C++ template specialization - unable to match function definition

Question

I've been beating my head against the wall for a day and a half, trying to learn template specialization and std::enable_if(). I'm not getting something. I'm trying to allow the specification of a return type from a class method, based on the class type AND user specification at compile time. For example, if the class type is integer, I might want a float return type (or an int) from the method.

My actual use case is an array for which I'm averaging all the values within. I might even want a boolean return value to reflect the outcome of a binary "vote". There are lots of combinations. There must be a way to do this without having the create all the overloads individually. My sample code is the simplest I could make it.

I'd be grateful for any pointers. How can I do this partial specialization, if indeed that is what it is called?

#include <string>

template <class T>
class Test {
public:
    Test(T val) { val_ = val; }
    template <typename U> U halve ();
private:
    T val_;
};


template<class T> template<typename U>
U Test<T>::halve() {
    throw std::invalid_argument("Cannot halve non-numeric objects");
}

template<class T> template<typename U>  //example: T=int, U=float
typename std::enable_if_t<std::is_arithmetic<T>::value && std::is_arithmetic<U>::value, U>
Test<T>::halve() {  //error C2244 - unable to match function definition to an existing declaration
    return ((U)val_ / (U)2);
}


int main() {
    Test<int> t1(5);
    float f = t1.halve<float>();    //expect 2.5
    int i = t1.halve<int>();        //expect 2
    Test<std::string> t2((std::string)"blah");
    int t2h = t2.halve<int>();  //this will throw (by design)
    return 0;
}

Answer 1

Sam's comment is spot on - you can't partial specialize member function. The work around is to use enable_if_t in the class body. Something like this should work:

template <class T> class Test {
  public:
    Test(T val) { val_ = val; }
    template <typename U>
      std::enable_if_t<std::is_arithmetic<T>::value && std::is_arithmetic<U>::value, U>
      halve () {  
         return ((U)val_ / (U)2);
      }
    template <typename U>
      std::enable_if_t<!(std::is_arithmetic<T>::value && std::is_arithmetic<U>::value), U>
      halve () {  
          throw std::invalid_argument("Cannot halve non-numeric objects");
      }
  private:
    T val_;
};

Answer 2

There's a much easier way to do this, just declare a main function with a template, then specialize it for whatever type you need. I added int and float, and it returns the right value.

Pass in anything else and it throws, because the first halve function will be called.

template <class T>
class Test
{
public:

    Test(T val)
    {
        val_ = val;
    }

    // Default function
    template<class MainType>
    MainType halve()
    {
        throw std::invalid_argument("Cannot halve non-numeric objects");
    }

    // Int specialization
    template<>
    int halve<int>()
    {
        return (static_cast<int>(this->val_) / static_cast<int>(2));
    }

    // Float specialization
    template<>
    float halve<float>()
    {
        return (static_cast<float>(this->val_) / static_cast<float>(2));
    }

private:

    T val_;
};

int main()
{
    Test<int> t1(5);
    float f = t1.halve<float>();    // Returns 2.5
    int i = t1.halve<int>();        // Returns 2
    void* v = t1.halve<void*>();    // Throws. Type void* is not specialized in the class
    printf("%.5f %d\n", f, i);
    getchar();
    return 0;
}