ! I need to digest this a little bit. Is there a program to generate such cool diagrams ??? –  newprint Nov 24 '10 at 20:49
I think I got it. I was expecting that my array would start at -24 as well, because 24 bytes were allocated. According to your diagram, I was totally wrong, it starts at -12. So when array is pushed on the stack, it will start -12 and work it way up ??(I see the reason why array is "backwards, it is little endian) –  newprint Nov 24 '10 at 21:11
Well, the space reserved for parameters must be at the bottom end of the allocated space for the function call. The compiler happens to be choosing to fill the remaining space with padding at the bottom end and the array at the top (but that's probably a fairly arbitrary choice). The array is not really "backwards" - s[0] is at the lowest address and s[11] is at the highest - I've just drawn my diagram with the lowest address at the bottom! (Endianness relates to the order in which bytes of a multi-byte value such as a 32-bit integer are stored; your array is just a sequence of bytes.) –  Matthew Slattery Nov 25 '10 at 0:38
...oh, and I just use vi for diagrams like this (and not in any particularly clever way, either!). –  Matthew Slattery Nov 25 '10 at 0:53

Because other things besides your string are getting stored on the stack, such as other local variables or temporaries. When you have complicated expressions, the compiler stores sometimes stores intermediate results of those expressions in memory on the stack (especially when optimization is disabled), even if they don't correspond to explicit local variables.

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