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Here is the sequence of steps that takes place when a function is called:

  1. The address of the instruction beyond the function call is pushed onto the stack. This is how the CPU remembers where to go after the function returns.
  2. Room is made on the stack for the function’s return type. This is just a placeholder for now.
  3. The CPU jumps to the function’s code.
  4. The current top of the stack is held in a special pointer called the stack frame.
  5. Everything added to the stack after this point is considered “local” to the function.
  6. All function arguments are placed on the stack.
  7. The instructions inside of the function begin executing.
  8. Local variables are pushed onto the stack as they are defined.

I am not sure how point #6 works. If all function arguments are placed on the stack, how are they accessed?

If for example, there are three arguments a, b and c and are placed on stack like this from top

| a |
| b |
| c |
|   |

Now what happens when the function wants to access c? Are a and b popped out?

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seem impossible to me that step 3 happens before 6: there should be inside the body function code about the evaluation of the caller. Nonsense! –  CapelliC Feb 12 '12 at 9:25

3 Answers 3

No they are not. The stack pointer (typically the esp registry) points to a, esp+8h points to b, esp+16h points to c and so on. There's no need for a to be popped.

Note that this is an implementation detail. You shouldn't worry about these. The number I've given is purely theoretical, on some architectures descending addresses are given to latter parameters, on others the other way around. There's no guarantee this happens.

EDIT: It seems to me like that's not a very reliable source of information. It speaks of stack and heap, but these are implementation details, and might not even be there.

There's no constraint in the standard for anything to be implemented via a stack either. For example, I have the following code generated:

void foo(int x, int y, int z)
01241380  push        ebp  
01241381  mov         ebp,esp 
01241383  sub         esp,0CCh 
01241389  push        ebx  
0124138A  push        esi  
0124138B  push        edi  
0124138C  lea         edi,[ebp-0CCh] 
01241392  mov         ecx,33h 
01241397  mov         eax,0CCCCCCCCh 
0124139C  rep stos    dword ptr es:[edi] 
    int c = x;
0124139E  mov         eax,dword ptr [x] 
012413A1  mov         dword ptr [c],eax 
    c = y;
012413A4  mov         eax,dword ptr [y] 
012413A7  mov         dword ptr [c],eax 
    c = z;
012413AA  mov         eax,dword ptr [z] 
012413AD  mov         dword ptr [c],eax 
012413B0  pop         edi  
012413B1  pop         esi  
012413B2  pop         ebx  
012413B3  mov         esp,ebp 
012413B5  pop         ebp  

So you see, there's no stack there. The runtime has direct access to the elements: dword ptr [x], etc.

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But generally a stack is implemented in a way that you cannot access an element by any other way than an implementation of top().. what am I missing? –  Lazer Feb 12 '12 at 9:18
@Lazer: No. Stack is a data structure where you can add and remove elements from the top of the stack in constant time. No one said you can't random-access them. –  ybungalobill Feb 12 '12 at 9:20

It uses the stack pointer and a relative adress to point out c.

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The stack is a metaphoric stack. Remember it is still a RAM, so you can access each address without popping the rest, if you know what you are looking for.

Since the automatic variable's size is known at compile time - the compiler marks offset for each variable, the offset is determined from where the automatic variables section on stack start [or the stack's head, both are valid and the specific implementation depends might depend on architecture], and it access them by merely: start + offset for each variable's offset.

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On every platform you are likely to encounter, it's a metaphoric stack. If it was a real stack that only had push and pop operations, then the function would have to pop the parameters off if it needed them "out of order". –  David Schwartz Feb 12 '12 at 9:27

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