According to this movie (around minute 38), if I have two functions with the same local vars, they will use the same space. So the following program, should print 5. Compiling it with gcc results -1218960859. why?

The program:

#include <stdio.h>

void A()
    int a;

void B()
    int a;
    a = 5;

int main()
    return 0;

as requested, here is the output from the disassembler:

0804840c <A>:
 804840c:   55                      push   ebp
 804840d:   89 e5                   mov    ebp,esp
 804840f:   83 ec 28                sub    esp,0x28
 8048412:   8b 45 f4                mov    eax,DWORD PTR [ebp-0xc]
 8048415:   89 44 24 04             mov    DWORD PTR [esp+0x4],eax
 8048419:   c7 04 24 e8 84 04 08    mov    DWORD PTR [esp],0x80484e8
 8048420:   e8 cb fe ff ff          call   80482f0 <printf@plt>
 8048425:   c9                      leave  
 8048426:   c3                      ret    

08048427 <B>:
 8048427:   55                      push   ebp
 8048428:   89 e5                   mov    ebp,esp
 804842a:   83 ec 10                sub    esp,0x10
 804842d:   c7 45 fc 05 00 00 00    mov    DWORD PTR [ebp-0x4],0x5
 8048434:   c9                      leave  
 8048435:   c3                      ret    

08048436 <main>:
 8048436:   55                      push   ebp
 8048437:   89 e5                   mov    ebp,esp
 8048439:   83 e4 f0                and    esp,0xfffffff0
 804843c:   e8 e6 ff ff ff          call   8048427 <B>
 8048441:   e8 c6 ff ff ff          call   804840c <A>
 8048446:   b8 00 00 00 00          mov    eax,0x0
 804844b:   c9                      leave  
 804844c:   c3                      ret    
 804844d:   66 90                   xchg   ax,ax
 804844f:   90                      nop
  • 41
    "they well use the same space" - that's incorrect. They might. Or they might not. And you can't rely on this either way.
    – Mat
    Commented Oct 24, 2013 at 7:06
  • 17
    i wonder what use of this has as an exercise, if one would use this in production code one would get shot.
    – AndersK
    Commented Oct 24, 2013 at 7:35
  • 12
    @claptrap Maybe to learn how the call stack works and understand what the computer is doing under the hood? People are taking this way too seriously. Commented Oct 24, 2013 at 7:38
  • 9
    @claptrap Again, it's a learning exercise. The "hoops you have to jump through" all make sense if you understand what is going on at the assembly level. I seriously doubt the OP has any intent of using something like this in a "real" program (if he does, he should be kicked!) Commented Oct 24, 2013 at 7:43
  • 12
    The example is misleading to the unsuspecting, because the two local variables have the same name; but this is irrelevant to what's going on: Only the number and type of variables matters. Different names should work exactly the same.
    – alexis
    Commented Oct 24, 2013 at 13:50

5 Answers 5


Yes, yes, this is undefined behavior, because you're using the variable uninitialized1.

However, on the x86 architecture2, this experiment should work. The value isn't "erased" from the stack, and since it's not initialized in B(), that same value should still be there, provided the stack frames are identical.

I'd venture to guess that, since int a is not used inside of void B(), the compiler optimized that code out, and a 5 was never written to that location on the stack. Try adding a printf in B() as well - it just may work.

Also, compiler flags - namely optimization level - will likely affect this experiment as well. Try disabling optimizations by passing -O0 to gcc.

Edit: I just compiled your code with gcc -O0 (64-bit), and indeed, the program prints 5, as one familiar with the call stack would expect. In fact, it worked even without -O0. A 32-bit build may behave differently.

Disclaimer: Don't ever, ever use something like this in "real" code!

1 - There's a debate going on below about whether or not this is officially "UB", or just unpredictable.

2 - Also x64, and probably every other architecture that uses a call stack (at least ones with an MMU)

Let's take a look at a reason why it didn't work. This is best seen in 32 bit, so I will compile with -m32.

$ gcc --version
gcc (GCC) 4.7.2 20120921 (Red Hat 4.7.2-2)

I compiled with $ gcc -m32 -O0 test.c (Optimizations disabled). When I run this, it prints garbage.

