3

I'm studying for a C++/OOP exam and am a little confused with this question on my practice test.

What is the output of the following code snippet?

int *list = new int[5];
int *ptr;
for (int i = 0; i < 5; i ++)
list [ i] = i+ 1;
ptr = list;
delete [ ] list;
cout << *ptr
  1. 1
  2. Address of list
  3. Address of ptr
  4. Error – ptr references memory that no longer belongs to the program

I found the output, which is -17891602, but am I correct in assuming this is just a reference to memory that no longer belongs to the program? Because I'm not necessarily getting an error.

It's been a while since I worked with pointers, so I'm getting a but twisted up trying to follow what the code is actually doing. (I know it's simple compared to some stuff you guys are working on, but I'm just getting started learning this stuff :) )

4
  • 5
    It's undefined behaviour. All of those answers are correct. – chris Aug 27 '14 at 1:40
  • 1
    The program exhibits undefined behavior. Any outcome whatsoever is correct. – Igor Tandetnik Aug 27 '14 at 1:41
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    @chris et al, all of those answers (and all other possible answers, including no answer at all) are both correct and incorrect. Sorry, I feel like a pedant today :-) – paxdiablo Aug 27 '14 at 1:45
  • Hmmm... Now I'm even more confused. – arsis-dev Aug 27 '14 at 1:47
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The output could be anything (including -17891602) since you're invoking undefined behaviour by dereferencing a pointer that has had its backing memory deallocated.

The relevant part of the standard is C++11 3.7.4.2 Deallocation functions /4 (my bold):

If the argument given to a deallocation function in the standard library is a pointer that is not the null pointer value, the deallocation function shall deallocate the storage referenced by the pointer, rendering invalid all pointers referring to any part of the deallocated storage. The effect of using an invalid pointer value (including passing it to a deallocation function) is undefined.

On my system, the following program (modelled on your snippet):

#include <iostream>

int main (void) {
    int *list = new int[5];
    int *ptr;
    for (int i = 0; i < 5; i ++)
        list [ i] = i+ 1;
    ptr = list;
    delete [ ] list;
    std::cout << *ptr;
    return 0;
}

outputs 1 but it is by no means required to.

The correct answer to your question is most likely 4, though that's not technically the output (you may not see the "error" string sent to the output stream) - it is, however, the result of executing the code.

0
2

I wasn't going to weight in on this, but HostileFork's answer (which I +1ed) digs in while missing a couple points - too much to comment on easily, so here I am...

Firstly the question:

What is the output of the following code snippet?

For the code given, the output may be anything or nothing, which is not one of the answers. Still, the intended answer is obviously 4:

Error – ptr references memory that no longer belongs to the program

That said:

  • the memory probably still belongs to the program/process (most C++ implementations don't release memory used to satisfy small memory allocations to the OS until program termination), but it's no longer "owned" by the application-level code you've listed, as delete[] returns ownership to the memory allocation library

  • the problem is not just what ptr references, but specifically that ptr is being dereferenced while pointing to released memory

Summarily, the question is poorly worded, but the intent behind it is fairly clear.

I won't repeat the explanation of undefined behaviour that addresses your "Because I'm not necessarily getting an error." observation, as HostileFork's answer does that well.

Still, computer programs don't tend to go out of their way to do weird things arbitrarily, even when the compiler's not obliged by the C++ Standard to provide any particular behaviour, and in this particular case the observation I made above that the memory's likely still owned by the program, combined with noticing that the value of *ptr before delete[] list; executed must have been 1, leads to the question...

Why did you see -17891602 and not 1?

On a hunch I converted it to unsigned 32 bit hexadecimal (as one does): the value's then FEEEFEEE. Wikipedia says of this "magic number":

Used by Microsoft's debug HeapFree() to mark freed heap memory.

So, Microsoft's delete[] function triggered overwriting of the five int locations with 0xFEEEFEEE, intended to make it easier for you - the programmer - to see you had undefined behaviour. As overwriting the memory takes time while the programm is running, and is only helpful if the program's actually broken anyway which you'll hopefully realise and fix before making and distributing a "release" build, this FEEEFEEE-fill behaviour is only done in MS's "debug" builds. Other compilers or malloc libraries often offer similar behaviour enabled by compiler flags / environment variables etc..

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    Reciprocating +1. I also +1'd the question after finding it initially at -1, because...well maybe I'm some kind of bleeding-heart-programmer but...I think that the world is actually full of enough bad information and the Internet Geeks can push back. This is a good example. "You said X. But people on the Internet told me Y..." Hence I campaign for less beatdown, more clearchannel, refine the process. as Daft Punk says – HostileFork says dont trust SE Aug 27 '14 at 4:43
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The person writing that question either doesn't understand or wrote it poorly. It could be fixed by inserting one word on each line:

  1. Definitely 1
  2. Definitely the Address of list
  3. Definitely the Address of ptr
  4. Programmer Error – ptr references memory that no longer belongs to the program

The issue touches upon something called "Undefined Behavior", which you can read about here:

https://softwareengineering.stackexchange.com/questions/99692/philosophy-behind-undefined-behavior

That lays out some of the reasons why--for instance--the compiler has not given you a "compile-time error" or "run-time exception". It is a mistake that in the general case may be impossible to detect a priori, and that checking at run-time would add undesirable overhead.

1
  • I see. Very interesting :) TYVM – arsis-dev Aug 27 '14 at 1:56

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