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I have the following code.

int * foo()
{
    int a = 5;
    return &a;
}

int main()
{
    int* p = foo();
    cout << *p;
    *p = 8;
    cout << *p;
}

And the code is just running with no runtime exceptions!

The output was 5 8

How can it be? Isn't the memory of a local variable inaccessible outside its function?

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locked by Robert Harvey Jun 26 '11 at 5:28

5  
this won't even compile as is; if you fix the nonforming business, gcc will still warn address of local variable ‘a’ returned; valgrind shows Invalid write of size 4 [...] Address 0xbefd7114 is just below the stack ptr –  sehe Jun 22 '11 at 14:34
15  
@Serge: Back in my youth I once worked on some kinda tricky zero-ring code that ran on the Netware operating system that involved cleverly moving around the stack pointer in a way not exactly sanctioned by the operating system. I'd know when I'd made a mistake because often the stack would end up overlapping the screen memory and I could just watch the bytes get written right onto the display. You can't get away with that sort of thing these days. –  Eric Lippert Jun 23 '11 at 4:23
10  
lol. I needed to read the question and some answers before I even understood where the problem is. Is that actually a question about variable's access scope? You don't even use 'a' outside your function. And that is all there is to it. Throwing around some memory references is a totally different topic from variable scope. –  erikb85 Jun 23 '11 at 6:23
21  
@sbi: Ya think? It makes me sad that a low-quality duplicate question can have so many upvotes just because it's got a great answer on it. A weakness of SO: votes are at least partially a function of views. –  Lightness Races in Orbit Jun 23 '11 at 10:40
9  
@Joel: If the answer here is good, it should be merged into older questions, of which this is a dupe, not the other way around. And this question is indeed a dupe of the other questions proposed here and then some (even though some of the proposed are a better fit than others). Note that I think Eric's answer is good. (In fact, I flagged this question for merging the answers into one of the older questions in order to salvage the older questions.) –  sbi Jun 23 '11 at 15:20

17 Answers 17

up vote 3361 down vote accepted

How can it be? Isn't the memory of a local variable inaccessible outside its function?

You rent a hotel room. You put a book in the top drawer of the bedside table and go to sleep. You check out the next morning, but "forget" to give back your key. You steal the key!

A week later, you return to the hotel, do not check in, sneak into your old room with your stolen key, and look in the drawer. Your book is still there. Astonishing!

How can that be? Aren't the contents of a hotel room drawer inaccessible if you haven't rented the room?

Well, obviously that scenario can happen in the real world no problem. There is no mysterious force that causes your book to disappear when you are no longer authorized to be in the room. Nor is there a mysterious force that prevents you from entering a room with a stolen key.

The hotel management is not required to remove your book. You didn't make a contract with them that said that if you leave stuff behind, they'll shred it for you. If you illegally re-enter your room with a stolen key to get it back, the hotel security staff is not required to catch you sneaking in. You didn't make a contract with them that said "if I try to sneak back into my room later, you are required to stop me." Rather, you signed a contract with them that said "I promise not to sneak back into my room later", a contract which you broke.

In this situation anything can happen. The book can be there -- you got lucky. Someone else's book can be there and yours could be in the hotel's furnace. Someone could be there right when you come in, tearing your book to pieces. The hotel could have removed the table and book entirely and replaced it with a wardrobe. The entire hotel could be just about to be torn down and replaced with a football stadium, and you are going to die in an explosion while you are sneaking around.

You don't know what is going to happen; when you checked out of the hotel and stole a key to illegally use later, you gave up the right to live in a predictable, safe world because you chose to break the rules of the system.

C++ is not a safe language. It will cheerfully allow you to break the rules of the system. If you try to do something illegal and foolish like going back into a room you're not authorized to be in and rummaging through a desk that might not even be there anymore, C++ is not going to stop you. Safer languages than C++ solve this problem by restricting your power -- by having much stricter control over keys, for example.

UPDATE

Holy goodness, this answer is getting a lot of attention. (I'm not sure why -- I considered it to be just a "fun" little analogy, but whatever.)

I thought it might be germane to update this a bit with a few more technical thoughts.

Compilers are in the business of generating code which manages the storage of the data manipulated by that program. There are lots of different ways of generating code to manage memory, but over time two basic techniques have become entrenched.

