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I am trying to write a function to determine the average of an arbitrary number of arguments, all of which have the same type. For learning purposes I am trying to do this using a templated variadic function.

This is what I have so far:

template<typename T, class ... Args>
T Mean(Args ... args)
{
    int numArgs = sizeof...(args);
    if (numArgs == 0)
        return T();           // If there are no arguments, just return the default value of that type

    T total;
    for (auto value : args...)
    {
        total += value;
    }

    return total / numArgs;   // Simple arithmetic average (sum divided by total)
}

When I try to compile this (VS2013) I get the following compile error:

error C3520: 'args' : parameter pack must be expanded in this context (test.cpp)

How should I properly "unpack" the args parameter? I thought that was the purpose of the ellipses?

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4 Answers 4

up vote 2 down vote accepted
template<typename T, class ... Args>
T Mean(Args ... args)
{
    int numArgs = sizeof...(args);
    if (numArgs == 0)
        return T();           // If there are no arguments, just return the default value of that type

    T total;
    for (auto value : {args...})
    {
        total += value;
    }

    return total / numArgs;   // Simple arithmetic average (sum divided by total)
}

This should create an std::initializer_list on which you can then use range-based for loops.

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Can also do it recursively, having the return type auto-deduced, so you can mix types. Code:

#include <iostream>

using namespace std;

template<typename T>
T Mean(T head)
{
    return head;
}

template<typename T, class ... Args>
T Mean(T head, Args... args)
{
    auto N = sizeof...(Args);
    return (head + (N)*Mean(args...)) / (N + 1);  
}

int main(void)
{
    cout << Mean((double)1, (int)2, (float)4) << endl; // (double) 2.3333...
}

or, with a wrapper,

#include <iostream>

using namespace std;

template<typename T>
T Mean_wrapper(T head)
{
    return head;
}

// return type is the type of the head of param list
template<typename T, class ... Args>
T Mean_wrapper(T head, Args... args) 
{
    return head + Mean_wrapper(args...);   
}

template<typename T, class ... Args>
T Mean(T head, Args... args)
{
    return Mean_wrapper(head, args...) / (sizeof...(args) + 1);
}

int main(void)
{
    cout << Mean((double)10, (int)20, (float)30) << endl; // (double) 20

}
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Note: The return type is the first type. Hence Mean((int)1, (int)2, (float)4) is an integer (2) –  Dieter Lücking Jul 29 at 18:40
    
@DieterLücking I think you have a previously un-edited piece of code in the browser cache, the call is Mean((double)1, (int)2, (float)4) –  vsoftco Jul 29 at 18:42
    
Ahh ok :) thanks, it was a typo on my part then, but why cannot I see that you edited it? –  vsoftco Jul 29 at 18:56
    
@DieterLücking, ok I got it, I thought first that you meant I have a typo in my code. –  vsoftco Jul 29 at 19:22

Note that you can expand the pack into a standard container and use the usual algorithms to get the result.

template <typename T, class... Args, std::size_t N = sizeof...(Args)>
T Mean(Args... args) {
  std::array<T, N> arr = {args...};
  if (N > 0) return std::accumulate(std::begin(arr), std::end(arr), T{}) / N;
  return T{};
}
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Recursively and considering argument types:

#include <iostream>
#include <type_traits>

namespace Detail {

    template <typename T, typename ... Args>
    struct Sum;

    template <typename T>
    struct Sum<T> {
        typedef T type;
        static type apply(T value) { return value; }
    };

    template <typename T, typename ... Args>
    struct Sum {
        typedef decltype(std::declval<T>() + std::declval<typename Sum<Args...>::type>()) type;
        static type apply(T a, Args ...args) {
            return a + Sum<Args...>::apply(args...);
        }
    };
} // namespace Detail

template <typename ... Args>
typename Detail::Sum<Args...>::type sum(Args ... args) {
    return Detail::Sum<Args...>::apply(args...);
}

template <typename ... Args>
typename Detail::Sum<Args...>::type mean(Args ... args) {
    return Detail::Sum<Args...>::apply(args...) / sizeof...(Args);
}


int main()
{
    // 2.5 / 2
    std::cout << mean(int(1), double(1.5)) << '\n';
    return 0;
}
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