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I'm coding some mission critical code that I have to make sure it's absolutely free of memory leaks. I've wrote a small function that allows me to retrieve the memory usage at runtime and I make measurements before and after executing some code (that should be leak free) to see if memory usage remains on the same level.

While debugging a piece of code that was 'leaking', I finally found the culprit to be a vector container.

The minimal code that reproduces what I'm seeing is the following:

vector<char*>* v = new vector<char*>();
int n = 1024*1024;
while (n--)
{
     v->push_back(new char[256]()); // A
}
for (vector<char*>::iterator it=v->begin() ; it!=v->end() ; ++it )
{
     delete[] (*it);
}
delete v;

If you run that code (disabling compiler optimizations of course, -O0) and put some trap at the end so that the program doesn't exit (like cin.ignore();) you would see that your program should be using around 20Mb or so of memory.

I'd like to understand why does that happen. There's a line I marked with A, where if you allocate a larger char array you would see that the 'remaining' memory at the end is larger too. I wouldn't call this a leak per se beause apparently that memory could be reused if I allocate and fill another STL container, but still I would have expected to have that memory completely freed when the code finishes.

Can someone shed some light on to why is this memory still being used? And how may I 'free' it for real?

Some details about my compiler environment:

Using clang++: Apple LLVM version 6.0 (clang-600.0.51) (based on LLVM 3.5svn)
Target: x86_64-apple-darwin13.3.0
Thread model: posix

Compiling with: g++ -std=c++11 -g -Wall -Wextra -Wpedantic -O0 main.cc -o main.out
  • Why would you want to use vector<char*> instead of vector<vector<char>> !? – Borgleader Dec 7 '14 at 22:04
  • I'm just using that char* to allocate an arbitrary amount of memory. In practice, you could use any kind of type there and you would still observe this behavior. – almosnow Dec 7 '14 at 22:05
  • 3
    You seem to be expecting that the memory manager would actually deallocate the memory from your process just because you freed it, but that's not how it generally works. It's just virtual memory, anyway, so as long as your process is not using it, it doesn't take up any RAM. And, as you said, if you ask for more memory that memory will be reused. – ooga Dec 7 '14 at 22:09
  • @Deduplicator You could try running the code with vector<string>* instead and allocate everything in your preferred way. You would still observe this behavior. – almosnow Dec 7 '14 at 22:10
  • Looking at the memory usage in the system monitor or the like is definitely the wrong way to check for leaks and you'll be hunting for ghosts everywhere. – user1942027 Dec 7 '14 at 22:12
3

First, there is no excuse for dynamically allocating your container in your scenario. Why?

Second, it's a container of char*, and while it is responsible for managing those, you retain full and sole responsibility for whatever they point (or don't point) to!

Consider using vector<char>, unique_ptr<char>, string or something like that as the element-type to let the vector take that task.

Finally, keep in mind that the runtime-system uses its own allocator built on the OS primitives, so allocating memory does not directly translate to a request to the OS, nor does freeing / deleting it immediately return it there.
Doing so would be incredibly inefficient.

If you really want to make sure freed memory is returned to the OS, you have basically two options (which both involve writing your own allocator, or finding and using one someone else built):

  • Replace the replacable global allocation and deallocation functions with your own.
  • Use your own allocator for just those allocations (standard-containers are allocator-aware, which means you can provide your own allocator on a per-container basis).

After you are done, just ask your allocator to release everything back to the OS.

  • Hits all the right points. Not using RAII is insane if you have to guarantee no leaks, and measuring active memory is very flawed when runtime allocator caches are not taken into account. – Puppy Dec 7 '14 at 22:27
  • This is in no way related to RAII. You could try writing your own code and see that you will end up finding the same behavior. Measuring memory could be very flawed, but you guys have no guarantee that I'm doing it right or wrong. I believe I was clear enough when explaining the overall situation/behavior so that these kind of comments wouldn't appear. Anyway, thanks Puppy for the allocator hint, I would try to implement a custom allocator and see if I can get rid of the problem that way. – almosnow Dec 7 '14 at 22:34
  • @almosnow: Yes, you are not directly asking about RAII, and if you reduced your question to what you wanted to actually ask about (missing memory-footprint-reduction after delete), I could remove the first part. It's still invaluable advice, and I would have been justly criticized had I failed to very prominently warn you about that. Still, I'm also answering the question you actually asked. – Deduplicator Dec 7 '14 at 22:38
  • Thanks @Deduplicator, but what I'm asking is why is this memory still being used? (because it may get used in the future, yeah but why and how does STL do that?) and how should I ensure that it gets freed? – almosnow Dec 7 '14 at 22:52
  • As I said, it is freed (back to the runtime-system). And there are excellent reasons the runtime-system does not return it to the operating-system (yet). Added something about how you can force freeing it back to the OS. (And the STL does not retain the memory, the allocator, which is part of the standard-library does. BTW: STL is the wrong term even for the container-part of the standard-library, which is STL-derived.) – Deduplicator Dec 7 '14 at 23:02

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