I'm trying to arbitrarily "bind" template parameters but have run into an elegance problem.

To cut straight to the underlying problem, gcc 6.2 has a problem with the following but logically I see no issue with it...

```
template<template<typename, typename> P, typename A, typename B>
struct foo {
static constexpr bool value = P<A, B>::value;
};
template<typename...Ts>
struct bar {
static constexpr bool value = true;
};
```

... `foo`

given `bar`

such as `foo<bar, void, void>`

should result in the instantiation of `bar<void, void>`

(which is valid), who's `value`

member is `true`

and therefore `foo<bar, void, void>::value`

is likewise `true`

. *Effectively*, this *should* (in my mind) result in instantiated structs conceptually akin to...

```
struct bar<void, void> {
static constexpr bool value = true;
};
struct foo<bar, void, void> {
static constexpr bool value = bar<void, void>::value; //which is true
};
```

You can see this concept in action (or rather the error) here https://godbolt.org/g/lT9umg.

Back to the begining now, first I tried the following...

```
template<typename...>
struct type_list { };
template<template<typename...> typename Tmpl, typename...Ts>
struct bind_template {
template<typename...Us>
using type = Tmpl<Ts..., Us...>;
};
template<template<typename> typename Predicate, typename...Ts>
struct has_matching_type {
private:
template<template<typename> typename, typename, typename=void>
struct helper: std::false_type { };
template<template<typename> typename P, typename U, typename...Us>
struct helper<P, type_list<U, Us...>, typename std::enable_if<P<U>::value>::type>: std::true_type { };
template<template<typename> typename P, typename U, typename...Us>
struct helper<P, type_list<U, Us...>, typename std::enable_if<!P<U>::value>::type>: helper<P, type_list<Us...>> { };
public:
static constexpr bool value = helper<Predicate, type_list<Ts...>>::value;
};
template<typename T, typename...Ts>
using has_type = has_matching_type<bind_template<std::is_same, T>::template type, Ts...>;
```

Later I might try to instantiate through `has_type<T, Ts...>`

such as...

```
cout << has_type<long, int, bool, long, float>::value << endl;
```

However, as I pointed out gcc 6.2.0 complains because it doesn't seem to recognize that, once resolution is done, the template instantiation is pragmatically equivalent.

Simply knowing the number of template parameters and specializing for that exact number solves the problem. If I specialize `bound_template`

keeping `std::is_same<LHS, RHS>`

in mind...

```
template<template<typename, typename> typename Tmpl, typename T>
struct bind_template<Tmpl, T> {
template<typename U>
using type = Tmpl<T, U>;
};
```

... we suddenly compile and evaluate compile-time no problem because gcc sees `bind_template<std::is_same, long>::type`

as taking one type parameter exactly.

Obviously, abstracting this concept out to allow for any template parameters, such as integral constants and not just types, is a fundamental issue regardless of compiler. Simply focusing on types for a minute though, my question is multiple:

- Am I missing something here conceptually and the compiler is actually doing exactly what should be obvious to me?
- If not, is this in violation of C++11 standards, not directed by standards, or is it a compiler dependency?
- Is there some elegant way I can get around this regardless of the answers to my first two questions?

Functionally, the real question (particularly if this is an unavoidable issue in C++11) is...

## Is there some elegant way I can abstractly bind templates without having to specialize for every case (the simplest here being *n* number of types)?

Just being able to get an answer to questions 1 or 3 would be great. Question 3 is the most important because at the end of the day it's what works that matters.

Obviously, I can specialize (as shown above). A big problem though is that even the following doesn't seem to work (at least according to this online compiler)...

```
template<template<typename...> class Tmpl, typename... Ts>
struct bind_helper {
template<typename... Us>
struct type: Tmpl<Ts..., Us...> { };
template<typename A>
struct type<A>: Tmpl<Ts..., A> { };
template<typename A, typename B>
struct type<A, B>: Tmpl<Ts..., A, B> { };
template<typename A, typename B, typename C>
struct type<A, B, C>: Tmpl<Ts..., A, B, C> { };
};
```

This means that, not only would I have to generate a bunch of parameters, but I'd have to match the outer parameters as well via complete `bind_template`

specialization. This quickly becomes (actually is) a binomial problem.

Extending this concept further (but still keeping to types), I was planning to next implement "placeholders" the same way `std::bind`

uses placeholders (which would have worked rather elegantly because I would have just peeled and rejoined the list at the index). Obviously this is too much of a mess to proceed without a more abstract approach available.