Class members and explicit stack/heap allocation

I think that you are confusing "stack/heap allocation" and "automatic variable".

Automatic variables are automatically destroyed when going out of context.

Stack allocation is the fact that the memory is allocated on the execution stack. And variable allocated on the stack are automatic variables.

Also, members are automatic variables whose destructors get called when its owner is destroyed. In the case of pointers, they are destroyed but not the underlying object, you have to explicitly call delete. To make sure that the underlying object is destroyed you have to use smart or unique pointers.

To put it another way: variables/members that you have to call delete on, are not automatic variables.

Lastly, member of a class are allocated on the same memory segment of the its owner.

In you code:

• A.m_B is an automatic variable. If A is on the stack so is B and if A is on the heap so is B.
• B.m_i and D.m_i are an automatic variables and will be allocated on the same memory segment of their owner
• The pointer C.m_D is an automatic variable, but the pointed object of type D is not, you have to explicitly call delete on the pointer to delete the underlying object. So, the pointer C.m_D is allocated on the same memory segment, but not the underlying objet. It's cleary allocated by new and will be on the heap.

So:

• Case 1: Everything is on the stack and automatic (ie: destroyed automatically).
• Case 2: myA2 is on the heap and not automatic (you have to delete myA2). Its member m_B2 is an automatic variable that will be destroyed when myA2 is destroyed. Also since myA2 is on the heap, m_B, like any member of a class, is in the same memory space the heap too.
• Case 3: myC1 is on the stack and is an automatic variable, The pointer to m_D is on the stack too, but not the object pointed by m_D which is allocated by new on the heap.
• Case 4: Same as case3 but myC2 is on the heap and is not automatic. So you have to delete myC2 (which will delete m_D).

Your object is a piece of organised memory. Object does not allocate it's members on the stack, it just consists of it's members.

Case 2: the whole object exists in the heap, this means that all it's members lie in the heap.

Case 3: the whole object exists on the stack. The trick is that it's not D class instance who is member of myC1, but pointer-to-B is physically member of myC1. So member of myC1 lies on stack and points to some D instance that lies in the heap.

Case 1: everything on the "stack" (automatic storage). Resources are released as you exit scope.

Case 2: myA2 is on the "heap", so is it's m_B, and you only have to worry about releasing the resources taken up by myA2. it's m_B will be destructed automatically when myA2 is.

Case 3: myC1 is on the stack, it's m_D points to a D on the heap, but the C destructor takes care of deleting it, so as myC1 goes out of scope, all dynamically allocated resources are cleared.

Case 4: myC2 dynamically allocated, to it must be deleted to release resources taken by it. Deleting it will call it's constructor which in turn will take care of it's m_D, as in case 3.

I am not sure about articles, I am sure there are plenty around. But I suggest reading some good C++ books