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For the code shown below, If I print the addresses, I get the following.

&test_var1 = 0x7fff0067d87c
&barrier (passed argument) = 0x7fff0067d770
&i (passed argument) = 0x7fff0067d77c
&test_var2 = 0x7fff0067d78c

There are two things I don't understand here. First is that I read that C pushes arguments from right to left, then how &i is greater than &barrier. Knowing that stack grows from a higher address to a lower address, &i should be at a lower address. Moreover, the local variable test_var2 is at even a greater address.

Secondly, one would expect the value of &barrier and &test_var1 to be close together, but no, you see a big difference of 268 bytes. What is the stack holding in between?

Note that I'm using optimization O3. Is this due to that? Maybe the compiler has played some tricks here? I use volatile to make sure every variable is on the stack here and not cached in some register.

void some_func()
  volatile int test_var1 = 0;
call_func( i, &barrier );

void call_func( volatile int i, volatile pthread_barrier* barrier )
 volatile int test_var2 = 0;
share|improve this question
The way the stack is used is implemented in the specific C compiler. You could look this up in the GCC source in your case. – Peter G. Dec 23 '11 at 14:04
You'd make it a lot easier for all of us if you'd include a complete example we could compile and run. – NPE Dec 23 '11 at 14:11
volatile should have no effect on the address of a variable. Also, you have two different types of volatile here: volatile int means the int itself can change, whereas volatile whatever* means that the "whatever" is volatile, but the pointer (i.e. the variable) is not itself volatile - the other way around would be whatever volatile *. – ams Dec 23 '11 at 17:12

2 Answers 2

up vote 3 down vote accepted

On x86 the stack (used when f() calls g()) grows downward.

Anyhow the way the compiler arranges the var/s for a certain call is implementation dependend.

share|improve this answer
It grows from a higher address to a lower address. For me going from a higher address to a lower address is called upwards, for you its downwards. But I wanted to say that, so yeah you are right and I too. I Edited my question to say from a higher to lower address instead of saying upwards or downwards. – MetallicPriest Dec 23 '11 at 14:26

You're making a bunch of assumptions here, none of which are really warranted:

  • The compiler has to push some number of registers when it calls a function; there's no rule that says they can't be in between the arguments and the local variables.
  • There's no rule that the arguments have to be pushed in any particular order, or event that they are on the stack at all; arguments can be passed in registers, too.
  • How memory is organized into a program stack is processor-dependent; in the x86 architecture it grows downward, not upwards.
share|improve this answer
"In the x86 architecture, it grows downards". That is certainly not true, because if you look at the functions in dissassembly, you will see that rsp is subtracted in the beginning of functions and added at the end. And I was actually using volatile to make sure everything is on the stack. Modified that in my question. – MetallicPriest Dec 23 '11 at 14:19
First link from Googling x86 stack architecture says otherwise: – Ernest Friedman-Hill Dec 23 '11 at 14:22
Its the way you interpret it. By upward I meant from a higher address to lower address, which you and this link call it downward. So basically what I wanted to say is that it grows from a higher address towards lower address. – MetallicPriest Dec 23 '11 at 14:24
This link has some nice diagrams:… – Ernest Friedman-Hill Dec 23 '11 at 14:24
@MetallicPriest pretty well any speaker of English uses 'downward' to mean 'from higher to lower' – Pete Kirkham Dec 23 '11 at 14:28

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