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I read that functions in C may use local stack-based variables, and they are allocated simply by decrementing the stack pointer by the amount of space required. This is always done in four-byte chunks (if I am not mistaken). But, what if run code like following:

 void foo(void)
   char str[6];

What size does var str occupy? 6 bytes or 6 × 4 bytes as per the four-byte chunks.

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5 Answers 5

The four-byte-chunk rule just means that the stack pointer must point to an address that is a multiple of four. In this case, allocating 8 bytes satisfies that rule, and such a block is large enough to hold a 6-character array with only 2 bytes of padding.

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Data alignment is a CPU requirement which means that the alignment amount changes from a CPU to another, keep that in mind.

Speaking about stack data-alignment, gcc for example keeps the data aligned using an option called -mpreferred-stack-boundary=n where the data will be aligned to 2^n. By default, the value of n is 4 which makes the stack-alignment 16-bytes.

What this means is that you'll find yourself allocating 16 bytes in stack memory although what you explictly allocated was just an integer.

int main()
        char ar[6] = {1,2,3,4,5,6};
        int x = 10;
        int y = 12 + (int) ar[1] + x;
        return y;

Compiling this code with gcc on my CPU produces the following assembly(posting only the stack-allocation instruction):

subl    $32, %esp

But why 32? we're allocating data that fits exactly in 16 bytes. Well, there are 8 bytes gcc needs to keep saved for the leave and ret which makes the total needed memory 24.
BUT, the alignment requirement is 16-bytes and thus gcc needs to allocate stack-space so that it's made up of 16-bytes chunks; making that 24 bytes to 32 solves the problem.
You'll have enough space for your variables, for the ret and leave and it's made of two 16-bytes chunks.

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The rule of allocating in 4-byte chunks is not valid in all cases. For example, ARM eabi requires aligment of 64-bit integers and doubles on 8-byte boundaries.

Usually the allocated space matches the rules of data packing into structures. So char[6] would actually take 6 bytes (usually), but the padding of the data (for the next field) can use few bytes more.


struct X
    char field1[6];

So the structure X size would be 8

structure Y
    char field1[2];
    double field2;

Structure Y is usually something like 8, 12 or 16 bytes depending on architecture.

Same rules are applied to automatic stack variables: usually the padding is dictated not by type you are using, but by the next type you are going to use. And rules sometimes are a bit vague.

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It is possible to force the compiler to not pad your data structure(s) though as I understand it will cause you to incur performance costs. –  dingrite Mar 24 '13 at 17:05
@dingrite Some compilers allow defining certain aligment on data on the stack. But that is an exeption, as rules are defined by platform documentation and renders parts of application incompatible with standard library and other existing code. –  Valeri Atamaniouk Mar 24 '13 at 17:07
@dingrite I've forgot to mention packed structures. You can use those, but the side effects and limits of portability can outweight the benefit. –  Valeri Atamaniouk Mar 24 '13 at 17:09
I was actually referring to ordering a compiler to treat a struct (maybe even a class) without padding regardless of where it's allocated. I actually used it myself once when I wanted to do some 'organized' memory asm patching - I needed a struct without padding so I used "#pragma pack(push, 1)" and pop on Visual Studio. –  dingrite Mar 24 '13 at 17:11
@dingrite Yes, that would work, but it would still align the structure itself on boundary. So you can adjust alignment of structure members, but the stack alignment stays as as predefined. –  Valeri Atamaniouk Mar 24 '13 at 17:24

I guess you are getting confused between data size and data alignment. There is no general rule, but, on modern computers, your variable will be stored in 6 bytes. On the other side, the next element won't necessarily be stored at the next byte. This is known as data structure padding.

The word-aligned architectures, where every variable must begin on an address which is a multiple of the word size, are becoming rare. With new processors such as SPARC or x86, variables are self-aligned. It means that they have to begin on an address which is a multiple of its type size.

Therefore, there is no "four-bytes chuck rule" on non-exotic computers. In your example, str will be stored with 6 bytes. If you declare a variable with an alignment of 8 bytes for instance (such as double on x86), there will be 2 padding bytes inserted by your compiler.

Alignment is fixed by the compiler, according to your architecture. So the standard doesn't define anything about it. You may find further informations on Wikipedia.

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If you have:

char str[6];
int a;
char b;
char c;

The stack will be of sufficient size to contain all these variables and be divisible by 4 (or whatever alignment is required). But each variable does not need to be aligned on the same boundary (though there may be hardware requirements).

On my system, compiling the above and printing out the addresses of the stack variables (leading digits removed for brevity):

&str    -- 18
&a      -- 12
&b      -- 10
&c      -- 11

i.e the compiler will arrange for the stack to be aligned, but the variables do not need to be padded.

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