I have a question rather than a problem (witch maybe arises a memory question).. I've written this simple program:

``````#include <stdio.h>
#include <stdlib.h>

int multi(int x, int y);

int main(){
int x;
int y;
printf("Enter the first number x: \n");
scanf("%d",&x);
printf("Enter the second number y: \n");
scanf("%d",&y);
int z=multi(x,y);
printf("The Result of the multiplication is : %d\n",z,"\n");
printf("The Memory adresse of x is : %d\n",&x);
printf("The Memory adresse of y is : %d\n",&y);
printf("The Memory adresse of z is : %d\n",&z);
getchar();
return 0;
}

int multi(int x,int y){
int c=x*y;
printf("The Memory adresse of c is : %d\n",&c);
return c;
}
``````

As you can see (if you develop in C), this program inputs 2 int variables, then multiplies them with the multi function:

after getting the result , it displays the location of each variable in the memory (`c`,`x`,`y` and `z`).

I've tested this simple example those are the results (in my case):

``````The Memory adresse of c is : 2293556
The Result of the multiplication is : 12
The Memory adresse of x is : 2293620
The Memory adresse of y is : 2293616
The Memory adresse of z is : 2293612
``````

as you can see , the three variables `x`,`y`,`z` that are declared in the main function have closed memory adresses (22936xx) , the variable c that's declared in the multi function has a different adress (22935xx).

looking at the `x`,`y` and `z` variables, we can see that there's a difference of 4 bytes between each two variables (i.e : `&x-&y=4`, `&y-&z=4`).

my question is , why does the difference between every two variable equals 4?

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Using `%d` to print pointer values is incorrect, unless you cast them to `(int)` first, and that's a bad idea. Instead, use `%p`. –  R.. Dec 8 '10 at 19:04
thank you, I just tried to use pointers and it comes to a cast error :) –  SmootQ Dec 8 '10 at 19:12

`x`, `y`, and `z`, are integer variables that will be created on the call stack (but see below). The `sizeof int` is 4 bytes, so that is how much space a compiler will allocate on the stack for those variables. These variables are adjacent to one another, so they are 4 bytes apart.

You can read about how memory is allocated for local variables by looking for information on calling conventions.

In some cases (where you do not use the address-of operator), the compiler may optimize local variables into registers.

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thank you for the explanation , and also for the links –  SmootQ Dec 8 '10 at 19:16

In your situation the three variables were allocated in contiguous memory blocks. On x86 systems, `int` types are 32-bits wide, i.e. `sizeof(int) == 4`. So each variable is placed 4 bytes apart from the last.

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thank you for this sizeof(int)==4. –  SmootQ Dec 8 '10 at 19:14

The size of a machine word on your machine is 4 bytes so, for speed of access by your program they offset each variable on a 4 byte boundary.

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Alignment is important, but doesn't seem to be the issue here. –  Stuart Golodetz Dec 8 '10 at 18:49
I would guess that if 3 char variables were declared, they would be on the same boundaries. –  KevinDTimm Dec 8 '10 at 18:50
But the other amazing thing that the c variable in the other function is not on the same boundaries it's really a bit far from x y and z locations –  SmootQ Dec 8 '10 at 18:58
I think it is on the same boundary. What's different is that the stack frame is different and so you see that the function is quite far from the caller. –  KevinDTimm Dec 8 '10 at 21:47

Local variables are allocated on the "stack". Often the compiler will put them in sequential order since there's really no reason not to. An integer in C is 4 bytes. Therefore, it makes sense that `y` comes in 4 bytes after `x`, and `z` comes in 4 bytes after `y`.

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but is this only in case of my machine or for every machine in the world? I can come to a conclusion that for a 64 bits machine, the for integers will be 8 bytes apart. –  SmootQ Dec 8 '10 at 19:18
Most `int` types are 32 bits even in a 64-bit machine. (The "bitness" of a machine refers to the size of the memory-address register, not the size of an integer.) To get a 64-bit integer, use a `long` type. –  chrisaycock Dec 8 '10 at 19:27
–  Emil Sit Dec 8 '10 at 19:28

It appears that you are running on a 32-bit machine. The size of each `int` is 32 bits, and with 8 bits in a byte, the size of an `int` is 4 bytes. Each memory address corresponds to one byte, so there is a difference of 4 between the address of each local variable.

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thank you for this explanation. it was really useful –  SmootQ Dec 8 '10 at 19:13
A 64-bit machine can still allocate 32 bits for an `int` type. –  chrisaycock Dec 8 '10 at 19:30