The first is to have some sort of "long lived" storage area where the "lifetime" of each byte in the storage -- that is, the period of time when it is validly associated with some program variable -- cannot be easily predicted ahead of time. The compiler generates calls into a "heap manager" that knows how to dynamically allocate storage when it is needed and reclaim it when it is no longer needed.

The second is to have some sort of "short lived" storage area where the lifetime of each byte in the storage is well known, and, in particular, lifetimes of storages follow a "nesting" pattern. That is, the allocation of the longest-lived of the short-lived variables strictly overlaps the allocations of shorter-lived variables that come after it.

Local variables follow the latter pattern; when a method is entered, its local variables come alive. When that method calls another method, the new method's local variables come alive. They'll be dead before the first method's local variables are dead. The relative order of the beginnings and endings of lifetimes of storages associated with local variables can be worked out ahead of time.

For this reason, local variables are usually generated as storage on a "stack" data structure, because a stack has the property that the first thing pushed on it is going to be the last thing popped off.

It's like the hotel decides to only rent out rooms sequentially, and you can't check out until everyone with a room number higher than you has checked out.

So let's think about the stack. In many operating systems you get one stack per thread and the stack is allocated to be a certain fixed size. When you call a method, stuff is pushed onto the stack. If you then pass a pointer to the stack back out of your method, as the original poster does here, that's just a pointer to the middle of some entirely valid million-byte memory block. In our analogy, you check out of the hotel; when you do, you just checked out of the highest-numbered occupied room. If no one else checks in after you, and you go back to your room illegally, all your stuff is guaranteed to still be there in this particular hotel.

We use stacks for temporary stores because they are really cheap and easy. An implementation of C++ is not required to use a stack for storage of locals; it could use the heap. It doesn't, because that would make the program slower.

An implementation of C++ is not required to leave the garbage you left on the stack untouched so that you can come back for it later illegally; it is perfectly legal for the compiler to generate code that turns back to zero everything in the "room" that you just vacated. It doesn't because again, that would be expensive.

An implementation of C++ is not required to ensure that when the stack logically shrinks, the addresses that used to be valid are still mapped into memory. The implementation is allowed to tell the operating system "we're done using this page of stack now. Until I say otherwise, issue an exception that destroys the process if anyone touches the previously-valid stack page". Again, implementations do not actually do that because it is slow and unnecessary.

Instead, implementations let you make mistakes and get away with it. Most of the time. Until one day something truly awful goes wrong and the process explodes.

This is problematic. There are a lot of rules and it is very easy to break them accidentally. I certainly have many times. And worse, the problem often only surfaces when memory is detected to be corrupt billions of nanoseconds after the corruption happened, when it is very hard to figure out who messed it up.

More memory-safe languages solve this problem by restricting your power. In "normal" C# there simply is no way to take the address of a local and return it or store it for later. You can take the address of a local, but the language is cleverly designed so that it is impossible to use it after the lifetime of the local ends. In order to take the address of a local and pass it back, you have to put the compiler in a special "unsafe" mode, and put the word "unsafe" in your program, to call attention to the fact that you are probably doing something dangerous that could be breaking the rules.

For further reading:

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498  
That's the best analogy for pointers I've ever seen. –  Maxpm Jun 23 '11 at 0:18
258  
I won't ever look at a Gideon's bible the same way... –  MPelletier Jun 23 '11 at 3:04
351  
I'd have stolen a lot fewer hotel-room keys had I known each would increase my likelihood of dying in an unfinished football stadium. –  Dan J Jun 23 '11 at 3:16
1319  
Somewhere there is a Hotel Manager explaining the problem of disappearing towels to an engineer using a memory leak analogy. –  leebriggs Jun 23 '11 at 6:55
328  
@cyberguijarro: That C++ is not memory safe is simply a fact. It's not "bashing" anything. Had I said, for example, "C++ is a horrid mishmash of under-specified, overly-complex features piled on top of a brittle, dangerous memory model and I am thankful every day I no longer work in it for my own sanity", that would be bashing C++. Pointing out that it's not memory safe is explaining why the original poster is seeing this issue; it's answering the question, not editorializing. –  Eric Lippert Jun 23 '11 at 7:27

What you're doing here is simply reading and writing to memory that used to be the address of a. Now that you're outside of foo, it's just a pointer to some random memory area. It just so happens that in your example, that memory area does exist and nothing else is using it at the moment. You don't break anything by continuing to use it, and nothing else has overwritten it yet. Therefore, the 5 is still there. In a real program, that memory would be re-used almost immediately and you'd break something by doing this (though the symptoms may not appear until much later!)

