What does it mean to create a
shared_ptr to an object? It means that the holder of the
shared_ptr now assumes ownership over the object. Ownership meaning that the object will be deleted when he so desires. When the holder of the
shared_ptr destroys its
shared_ptr, that will cause the object to potentially be destroyed, assuming that there are no other
shared_ptrs to that object.
shared_ptr is a member of a class, that means that the lifetime of the object pointed to by the
shared_ptr is at least as long as the object that the
shared_ptr is a member of. When a
shared_ptr is on the stack, this means that the lifetime of the object that the
shared_ptr is pointing to will be at least as long as the scope it was created in. Once the object falls off the stack, it may be deleted.
The only time you should ever take a pointer and wrap it into a
shared_ptr is when you are allocating the object initially. Why? Because an object does not know whether it is in a
shared_ptr or not. It can't know. This means that the person who creates the original
shared_ptr now has the responsibility to pass it around to other people who need to share ownership of that memory. The only way shared ownership works is through the copy constructor of
shared_ptr. For example:
shared_ptr<int> p1 = new int(12);
shared_ptr<int> p2 = p1.get();
shared_ptr<int> p3 = p1;
The copy constructor of
shared_ptr creates shared ownership between
p3. Note that
p2 does not share ownership with
p1. They both think they have ownership over the same memory, but that's not the same as sharing it. Because they both think that they have unique ownership of it.
Therefore, when the three pointers are destroyed, the following will happen. First,
p3 will be destroyed. But since p3 and p1 share ownership of the integer, the integer will not be destroyed yet. Next,
p2 will be destroyed. Since it thinks that it is the only holder of the integer, it will then destroy it.
At this point,
p1 is pointing to deleted memory. When
p1 is destroyed, it thinks that it is the only holder of the integer, so it will then destroy it. This is bad, since it was already destroyed.
Your problem is this. You are inside an instance of a class. And you need to call some functions of yours that take a
shared_ptr. But all you have is
this, which is a regular pointer. What do you do?
You're going to get some examples that suggest
enable_shared_from_this. But consider a more relevant question: "why do those functions take a
shared_ptr as an argument?"
The type of pointer a function takes is indicative of what that function does with its argument. If a function takes a
shared_ptr, that means that it needs to own the pointer. It needs to take shared ownership of the memory. So, look at your code and ask whether those functions truly need to take ownership of the memory. Are they storing the
shared_ptr somewhere long-term (ie: in an object), or are they just using them for the duration of the function call?
If it's the latter, then the functions should take a naked pointer, not a
shared_ptr. That way, they cannot claim ownership. Your interface is then self-documenting: the pointer type explains ownership.
However, it is possible that you could be calling functions that truly do need to take shared ownership. Then you need to use
enable_shared_from_this. First, your class needs to be derived from
enable_shared_from_this. Then, in the function:
//some operation with classNamePtr
Note that there is a cost here.
enable_shared_from_this puts a
boost::weak_ptr in the class. But there is no virtual overhead or somesuch; it doesn't make the class virtual.
enable_shared_from_this is a template, so you have to declare it like this:
class ClassName : public boost::enable_shared_from_this<ClassName>