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I am writing a template of a working class, and this might just be a dumb question, but if I have a template structure (linked list) to hold possibly pointers to objects then how do I know that they are being deleted, or that they where pointers in the first place?

for example: the linkedList will be used in 2 ways in this program

a pointer to an object of class Thing is placed inside a node inside a linkedList

an enum is placed inside a node inside a linkedList

I know that the nodes are being deleted, but how do I know that the thing in the node is a pointer so that it can be deleted as well, and not just be a Null referenced object?

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Are you thinking of making a linked list of different types? –  Xeo Mar 7 '12 at 19:26
To make sure I'm understanding this correctly, you want to have a LinkedList<Blah*> and then be able to push Blah*'s into it and have the LinkedList automatically destruct and free all of objects pointed to by contents of the linked list? This seems like something the class shouldn't be doing. What if you want to keep an object alive, but you've pushed it into the list and the list has been deleted? Maybe you're looking for some kind of smart pointer? (Like the Boost smart pointers.) –  Corbin Mar 7 '12 at 19:28
@Xeo yes, but I one of the types will be enums (static), and the other type will be pointers to Things(dynamic). the structure already exists, and I am working though converting it to a template now –  gardian06 Mar 7 '12 at 19:28
@Corbin not exactly some of the operations (remove(int X), clear()) will destroy nodes, but when it comes time to remove the node how do I determine if the node is holding a static, or dynamic thing in it –  gardian06 Mar 7 '12 at 19:33
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2 Answers 2

up vote 4 down vote accepted

You can specialize the node based on the type of the object, and for the pointer specialization, create a destructor for the node-type that properly allocates and deletes the pointer managed by the node.

For instance:

//general node type for non-pointer types
template<typename T>
struct linked_list_node
    T data;
    linked_list_node<T>* next;

    linked_list_node(const T& d): data(d), next(NULL) {}
    ~linked_list_node() {} 

//specialized version for pointer types
template<typename T>
struct linked_list_node<T*>
    typedef void (*deleter)(T*);

    T* data;
    linked_list_node<T>* next;
    deleter d_func;  //custom function for reclaiming pointer-type

    linked_list_node(const T& d): data(new T(d)), next(NULL), d_func(NULL) {}

    linked_list_node(const T& d, deleter func): data(new T(d)), 
                                                next(NULL), d_func(func) {}
            d_func(data);  //execute custom function for reclaiming pointer-type
            delete data;

You can then instantiate the different versions by passing the correct template argument when creating an instance of the linked_list_node type. For instance,

linked_list_node<MyPtr*> node(FooPtr); //creates the specialized ptr version
linked_list_node<MyEnum> node(FooEnum); //creates a non-ptr version of the node
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then do I do some kind of case switch to determine which one to use –  gardian06 Mar 7 '12 at 19:38
No, simply instantiate the template argument with either a pointer type or a enum type. For instance, linked_list_node<MyFooPtr_t*>, or linked_list_node<MyFooEnum_t>. –  Jason Mar 7 '12 at 19:43
But don't specialize the whole list data structure. Instead, just create a helper function (or class) that the list calls when it's time to free an element, the helper will be specialized by type. And you can also specialize for specific types, i.e. FILE* might call fclose instead of delete. –  Ben Voigt Mar 7 '12 at 19:49
@BenVoigt : Thanks for the suggestion ... I made some updates per your suggestions, let me know if that's what you were thinking, or if there was something else you were getting at. –  Jason Mar 7 '12 at 21:30
@Jason: No, what I was thinking of is just one version of linked_list_node (you really don't want to duplicate the whole class). In the destructor it would call element_release<T>(data) or element_traits<T>::release(data). Then you specialize a class with just one function, and can also easily specify cleanup operations for non-pointer handles, such as mutex_t, etc. –  Ben Voigt Mar 7 '12 at 22:20
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Template specialization is the best answer, and will work well as long as you don't mix types of nodes. However if you want to mix types of your linked nodes, let me show you how to do it. First, there is no straightforward template solution. You would have to type cast your linked nodes together due to strict type constrains.

A quite common solution is to construct a variant class (which can hold one value with variant types, and is always aware which one). Qt has a QVariant class, for instance. Boost has boost::any.

