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`

.

`Collection`

is a`Collection<Object>`

. – trutheality Jun 1 '11 at 23:12