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How do I declare a templated type that refers to itself?

template <class T = Animal> class Animal
    T getChild ();

With this, I get a compiler error concerning a missing type specifier. I tried to forward-declare Animal, without success.

I am trying to impose a type constraint. A Lion can only have a Lion as a child, a Bear has a Bear, and so on.


I'll post part of the actual class. It is a template for classes that can appear in a linked list:

template <class T = Linked<T> > class Linked
    T* m_prev;
    T* m_next;

I want to enforce that the class can only point to object of the same class (or a subclass).

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This strikes me as a rather weird use of templates. What is it that you are trying to achieve? –  André Caron Jun 1 '11 at 23:05
It's a node in a specialized linked list that holds pointers to other instances of its type. In Java generics, this works without a hitch. –  Tony the Pony Jun 1 '11 at 23:07
That seems like a need that inheritance would fill more correctly than template types. –  dusktreader Jun 1 '11 at 23:09
If it holds pointers to other instances of the same type, why do you need a template argument? –  André Caron Jun 1 '11 at 23:09
It works in Java because, e.g. a Collection is a Collection<Object>. –  trutheality Jun 1 '11 at 23:12

4 Answers 4

up vote 1 down vote accepted

The usual way to do something like a linked list is:

template <class T> class Linked
    Linked<T>* m_prev;
    Linked<T>* m_next;

Does this work for you, and if not, what are you trying to accomplish that can't be done this way?

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This works. I can constrain the type in the API. Thanks! –  Tony the Pony Jun 1 '11 at 23:27
Now comes the inevitable memory corruption followup question since the template class lacks a copy c'tor, copy-assignment operator, and destructor. :-P –  ildjarn Jun 1 '11 at 23:29

In this case, you need to specify some type parameter to Animal in your typename definition, or else it would be an "infinite recursion" in the type construction:

template<class T> class Animal;//you'll need this forward declaration

template <class T = Animal<int> > class Animal //int is just an example
    T getPrey ();
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The OP has been answered but I want to chime in because the immediate cause of the problem is not recursion, as others claim. The simplest reason this wouldn't work is that class templates are not types. They are templates. Similarly, function templates are not functions either. So all of this is nonsensical:

template<typename T> int function_template(int);
typedef int function_type(int);
void eats_a_function(function_type&); // needs a reference to function

std::vector< std::vector > vec0; // std::vector is not a type
std::vector< std::list > vec1; // std::list is not a type
eats_a_function(function_template); // function_template is not a function

Notice that in the vec1 case, std::list is not related to std::vector. The template is fully defined (assuming header inclusion) at the point of instantiation. It still won't work.

Instead, the following works:

std::vector< std::vector<int> > vec2; // std::vector<int> is a type
std::vector< std::list<double> > vec3; // std::list<double> is a type
eats_a_function(function_template<long>); // function_template<long> is a function

Notice that in the vec2 case, it's fine to pass an instantiation of the template itself.

For the record, a toy solution to the toy problem on writing a template that refers to itself, using the proverbial layer of indirection:

// expects a template that expects a type
template<template<class> class T> struct indirection {};

// forward decl. for defaulting the parameter
template<typename T> struct recursive;

// template that expects a type
template<typename T = indirection<recursive> > struct recursive {};

Not terribly powerful given the few things that are possible with a template (the T parameter inside indirection). It's of course possible to write a rebind-style metafunction that returns an instantiation of T.

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You can't create a template class wherein the template type is the class itself. This is a logical recursion that your compiler can't mitigate. Since templates require the compiler to construct the object when a specific typing is encountered ( say Animal ), you have to have a complete definition of the template type. Otherwise, the compiler will recursively try to construct objects. Since your object self-references, this will be an non-terminating recursion.

This use-case seems much more appropriate for inheritance than for templates.

Doing this will let you compile: template class Animal { public: T getPrey (); }

Or, if you really wan't a default argument:

template <class T=Cheetah> class Animal
    T getPrey ();

Yet, cheetah must not use itself or Animal as one of its potential template types.

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