Looking at $ objdump -Mintel -d ./a.out:

080483ec <A>:
 80483ec:   55                      push   ebp
 80483ed:   89 e5                   mov    ebp,esp
 80483ef:   83 ec 28                sub    esp,0x28
 80483f2:   8b 45 f4                mov    eax,DWORD PTR [ebp-0xc]
 80483f5:   89 44 24 04             mov    DWORD PTR [esp+0x4],eax
 80483f9:   c7 04 24 c4 84 04 08    mov    DWORD PTR [esp],0x80484c4
 8048400:   e8 cb fe ff ff          call   80482d0 <printf@plt>
 8048405:   c9                      leave  
 8048406:   c3                      ret    

08048407 <B>:
 8048407:   55                      push   ebp
 8048408:   89 e5                   mov    ebp,esp
 804840a:   83 ec 10                sub    esp,0x10
 804840d:   c7 45 fc 05 00 00 00    mov    DWORD PTR [ebp-0x4],0x5
 8048414:   c9                      leave  
 8048415:   c3                      ret    

We see that in B, the compiler reserved 0x10 bytes of stack space, and initialized our int a variable at [ebp-0x4] to 5.

In A however, the compiler placed int a at [ebp-0xc]. So in this case our local variables did not end up at the same place! By adding a printf() call in A as well will cause the stack frames for A and B to be identical, and print 55.

  • 5
    Even if it works once, it will not be reliable on some architectures - an interrupt preamble my blow away everything below the stack pointer at any time. Commented Oct 24, 2013 at 7:36
  • 4
    @JonathonReinhart - one example is any where there is no memory-management unit, no user/lernel mode distictions and so no hardware-switch to a different stack on interrupt. There are probably others where some data has to be pushed onto the interrupted task stack before there is a switch to kernel interrupt stack. Commented Oct 24, 2013 at 11:09
  • 6
    So many up votes for an answer which doesn't even mention "undefined behavior". On top of it, it is also accepted. Commented Oct 24, 2013 at 11:22
  • 25
    Also, it's accepted because it actually answers the question.
    – slebetman
    Commented Oct 24, 2013 at 16:33
  • 8
    @BЈовић Did you watch any of the video? Look, everybody and their brother knows that you shouldn't do this in real code, and it invokes undefined behavior. That's not the point. The point is that a computer is a well-defined, predictable machine. On an x86 box (and probably most other architectures), with a sane compiler and potentially some code/flag massaging, this will work as expected. This code, along with the video is merely a demonstration of how the call stack works. If it bothers you that badly, I suggest you go elsewhere. Some of us curious types like to understand things. Commented Oct 24, 2013 at 22:25

It's undefined behavior. An uninitialized local variable has an indeterminate value, and using it will lead to undefined behavior.

  • 6
    To be more precise, using an unitialized variable of which the address is never taken is undefined behavior. Commented Oct 24, 2013 at 8:27
  • @JensGustedt Nice comment. Do you have anything to say about the “The next example” section of blog.frama-c.com/index.php?post/2013/03/13/… ? Commented Oct 24, 2013 at 9:26
  • @PascalCuoq,this even seems to be an ongoing discussion in the standards committee. There are situations where inspecting memory that you get through a pointer makes sense, even if you can't know whether it is initialized or not. Simply making it undefined in all cases is too restrictive. Commented Oct 24, 2013 at 9:36
  • @JensGustedt: How does taking its address cause using it to have defined behavior: { int uninit; &uninit; printf("%d\n", uninit); } still has undefined behavior. On the other hand, you can treat any object as an array of unsigned char; is that what you had in mind? Commented Oct 28, 2013 at 14:49
  • @KeithThompson, no it is the other way round. Having a variable such that its address is never taken and it is not initialized leads to UB. Reading an indeterminate value by itself is not undefined behavior, the contents is just unpredictable. From p2: If the lvalue designates an object of automatic storage duration that could have been declared with the register storage class (never had its address taken), and that object is uninitialized (not declared with an initializer and no assignment to it has been performed prior to use), the behavior is undefined. Commented Oct 28, 2013 at 20:01

One important thing to remember - don't ever rely on something like that and never use this in real code! It's just an interesting thing(which even isn't always true), not a feature or something like that. Imagine yourself trying to find bug produced by that kind of "feature" - nightmare.

Btw. - C and C++ are full of that kind of "features", here is GREAT slideshow about it: http://www.slideshare.net/olvemaudal/deep-c So if you want to see more similar "features", understand what's under the hood and how it's working just watch this slideshow - you won't regret and i'm sure that even most of experienced c/c++ programmers can learn a lot from this.


