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The following code compiles and runs fine:

#include <memory>
struct MyTree {
    std::shared_ptr <MyTree> left;
    std::shared_ptr <MyTree> right;
    int val;
    MyTree(
        std::shared_ptr <MyTree> left_,
        std::shared_ptr <MyTree> right_,
        int val_
    ) : left(left_), right(right_), val(val_) {};
};
int main() {
    std::shared_ptr <MyTree> t(
        new MyTree( std::shared_ptr <MyTree>(),
                    std::shared_ptr <MyTree>(),
                    0)
    );  
    for(int i=0;i<10000;i++) {
        t.reset(new MyTree(t,t,0));
    }
}

However, when the for loop is changed from 10000 to 100000, I receive a segfault. Looking at the result in gdb, it looks like the destructors being called as a result of the garbage collection in std::shared_ptr create a backtrace that's thousands deep. As such, I think the segfault is due to running out of room on the stack from the function calls. I've two questions. First, is this a correct assessment of the segfault? Second, if so, is there a good way to manage custom data structures such as trees that need to be garbage collected, but may be extremely large. Thanks.

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6  
There is no garbage collection in C++. –  John Dibling Dec 27 '12 at 15:45
2  
@JohnDibling I am pretty sure the OP understands that automatic GC like in Java and other languages does not exist in C++, I think he means the recursive deallocation that is needed in such a case due to shared_ptr detruction –  Karthik T Dec 27 '12 at 15:48
3  
@JohnDibling: std::shared_ptr does simple reference counting garbage collection. That's what I'm talking about. –  wyer33 Dec 27 '12 at 15:48
3  
@LightnessRacesinOrbit: Not garbage collection. –  John Dibling Dec 27 '12 at 15:50
3  
@aleguna: What cycles? This isn't a doubly-linked list, it's a binary tree. All the pointers are directed in the same direction, which is deeper into the tree, away from the root. –  Ben Voigt Dec 27 '12 at 16:06

4 Answers 4

This isn't usually a problem, because normally you keep a tree balanced and the depth is O(lg N).

You've instead got a weird singly-linked list, with a duplicate copy of every pointer. That's... odd.

A real singly-linked list would be very deep recursion, but might benefit from tail call optimization and not exhaust the stack.

The problem you're having is really quite unique to your mixing of the two data structures. Which has no benefits that I can see.

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how you can prove that this is O(lg N) ? You can't even say how shared_ptr is implemented ? the implementation of a shared_ptr it's not standard ... –  user1824407 Dec 27 '12 at 16:11
    
This is a simplified version of a more complex problem. It was the shortest code that I could come up with that exhibits the problem. Sorry for the oddity. –  wyer33 Dec 27 '12 at 16:12
3  
@user1824407: The depth of a balanced tree has nothing to do with the implementation of std::shared_ptr. –  Ben Voigt Dec 27 '12 at 16:13
    
really ? so the internal management of a shared_ptr is magic ? your CPU will spend no time updating and manipulating the state of a shared_ptr ? –  user1824407 Dec 27 '12 at 16:14
1  
@user1824407: Well, now we get to the implementation of deletion of the tree (which I believe most people understand implicitly). Which is O(f(N)) time complexity but O(f(depth)) space complexity. And those complexity limits can be derived by the fact that each shared_ptr is aware of a limited number of other shared_ptr instances. –  Ben Voigt Dec 27 '12 at 16:20

Your assessment looks totally correct to me. It looks like the recursive calls to delete child subtrees are exceeding yoru stack size. This is unrelated to shared_ptr though as I would expect any recursive algorithms on the data structure to also fail in the same way.

If possible on your platform, the simplest way to deal with the need for large structures like that is simply to increase the size of your stack (for example ulimit) to allow the natural recursive algorithm to function.

If that's not possible you're going to have to traverse the nodes yourself, storing the result of the traversal into a container of some sort so you can chop of subnodes and not require a full depth traversal of the tree structure.

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I think that it's important to note that the definition of a shared_ptr it's templated and its actual implementation is different among compilers and platforms. the words on shared_ptr from the official C++ standard are about functionalities that shared_ptr provides, not about implementation details. –  user1824407 Dec 27 '12 at 16:05
    
@user1824407: You're correct and I think that's part of the problem in this situation. As far as I know, there's nothing in the standard that says that the deallocation will use a recursive algorithm to free the memory. All the same, since that's a possibility and causing the segfault in this case, I need some strategies for compensating. –  wyer33 Dec 27 '12 at 16:14
1  
@wyer33 The standard guarantees the order of destruction. The leaf nodes have to be destructed before the intermediate nodes. Without a parent pointer, it's impossible to do so without storing the list of nodes to be deleted somewhere. A recursive implementation stores the list on the call stack. –  Sjoerd Dec 27 '12 at 16:31
    
@wyer33 Now imagine that the leaf nodes are shared but the intermediate nodes are not (not a real tree, but OP's tree is not a tree either). Or there could be polymorphism: when the destructor is virtual, it is impossible to build that list-of-nodes-to-be-destructed without calling the destructor. –  Sjoerd Dec 27 '12 at 16:34
1  
@wyer33 The actual implementation of std::shared_ptr is implementation dependent, but there are a number of constraints. In particular, it must call the destructor of the object, and if the object contains shared_ptr, then the destructor of the object must call the destructor on those. A single instance of shared_ptr can only handle a single object. So in his case, it must be recursive. In the abstract machine, at least; there's no restriction as to what the compiler can do under the "as if" rule. –  James Kanze Dec 27 '12 at 17:13

This looks to me like a misuse of std::shared_ptr. And some very poor naming: your class MyTree isn't a tree, but simply a node. The tree should be a separate class, and should delete all of the nodes in its destructor.

Having said that, this won't change much with regards to the problem at hand. You're visiting the nodes on the tree recursively (about the only way that makes sense), and if you let the tree get too deep, the stack will overflow, regardless of whether the visiting is implicit (through the destructor calls in std::shared_ptr) or explicit. Creating such trees to begin with makes no sense, since there's no point in creating a tree whose nodes you cannot visit before you start destructing it.

EDIT:

To take into account the discussion of garbage collection in the comments. Using the Boehm collector, or some other garbage collector, will solve the problem of deallocating the elements. But it still won't allow you to visit them before deallocation, so such a tree remains useless. (I think that there are very strong arguments in favor of garbage collection in C++, but this isn't one of them.)

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I think this type of error can reproduced without shared_ptr. This is basically a long recursion call. Ok, I just created and deleted half of the tree but...

struct MyTree {
    MyTree *left;
    int val;
    MyTree()
    {
      left = 0;
    }
    MyTree(MyTree *left_)
     : left(left_) {};

    ~MyTree()
    {
      delete left;
    }
};
int main() {
    MyTree *t = new MyTree();
    for(int i=0;i<100000;i++) {
      t = new MyTree(t);
    }
    delete t;
}

Just add one more zero after 100000 and you got the same error message

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