Here is a complete example implementation using a custom variant class that could hold any of your types. I can handle your suggested object pointer and enum, but could be extended to hold more.

An example which will print "delete obj" once:

    #include <iostream>                                                                                                                                                                                                    

    main( int argc, char **argv )                                                                                                                                                                                            
      LinkedList<VariantExample> elementObj( new ExampleObj );                                                                                                                                                                

      LinkedList<VariantExample> elementEnum( enumOne );                                                                                                                                                                      

      elementEnum.setNext( elementObj );                                                                                                                                                                                     

// VariantExample class. Have a look at [QVariant][4] to see how a fairly
// complete interface could look like.

        struct ExampleObj                                                                                                                                                                                                        

        enum ExampleEnum                                                                                                                                                                                                         

        struct VariantExample                                                                                                                                                                                                     
          ExampleObj* obj;      // or better boost::shared_ptr<ExampleObj> obj                                                                                                                                                                                                      
          ExampleEnum en;                                                                                                                                                                                                        

          bool is_obj;                                                                                                                                                                                                           
          bool is_enum;                                                                                                                                                                                                          

          VariantExample() : obj(0), is_obj(false), is_enum(false) {}

          // implicit conversion constructors

          VariantExample( ExampleObj* obj_ ) : is_obj(true), is_enum(false)                                                                                                                                                
          { obj = obj_;                                                                                                                                                                                                          

          VariantExample( ExampleEnum en_ ) : obj(0), is_obj(false), is_enum(true)                                                                                                                                                        
          { en = en_;                                                                                                                                                                                                            

          // Not needed when using boost::shared_ptr above

            if( is_obj && obj )                                                                                                                                                                                                         
                std::cout << "delete obj" << std::endl;                                                                                                                                                                          

                delete obj;                                                                                                                                                                                                      


// The linked list template class which handles variant classes with a destroy()
// method (see VariantExample).

      typename _type_ = VariantExample                                                                                                                                                                                                       
    struct LinkedList                                                                                                                                                                                                        
      LinkedList* m_next;                                                                                                                                                                                                    

      _type_ m_variant;                                                                                                                                                                                                      

      LinkedList( _type_ variant_ ) : m_next(0), m_variant( variant_ ){ }                                                                                                                                                               

      setNext( LinkedList& next_ ){ m_next = &next_; }                                                                                                                                                                       

      // Not needed when using boost::shared_ptr above


Because elementObj's destroy method called once when the LinkedList's destructor is called, the output "delete obj" is appearing just once. Again, as you were quite specific about the delete/ownership, this example has a destroy method/interface. It will be explicitly called in the destructor of the LinkedList class. A better ownership model could be implemented with ie. boost::shared_ptr. Then you dont need to destroy it manually. It helps to read about conversion constructors, by the way.

  // the first parameter becomes boost::shared_ptr<ExampleObj>( new ExampleObj ) )
  // and is deleted when LinkedList is destroyed. See code comments above.

  LinkedList<> elementObj( new ExampleObj );                                                                                                                                                                

Finally note that you have to have a single variant class to hold all your types which could appear in your LinkedList chain. Two different LinkedList Variant types would not work, again, finally because of the "next" pointer type; which would be not compatible.

Footnote: How type constrains prevent an easy solution ? Imagine your linked node "next" pointer type is not just the the bare template name, its a shortcut, but is actually qualified including the template arguments - what end up as the type symbol the compiler uses to judge type compabilities.

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Jason's example should not compile as soon as you set node.next with different types of nodes –  muenalan Mar 8 '12 at 10:27
The idea with templates is to enforce a type constraint ... so the fact that it won't compile is not an error, but rather signifies that you've broken the type constraint rules, which is much better to be warned about at compile rather than run-time. –  Jason Mar 8 '12 at 14:26
Yep, agreed: no template nonsense shall sneak into runtime ;) So, my point: variants for relaxed type constrains. However, the idea with templates is to prevent code duplication without disobeying language constrains; including type constrains. See Ben Voigts comment on your answer. –  muenalan Mar 10 '12 at 11:22
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