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N3580 describes the following scenario:

template<Object T, template<Object> Cont>
struct stack {
    Cont<T> container;

struct my_vector;

struct my_list;

struct my_magic;

Here, Regular is a refinement of Object; that is, every Regular is an Object but not every Object is a Regular.

I would expect the type system to be such that for stack<X, Y> to be valid, X must be an Object and Y must be instantiable with an Object. This would mean that stack<int, my_vector> and stack<int, my_magic> are valid, while stack<int, my_list> is not. Much like the case with normal functions:

struct Base {};
struct Derived : Base {};

void foo(Base* p, function<void(Base*)> fun) {

template<typename T>
void bar(T*);

I would expect that if p is a Base*, then foo(p, bar<Base>) and foo(p, bar<void>) are valid, while foo(p, bar<Derived>) is not; after all, a Base* has an implicit conversion to a void*, but not to a Derived*.

In the case of templates, though, the situation is the opposite. Only stack<int, my_vector> and stack<int, my_list> are allowed, while stack<int, my_magic> is forbidden. Why is this? my_magic works fine with any type, while my_list may fail depending on what object I give it. Moreover, I can trivially make my_magic work with only objects:

template<Object T>
struct my_restricted_magic : my_magic<T> {};

Now my_restricted_magic can be used with stack. On the other hand, there's no easy way of making a my_list which accepts any type, but this is exactly what passing it as a template template parameter now allows.

Am I misinterpreting the purpose of constraints on template template parameter's parameters?

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@KerrekSB N3580 is a C++1y paper. Bar has one type argument constrained by the concept Object. –  Yakk Dec 30 '13 at 23:03
@Yakk: Oh, I see. I actually read that once. (It's not in C++1y though, is it?) –  Kerrek SB Dec 30 '13 at 23:05
@KerrekSB Nope, it'll be a separate TS. –  Joseph Mansfield Dec 30 '13 at 23:09
I'm a little confused by this question. Do you think your last line should be allowed? Why? –  Joseph Mansfield Dec 30 '13 at 23:11
@sftrabbit: I expect passing template templates to work much like passing functions, while it actually does the opposite. Basically, I'd expect contravariance, but get covariance instead. –  Anton Golov Dec 30 '13 at 23:20

2 Answers 2

up vote 8 down vote accepted

It's a bug in the proposal. A constrained template template parameter should accept arguments with weaker constraints.

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Thanks! Is the current behaviour (allowed, forbidden) also backwards? –  Anton Golov Dec 31 '13 at 12:27
That's a good question, and I don't have a good answer. It looks like you can make a very convincing argument that [allowed] should be an error, and [forbidden] should be valid. The reasoning would follow the arguments here: that the template template parameter's signature announces the intended use of the argument. –  Andrew Sutton Dec 31 '13 at 20:48
Ugh. Stupid comment editing system. The reason being that the template template parameter's signature expresses the intended use of the argument, and the arguments provided don't support the intended uses. Right or wrong, the standard requires that behavior (14.3.3/3). Maybe a defect report is in order. –  Andrew Sutton Dec 31 '13 at 21:02
Hm, this seems to have been introduced by N2555, where such matching rules were desired for the implementation of Boost's MPL and Proto libraries. It seems like people want a way of taking a template that "can be anything", and which they simply want to instantiate with a user-provided parameter pack. This doesn't go well with the meta-type-safety that constraints want to add, but it does look like a valid use case. Thanks, I'll look into submitting a defect report. (I think the [forbidden] case should definitely be allowed.) –  Anton Golov Dec 31 '13 at 21:22
@AntonGolov Note that we don't have "anything", as a template that takes a mixture of types and values cannot be taken, and you cannot have a pack of a mixture of types and values. Here is a way to map your typename... to a unary template: ideone.com/3wX9o5 -- if allowed/forbidden was reversed, I don't think I could write such an adapter the other way. –  Yakk Jan 2 '14 at 16:50

This is conjecture, but it seems like a likely explanation:

Allowing to pass a more specific template, rather than a more generic one, is the way the rules currently work in regard to variadic template template parameters. You are allowed to pass a single-type-parameter template where a variadic is expected:

template<template<typename...> class> struct Foo {};
template<typename> Bar {};

Foo<Bar>(); // legal

But not vice-versa:

template<template<typename> class> struct Foo {};
template<typename...> Bar {};

Foo<Bar>(); // error, argument/parameter mismatch.

The phrasing originated in N2555 where it was requested to allow code like this:

struct Foo;

template<template<typename...> class Fun, template... Args>
struct Foo<Fun<Args...>> {};

Foo<std::pair<int, double>>();

Basically, instead of the template<typename...> class being a guarantee to the user, it is a catch-all thing that the user must then provide sensible arguments for. Given this usage involving specialisations, that does seem reasonable.

This does not explain why passing a more general template is not allowed, but reversing the phrasing in N3580 would make the two rules put together rather unintuitive.

Proposal link: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2008/n2555.pdf

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