When you return from foo, you tell the OS that you're no longer using that memory and it can be reassigned to something else. If you're lucky and it never does get reassigned, and the OS doesn't catch you using it again, then you'll get away with the lie. Chances are though you'll end up writing over whatever else ends up with that address.

Now if you're wondering why the compiler doesn't complain, it's probably because foo got eliminated by optimization. It usually will warn you about this sort of thing. C assumes you know what you're doing though, and technically you haven't violated scope here (there's no reference to a itself outside of foo), only memory access rules, which only triggers a warning rather than an error.

In short: this won't usually work, but sometimes will by chance.

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39  
Up vote for the only thought-out answer to the question. All the others give analogy completely out of context. –  Chad Jun 23 '11 at 9:33

Because the storage space wasn't stomped on just yet. Don't count on that behavior.

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4  
I like Eric's answer a lot, obviously, and I'm not just being egregious for the sake of it, but this answer has the virtue of brevity and correctness. –  Rob Kent Jul 5 '12 at 15:43

It's like skipping the red light; you may get to the other side, or you may get hit by a truck!

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In C++, you can access any address, but it doesn't mean you should. The address you are accessing is no longer valid. It works because nothing else scrambled the memory after foo returned, but it could crash under many circumstances. Try analyzing your program with Valgrind, or even just compiling it optimized, and see...

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You never throw a C++ exception by accessing invalid memory. You are just giving an example of the general idea of referencing an arbitrary memory location. I could do the same like this:

unsigned int q = 123456;

*(double*)(q) = 1.2;

Here I am simply treating 123456 as the address of a double and write to it. Any number of things could happen: 1) q might in fact genuinely be a valid address of a double, e.g. double p; q = &p;. 2) q might point somewhere inside allocated memory and I just overwrite 8 bytes in there. 3) q points outside allocated memory and the operating system's memory manager sends a segmentation fault signal to my program, causing the runtime to terminate it. 4) You win the lottery.

The way you set it up it is a bit more reasonable that the returned address points into a valid area of memory, as it will probably just be a little further down the stack, but it is still an invalid location that you cannot access in a deterministic fashion.

Nobody will automatically check the semantic validity of memory addresses like that for you during normal program execution. However, a memory debugger such as valgrind will happily do this, so you should run your program through it and witness the errors.

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A little addition to all the answers:

if you do something like that:

#include<stdio.h>
#include <stdlib.h>
int * foo(){
    int a = 5;
    return &a;
}
void boo(){
    int a = 7;

}
int main(){
    int * p = foo();
    boo();
    printf("%d\n",*p);
}

the output probably will be: 7

That is because after returning from foo() the stack is freed and then reused by boo(). If you deassemble the executable you will see it clearly.

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Simple, but great example to understand the underlying stack theory.Just one test addition, declaring "int a = 5;" in foo() as "static int a = 5;" can be used to understand the scope and life time of a static variable. –  ppu.spu May 7 '13 at 19:02
1  
-1 "for will probably be 7". The compiler might enregister a in boo. It might remove it because it's unnecessary. There is a good chance that *p will not be 5, but that doesn't mean that there is any particularly good reason why it will probably be 7. –  Matt Oct 9 '13 at 19:16
    
+1 as it explains the situation in question while stating it's not guaranteed. –  rahmanisback Jun 1 at 11:47

Did you compile you program with the optimiser enabled ?

The foo() function is quite simple and might have been inlined/replaced in the resulting code.

But I aggree with Mark B that the resulting behavior is undefined.

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That's my bet. Optimizer dumped the function call. –  Erik Aronesty Jun 22 '11 at 17:34
4  
That is not necessary. Since no new function is called after foo(), the functions local stack frame is simply not yet overwritten. Add another function invocation after foo(), and the 5 will be changed... –  Tomas Jun 23 '11 at 11:02

Your problem has nothing to do with scope. In the code you show, the function main does not see the names in the function foo, so you can't access a in foo directly with this name outside foo.

