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I am currently using Boehm Garbage Collector for a large application in C++. While it works, it seems to me that the GC is overkill for my purpose (I do not like having this as a dependency and I have to continually make allowances and think about the GC in everything I do so as to not step on its toes). I would like to find a better solution that is more suited to my needs, rather than a blanket solution that happens to cover it.

In my situation I have one specific class (and everything that inherits from that class) that I want to "collect". I do not need general garbage collection, in all situations except for this particular class I can easily manage my own memory.

Before I started using the GC, I used reference counting, but reference cycles and the frequent updates made this a less than ideal solution.

Is there a better way for me to keep track of this class? One that does not involve additional library dependancies like boost.

Edit: It is probably best if I give a rundown on the potential lifespan of my object(s).

A function creates a new instance of my class and may (or may not) use it. Regardless, it passes this new instance back to the caller as a return value. The caller may (or may not) use it as well, and again it passes it back up the stack, eventually getting to the top level function which just lets the pointer fade into oblivion.

I cannot just delete the pointer in the top level, because part of the "possible use", involves passing the pointer to other functions which may (or may not) store the pointer for use somewhere else, at some future time.

I hope this better illustrates the problem that I am trying to solve. I currently solve it with Boehm Garbage Collector, but would like simpler, non dependency involving, solution if possible.

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If you want GC, why are you using C++? Switch to Java or C# – SJuan76 Nov 10 '13 at 18:54
Why does std::shared_ptr and std::weak_ptr to break cycles not work? – OmnipotentEntity Nov 10 '13 at 18:56
C++ depends on you to destroy all the objects once they become unreferenced. Make a static class and keep there a list of references and counters. – Fèlix Galindo Allué Nov 10 '13 at 18:58
@SJuan76 I do not want GC, if you read my post, the whole point is to do away with GC in all but one specific instance where its not possible for me to know the lifespan of the object. Second, Java and C# are not just "C++ with GC" so your solution is a non-starter. – latreides Nov 10 '13 at 18:58
@OmnipotentEntity - C++ does not have garbage collection built into the standard library. However, there are some hooks to make it easier to write garbage-collected code. – Pete Becker Nov 10 '13 at 19:10

In the Embedded Systems world, or programs that are real-time event critical, garbage collection is frowned upon. The point of using dynamic memory is bad.

With dynamic memory allocation, fragmentation occurs. A Garbage Collector is used to periodically arrange memory to reduce the fragmentation, such as combining sequential freed blocks. The primary issue is when to perform this defragmentation or running of the GC.

Some suggested alternatives:

Redesign your system to avoid dynamic memory allocation.
Allocate static buffers and use them. For example in an RTOS system, preallocate space for messages, rather than dynamically allocating them.

Use the Stack, not the Heap. Use the stack for dynamically allocated variables, if possible. This is not a good idea if variables need a lifetime beyond the function execution.

Place limits on variable sized data.
Along with static buffers, place limits on variable length data or incoming data of unknown size. This may mean that the incoming data must be paused or multiple buffering when the input cannot be stopped.

Create your own memory allocator.
Create many memory pools that allocate different sized blocks. This will reduce fragmentation. For example, for small blocks, maybe a bitset could be used to determine which bytes are in use and which are available. Maybe another pool for 64 byte blocks is necessary. All depends on your system's needs.

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Avoiding dynamic memory allocation would cause significant performance hits as things are copied numerous times. Using the stack is not a solution as there is no way to know what the lifetime of the object will be. Your other solutions would not free me from the need to manage the object manually. I appreciate the suggestions but these will not work for me. – latreides Nov 10 '13 at 19:16

If you really just need special handling for the memory allocations associated with a single class, then you should look at overloading the new operator for that class.

class MyClass
  void *operator new(size_t);
  void operator delete(void *);

You can implement these operators to do whatever you need to track the memory: allocate it from a special pool, place references on a linked list for tracking, etc.

void* MyClass::operator new(size_t size)
    void *p = my_allocator(size);  // e.g., instead of malloc()
    // place p on a linked list, etc.
    return p;

void MyClass::operator delete(void *p)
    // remove p from list...

You can then write external code that can walk through the list you are keeping to inspect every currently-allocated instance of MyClass, GC'ing instances as appropriate for your situation.

share|improve this answer
The problem here is that you assume that I am keeping some list of every allocated object that I could walk through. The number of allocated objects is limited only to the amount of memory on the target platform, so (although unlikely) it could theoretically contain hundreds of thousands of entries (even more if I wait to delete for some arbitrary time or trigger), which would not only be a memory waste, but it would be non-trivial to walk through the list as well. – latreides Nov 10 '13 at 20:06
@latreides - I'm actually assuming that you are not currently keeping a list of the allocated objects. That's the point of overloading new and delete, so that you can easily do so without touching any code outside of the object itself. The overhead of maintaining a list (or some other data structure) of these allocated objects is minimal compared to their overall heap size (and in any case, the runtime heap is already doing this whether you realize it or not). If you have so many that you need a more efficient data structure to walk them, you can use anything you wish: hash table, etc. – Myk Willis Nov 10 '13 at 20:11
I do not think you understand my original question. The question is about a better mechanism to determine if a pointer should be deleted, a point that your example code does not solve. Maintaining a massive list (no matter the data structure) and walking such a massive list to check for things that need to be deleted, is a huge performance hit, not one that I am willing to take no matter what mechanism is in play to determine if the pointer should be deleted. I appreciate the attempt, and if I was wondering about a good way to do reference counting, your example would be a good start. – latreides Nov 10 '13 at 20:39
fair enough - good luck! – Myk Willis Nov 10 '13 at 20:40

With memory, you should always try and have clear ownership and knowledge of lifetime. Lifetime determines where you take the memory from (as do other factors), ie stack for scope lived, pool for reused, etc. Ownership will tell you when and if to free memory. In your case, the GC has the ownership and makes the decision when to free. With ref counting, the wrapper class does this logic. Unclear ownership leads to hard to maintain code if manual memory management is used. You must avoid use after free, double frees, and memory leaking.

To solve your problem, figure out who should keep ownership. This will dictate the algoritm to use. GC and ref counting are popular choices, but there are infinetly many. If ownership is unclear, give it to a 3rd party whose job it is to keep track of it. If ownership is shared, make sure all parties are aware of it perhaps by enforcing it via specialized classes. This can also be enforced by simple convention, ie objects of type foo should never keep ptrs of type bar internally as they do not own them and if they do they cannot assume them always valid and might have to check for validity first. Etc.

If you find this hard to determine, it could be a sign that the code is very complex. Could it be made in a more simple manner?

Understanding how your memory is used and accessed is key to writing clean code for maintenance and performance optimizations. This is true regardless of language used.

Best of luck.

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