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I created a matrix class:

template <typename T>
class Matrix
{
public:
    Matrix(size_t n_rows, size_t n_cols);
    Matrix(size_t n_rows, size_t n_cols, const T& value);

    void fill(const T& value);
    size_t n_rows() const;
    size_t n_cols() const;

    void print(std::ostream& out) const;

    T& operator()(size_t row_index, size_t col_index);
    T operator()(size_t row_index, size_t col_index) const;
    bool operator==(const Matrix<T>& matrix) const;
    bool operator!=(const Matrix<T>& matrix) const;
    Matrix<T>& operator+=(const Matrix<T>& matrix);
    Matrix<T>& operator-=(const Matrix<T>& matrix);
    Matrix<T> operator+(const Matrix<T>& matrix) const;
    Matrix<T> operator-(const Matrix<T>& matrix) const;
    Matrix<T>& operator*=(const T& value);
    Matrix<T>& operator*=(const Matrix<T>& matrix);
    Matrix<T> operator*(const Matrix<T>& matrix) const;

private:
    size_t rows;
    size_t cols;
    std::vector<T> data;
};

Now I want to enable operations between matrix of different types, for example:

Matrix<int> matrix_i(3,3,1); // 3x3 matrix filled with 1
Matrix<double> matrix_d(3,3,1.1); // 3x3 matrix filled with 1.1

std::cout << matrix_i * matrix_d << std::endl;

I thought to do like this (is the right way?):

template<typename T> // Type of the class instantiation
template<typename S>
Matrix<T> operator*(const Matrix<S>& matrix)
{
   // Code
}

I think this will work fine if I multiply a double matrix with an integer matrix: I will obtain a new double matrix. The problem is that if I multiply an integer matrix with a double matrix I will lose some information, because the matrix I obtain will be an integer matrix... Right? How can I fix this behave?

std::cout << matrix_d * matrix_i << std::endl; // Works: I obtain a 3x3 matrix full of 1.1
std::cout << matrix_i * matrix_d << std::endl; // Doesn't work: I obtain a 3x3 matrix full of 1 instead of 1.1
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1 Answer 1

up vote 4 down vote accepted

To do what you want, you will need to offer an operator* that returns a Matrix<X> where X is the type with the largest range/greatest precision.

If you have a C++11 compiler at hand, you could use:

template <typename T, typename U>
auto operator*( Matrix<T> const & lhs, Matrix<U> const & rhs) 
     -> Matrix< delctype( lhs(0,0) * rhs(0,0) ) >
{
   Matrix< delctype( lhs(0,0) * rhs(0,0) ) > result( lhs );
   result *= rhs;
   return result;
}

Assuming that you have operator*= implemented as a template that allows multiplications with other instantiations of Matrix<T> and that you have a conversion constructor.

share|improve this answer
    
I have C++ compiler (GCC 4.7). The auto keyword is the only way? What is a conversion constructor? Can you explain me the third line? I don't get it... Thank you. –  user1434698 Aug 19 '12 at 12:49
    
@R.M.: C++11 is no the only way, but it is the simplest. g++4.7 should support the syntax if you pass in -std=c++11. The auto together with the -> ... are called trailing return type, and are a way of postponing the definition of the return type until the arguments to the function are in context (so that lhs and rhs can be used inside the decltype expression) –  David Rodríguez - dribeas Aug 19 '12 at 13:23
    
@R.M. A conversion constructor (I don't think the standard calls them so, but I thought this would be understood) would be a constructor that takes an argument of a different type, effectively performing a type conversion. In C++03 you could define a type trait that takes two types and yields the promoted type (say int,int->int, int,double->double) and use that trait in the return type: template <typename T, typename U> Matrix< typename promoted<T,U>::type > operator*( Matrix<T> const&, Matrix<U> const& ). –  David Rodríguez - dribeas Aug 19 '12 at 13:46

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