In the function A, the variable a is not initialized, printing its value leads to undefined behavior.

In some compiler, the variable a in A and a in B are in the same address, so it may print 5, but again, you can't rely on undefined behavior.

  • 1
    The tutorial is 100% right, but whether the results on the original posters machine will be the same depends on the assembly generated by the compiler. As @JonathonReinhart pointed out the call to B()` may be have been optimized away. Commented Oct 24, 2013 at 7:19
  • 1
    I have a problem with the "that tutorial is wrong" verbiage. Did you actually go watch the tutorial? It's not trying to teach you how to do crazy thing like this, but to demonstrate how the call stack works. In that case, the tutorial is completely correct. Commented Oct 24, 2013 at 7:19
  • @JonathonReinhart I didn't watch the tutorial, thought this example was from the tutorial, I'll remove this part.
    – Yu Hao
    Commented Oct 24, 2013 at 7:23
  • @LloydCrawley I've removed the part about the tutorial. I know it's about stack architecture, that's what I meant by they are in the same address when it did print 5, but apparently Jonathon Reinhart has a much much better explanation.
    – Yu Hao
    Commented Oct 24, 2013 at 7:53

Compile your code with gcc -Wall filename.c You will see these warnings.

In function 'B':
11:9: warning: variable 'a' set but not used [-Wunused-but-set-variable]

In function 'A':
6:11: warning: 'a' is used uninitialized in this function [-Wuninitialized]  

In c Printing uninitialized variable Leads to Undefined behavior.

Section 6.7.8 Initialization of C99 standard says

If an object that has automatic storage duration is not initialized explicitly, its value is indeterminate. If an object that has static storage duration is not initialized explicitly, then:

— if it has pointer type, it is initialized to a null pointer;
— if it has arithmetic type, it is initialized to (positive or unsigned) zero;
— if it is an aggregate, every member is initialized (recursively) according to these rules;
— if it is a union, the first named member is initialized (recursively) according to these rules.


As @Jonathon Reinhart If you disable optimization by Using -O flag gcc-O0 then you might get output 5.

But this is not at all good idea , never ever use this in production code.

-Wuninitialized this is one of the valuable warning You should consider this one You should not either disable or skip this warning that leads huge damage in production like causing crashes in while running daemons.


Deep C slides explained Why result is 5/garbage.Adding this information from those slides with minor modifications to make this answer little more effective.

Case 1: without optimization

$ gcc -O0 file.c && ./a.out  

Perhaps this compiler has a pool of named variables that it reuses. Eg variable a was used and released in B(), then when A() needs an integer names a it will get the variable will get the same memory location. If you rename the variable in B() to, say b, then I don’t think you will get 5.

Case 2: with optimization

A lot of things might happen when the optimizer kicks in. In this case I would guess that the call to B() can be skipped as it does not have any side effects. Also, I would not be surprised if the A() is inlined in main(), ie no function call. (But since A () has linker visibility the object code for the function must still be created just in case another object file wants to link with the function). Anyway, I suspect the value printed will be something else if you optimize the code.

gcc -O file.c && ./a.out


  • 1
    Your logic in Edit 2, Case 1 is completely incorrect. That is not at all how it works. The name of the local variable means absolutely nothing. Commented Oct 30, 2013 at 6:21
  • @JonathonReinhart As mentioned in answer I added this from deepc slides, please explain on which basis it is incorrect.
    – Gangadhar
    Commented Oct 30, 2013 at 8:15
  • 3
    There isn't any association between stack space and variable names. The example relies on the fact that conceptually the stack frame in the second function call will simply overlay the stack frame of the second function call. It doesn't matter what the names are, as long as both method signatures are the same, the same thing might happen. As others have pointed out, if it were in an embedded system and a hardware interrupt was serviced between the calls to A() and B(), the stack would contain random values. Old tools like Code Guard for Borland allowed writing zeros to stack before each call.
    – Dan Haynes
    Commented Oct 30, 2013 at 13:56
  • @DanHaynes Your comment convinces me.stack frame in the second function call may overlay the stack frame of the First function call as far as the variable type and function prototype same.Yes i too agree for there is nothing to do with variable names.
    – Gangadhar
    Commented Oct 30, 2013 at 18:55

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