5

Consider a class template and auxiliary enum classes defined as follows:

enum class Color {Red, Green, Blue}
enum class ShowAxes {False, True}
enum class ShowLabels {False, True}

template< Color, ShowAxes, ShowLabels >
class A
{......};

The question is, how to redefine the class A, which would be independent on the permutations of its arguments. I use Dev C++, which supports C++11.

[EDIT]

For example, the new version of A should support

A< Color::Red, ShowAxes::True, ShowLabels::True >
A< Color::Red, ShowLabels::True, ShowAxes::True >
A< ShowAxes::True, Color::Red, ShowLabels::True >
A< ShowLabels::True, Color::Red, ShowAxes::True >
A< ShowLabels::True, Color::Red, ShowAxes::True >
A< ShowAxes::True, Color::Red, ShowLabels::True >

versions, and all of them are identical, i.e. they generate the same class.

  • c++ class template specialization? – Bryan Chen Feb 2 '15 at 11:02
  • 1
    @BryanChen you can't change the types of parameters with a specialization – Piotr Skotnicki Feb 2 '15 at 11:03
  • I don't want to change the types of parameters. The specialization is a good idea, but I have 3! = 6 permutations. Moreover, I am going to add more parameters. – Vahagn Poghosyan Feb 2 '15 at 11:24
  • Not possible with non-type parameters of different types. You can take type parameters and wrap the value in a type like std::integral_constant, but it gets verbose rather quickly. – T.C. Feb 2 '15 at 11:25
5

It isn't possible with your current interface using non-type parameters.

You can take type parameters instead and wrap the values in a std::integral_constant:

template<class X, class Y, class Z>
class A { /* stuff */ };

// use as:
A<std::integral_constant<Color, Color::Red>,
  std::integral_constant<ShowAxes, ShowAxes::True>,
  std::integral_constant<ShowLabels, ShowLabels::True>> a;

This is rather verbose, so you could consider writing a macro:

#define AS_IC(Value) std::integral_constant<decltype(Value), Value>

and rewrite as

A<AS_IC(Color::Red), AS_IC(ShowAxes::True), AS_IC(ShowLabels::True)> a;

Extracting the value of the desired type from the list of integral_constants is straightforward:

template<class Result, class...>
struct extract;

template<class Result, Result Value, class... Tail>
struct extract<Result, std::integral_constant<Result, Value>, Tail...> : std::integral_constant<Result, Value> {};

template<class Result, class Head, class... Tail>
struct extract<Result, Head, Tail...> : extract<Result, Tail...> {};

Then you can do

// inside the definition of A
static constexpr Color col = extract<Color, X, Y, Z>::value;

Demo.

This do not, however, generate the same class, but you can make a class template A_impl that behaves like your A with non-type parameters, and that contains the actual implementation, and then make A an alias template:

template< Color, ShowAxes, ShowLabels >
class A_impl
{/* stuff */};

template<class X, class Y, class Z>
using A = A_impl<extract<Color, X, Y, Z>::value,
                 extract<ShowAxes, X, Y, Z>::value,
                 extract<ShowLabels, X, Y, Z>::value>;

Now given

A<AS_IC(Color::Red), AS_IC(ShowAxes::True), AS_IC(ShowLabels::True)> a;
A<AS_IC(Color::Red), AS_IC(ShowLabels::True), AS_IC(ShowAxes::True)> b;

a and b have the same type. Demo.

In the alternative, you can also use decltype and overloading function templates, but that requires adding a function template declaration for every possible order of types:

template< Color c, ShowAxes a, ShowLabels l>
A<c,a,l> A_of();

template< ShowAxes a, ShowLabels l, Color c>
A<c,a,l> A_of();

// etc.

decltype(A_of<Color::Red, ShowAxes::True, ShowLabels::True>()) a1;
decltype(A_of<ShowAxes::True, ShowLabels::True, Color::Red>()) a2;
  • The idea of std::integral_constant and extract looks nice. I will think about optimization of the code. – Vahagn Poghosyan Feb 2 '15 at 12:12
  • I have a small (maybe trivial) question. Is it possible to replace a macro AS_IC by a non-directive staff, say a class template or template function ? – Vahagn Poghosyan Feb 2 '15 at 15:01
  • 1
    @VahagnPoghosyan No macro-free way that I'm aware of without adding lots of boilerplate when you declare an A. – T.C. Feb 3 '15 at 1:03
0

Maybe by using std::is_same. Then you can simplify your code this way:

template <typename A, typename B, typename C>
class X
{
public:
    X() {
        static_assert(
            std::is_same<A, Color>::value ||
            std::is_same<B, Color>::value ||
            std::is_same<C, Color>::value,
            "nope");
        // other assertions here!
        // also, make sure your types are different ;)
    }
    X(A a, B b, C c) : X() {
        // your code here
    }
};

template <typename A, typename B, typename C>
X<A, B, C> make(A a, B b, C c) {
    // possible verifications here
    return X<A, B, C>(a, b, c);
}

int main() {
    auto a = make(Color::Red, ShowAxes::true, ShowLabels::True);
    return 0;
}

You can verify all of your types A, B & C.

I'm sorry, but I don't see any other solution. :/

  • 2
    OP's code expects non-type template parameters – Piotr Skotnicki Feb 2 '15 at 11:01
  • I added some text in the question for the detailed explanation of my aim. – Vahagn Poghosyan Feb 2 '15 at 11:21
  • I edited my post. – vincentp Feb 2 '15 at 11:36
  • Thank you, but for example make(Color::Red, ShowAxes::True, ShowLabels::True) and make(ShowAxes::True, Color::Red, ShowLabels::True) give different results. They should generate the same class. – Vahagn Poghosyan Feb 2 '15 at 11:51
  • Can inheritance resolve the problem? If the X class inherits from a Base class, they can be of the same type thanks to polymorphism. – vincentp Feb 2 '15 at 11:54

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.