The problem you are having is why the program doesn't signal an error when referencing illegal memory. This is because C++ standards does not specify a very clear boundary between illegal memory and legal memory. Referencing something in popped out stack sometimes causes error and sometimes not. It depends. Don't count on this behavior. Assume it will always result in error when you program, but assume it will never signal error when you debug.

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I recall from an old copy of Turbo C Programming for the IBM, which I used to play around with some way back when, how directly manipulating the graphics memory, and the layout of the IBM's text mode video memory, was described in great detail. Of course then, the system that the code ran on clearly defined what writing to those addresses meant, so as long as you didn't worry about portability to other systems, everything was fine. IIRC, pointers to void were a common theme in that book. –  Michael Kjörling Jun 23 '11 at 8:05
    
@Michael Kjörling: Sure! People like to do some dirty work once in a while ;) –  Chang Peng Jun 23 '11 at 8:47

In typical compiler implementations, you can think of the code as "print out the value of the memory block with adress that used to be occupied by a". Also, if you add a new function invocation to a function that constains a local int it's a good chance that the value of a (or the memory address that a used to point to) changes. This happens because the stack will be overwritten with a new frame containing different data.

However, this is undefined behaviour and you should not rely on it to work!

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2  
"print out the value of the memory block with address that used to be occupied by a" isn't quite right. This makes it sound like his code has some well-defined meaning, which is not the case. You are right that this is probably how most compilers would implement it, though. –  Brennan Vincent Jun 22 '11 at 21:23
    
@Brennan Vincent: you're right, edited the answer to reflect what you've said. –  larsm Jun 23 '11 at 8:03

It works because the stack has not been altered (yet) since a was put there. Call a few other functions (which are also calling other functions) before accessing a again and you will probably not be so lucky anymore... ;-)

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That's classic undefined behaviour that's been discussed here not two days ago -- search around the site for a bit. In a nutshell, you were lucky, but anything could have happened and your code is making invalid access to memory.

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It can, because a is a variable allocated temporarily for the lifetime of its scope (foo function). After you return from foo the memory is free and can be overwritten.

What you're doing is described as undefined behavior. The result cannot be predicted.

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You are just returning a memory address, it's allowed but probably an error.

Yes if you try to dereference that memory address you will have undefined behavior.

int * ref () {

 int tmp = 100;
 return &tmp;
}

int main () {

 int * a = ref();
 //Up until this point there is defined results
 //You can even print the address returned
 // but yes probably a bug

 cout << *a << endl;//Undefined results
}
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I disagree: There is a problem before the cout. *a points to unallocated (freed) memory. Even if you don't derefence it, it is still dangerous (and likely bogus). –  ereOn May 19 '10 at 7:15
    
@ereOn: I clarified more what I meant by problem, but no it is not dangerous in terms of valid c++ code. But it is dangerous in terms of likely the user made a mistake and will do something bad. Maybe for example you are trying to see how the stack grows, and you only care about the address value and will never dereference it. –  Brian R. Bondy May 19 '10 at 13:02

The things with correct (?) console output can change dramatically if you use ::printf but not cout. You can play around with debugger within below code (tested on x86, 32-bit, MSVisual Studio):

char* foo() 
{
  char buf[10];
  ::strcpy(buf, "TEST”);
  return buf;
}

int main() 
{
  char* s = foo();    //place breakpoint & check 's' varialbe here
  ::printf("%s\n", s); 
}
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You actually invoked undefined behaviour.

Returning the address of a temporary works, but as temporaries are destroyed at the end of a function the results of accessing them will be undefined.

So you did not modify a but rather the memory location where a once was. This difference is very similar to the difference between crashing and not crashing.

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This behavior is undefined, as Alex pointed out--in fact, most compilers will warn against doing this, because it's an easy way to get crashes.

For an example of the kind of spooky behavior you are likely to get, try this sample:

int *a()
{
   int x = 5;
   return &x;
}

void b( int *c )
{
   int y = 29;
   *c = 123;
   cout << "y=" << y << endl;
}

int main()
{
   b( a() );
   return 0;
}

This prints out "y=123", but your results may vary (really!). Your pointer is clobbering other, unrelated local variables.

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protected by Joel Spolsky Jun 23 '11 at 14:36

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