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Consider the following code when a new container is defined over a std::array

#include <iostream>
#include <array>
#include <initializer_list>

// My container
template<typename Type, unsigned int Size>
class MyContainer
{
    // Lifecycle
    public:
        MyContainer() : _data() {}
        MyContainer(const MyContainer<Type, Size>& rhs) : _data(rhs.data()) {}
        MyContainer(const std::array<Type, Size>& rhs) : _data(rhs) {}
        template<typename... Types> MyContainer(const Types&... numbers) : _data({{numbers...}}) {}
        ~MyContainer() {}

    // Assignment
    public:
        MyContainer<Type, Size>& operator=(const MyContainer<Type, Size>& rhs) {_data = rhs.data(); return *this}

    // Accessors
    public:
        Type& operator[](const unsigned int i) {return _data[i];}
        const Type& operator[](const unsigned int i) const {return _data[i];}
        std::array<Type, Size>& data() {return _data;}
        const std::array<Type, Size>& data() const {return _data;}

    // Operators
    public:
        MyContainer<Type, Size> operator+(const MyContainer<Type, Size>& rhs)
        {
            MyContainer<Type, Size> result;
            for (unsigned int i = 0; i < Size; ++i) {
                result[i] = _data[i] + rhs[i];
            }
            return result;
        }

    // Data members
    protected:
        std::array<Type, Size> _data;
};

// Main
int main(int argc, char* argv[])
{
    // Initialization
    MyContainer<double, 4> x = {0., 1., 2., 3.};
    MyContainer<double, 4> y = {4., 5., 6., 7.};
    MyContainer<double, 4> z;

    // Operation
    z = x+y; // Can move semantics help here ?

    // Result
    std::cout<<z[0]<<" "<<z[1]<<" "<<z[2]<<" "<<z[3]<<std::endl;
    return 0;
}

Can move semantics speed up the operation in the main() by avoiding some copies ?

If the answer is yes, how to implement it in the current design ?

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In general, rvalues make things with pointers faster. If you have no pointers, don't bother with rvalues. –  Mooing Duck Jan 5 '13 at 1:45
    
you shouldn't defined constructors/operators that already do what you're implementing. Then the question becomes much simpler wr.t. the Rule of Five. –  GManNickG Jan 5 '13 at 1:47
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2 Answers

up vote 2 down vote accepted

No. All of the data of a std::array<double, N> is contained within the object itself. Move semantics only help when the object owns external referenced resources (usually via a pointer), and that reference can be copied and nullified.

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And do you think that it would be preferable that MyContainer contains a pointer to a std::array and not an std::array ? –  Vincent Jan 5 '13 at 1:45
    
More generally: if the class owns any resources or has members that have move-constructors, then a move constructor is helpful. But in the former case the Rule of Five dictates such a thing anyway, and in the former the implicitly generated move constructor Does The Right Thing. –  GManNickG Jan 5 '13 at 1:46
    
@Vincent: a pointer to a std::array seems silly to me, why not a std::vector? –  Mooing Duck Jan 5 '13 at 1:46
1  
@Vincent: I don't know. What are your concerns? Performance? Then measure it. –  Benjamin Lindley Jan 5 '13 at 1:48
    
@MooingDuck Because in the original code (not this one which is just an example), I compared the speed of two designs (one with std::array and one with std::vector, and the containers defined over std::array are faster (due to the memory allocation I suppose)) –  Vincent Jan 5 '13 at 1:49
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For MyContainer<double> there's no advantage, when you "move" a double it actually does a copy, because a double has no resources to move, it only has a value to copy.

But your type is a template, so presumably you're going to use it for types other than double. For MyContainer<std::string> or MyContainer<HeavyweightType> it would be worth defining move operations. That would be simple:

    MyContainer(MyContainer&&) = default;
    MyContainer& operator=(MyContainer&&) = default;

Note that you can just say MyContainer instead of MyContainer<Type, Size>, in a class template's definition the name of a class template without a template argument list refers to the current instantiation, i.e. MyContainer is the same type as MyContainer<Type, Size>.

You can simplify some of your other special member functions too:

    MyContainer(const MyContainer&) = default;
    ~MyContainer() = default;

    MyContainer& operator=(const MyContainer>&) = default;

Now your type is movable and copyable, with the right semantics, and the code is even simpler than your original version!

You could also add move support to these functions:

    MyContainer(const std::array<Type, Size>& rhs) : _data(rhs) {}
    template<typename... Types> MyContainer(const Types&... numbers) : _data({{numbers...}}) {}

by adding a constructor taking an rvalue array, and making the constructor template use universal references and perfect forwarding:

    MyContainer(const std::array<Type, Size>& rhs) : _data(rhs) {}
    MyContainer(std::array<Type, Size>&& rhs) : _data(std::move(rhs)) {}
    template<typename... Types> MyContainer(Types&&... numbers)
      : _data{{ std::forward<Types>(numbers)...}} {}

Now your type can be initialized with rvalues.

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