This is the answer you should use... So a good way to solve this one involves creating a `struct`

or `class`

to wrap your array (well, buffer of data -- I'd use a `std::vector`

). And instead of a signature like `times(A, b, c, m, n)`

, go with this kind of syntax:

```
Matrix<4,4> M;
ColumnMatrix<4> V;
ColumnMatrix<4> C = M*V;
```

where the width/height of M are in the `<4,4>`

numbers.

A quick sketch of the Matrix class might be (somewhat incomplete -- no const access, for example)

```
template<size_t rows, size_t columns>
class Matrix
{
private:
std::vector<double> values;
public:
struct ColumnSlice
{
Matrix<rows,columns>* matrix;
size_t row_number;
double& operator[](size_t column) const
{
size_t index = row_number * columns + column;
Assert(matrix && index < matrix->values.size());
return matrix->values[index];
}
ColumnSlice( Matrix<rows,columns>* matrix_, size_t row_number_ ):
matrix(matrix_), row_number(row_number_)
{}
};
ColumnSlice operator[](size_t row)
{
Assert(row < rows); // note: zero based indexes
return ColumnSlice(this, row);
}
Matrix() {values.resize(rows*columns);}
template<size_t other_columns>
Matrix<rows, other_columns> operator*( Matrix<columns, other_columns> const& other ) const
{
Matrix<rows, other_columns> retval;
// TODO: matrix multiplication code goes here
return std::move(retval);
}
};
template<size_t rows>
using ColumnMatrix = Matrix< rows, 1 >;
template<size_t columns>
using RowMatrix = Matrix< 1, columns >;
```

The above uses C++0x features your compiler might not have, and can be done without these features.

The point of all of this? You can have math that both looks like math and does the right thing in C++, while being really darn efficient, and *that* is the "proper" C++ way to do it.

You can also program in a C-like way using some features of C++ (like `std::vector`

to handle array memory management) if you are more used to it. But that is a different answer to this question. :)

(Note: code above has not been compiled, nor is it a complete Matrix implementation. There are template based Matrix implementations in the wild you can find, however.)

`c = A * b;`

, you'll need a`Vector operator*(const Matrix& A, const Vector& b);`

or similar (depending on what your matrix and vector classes are, if they're templates, etc...). You could also make it a member function of the matrix class (thus getting the matrix argument implicitly, so the signature omits the first argument). – twalberg Nov 2 '12 at 15:28`std::array<std::array, width>, height>`

(or whatever your row/column order preferences are) instead of simple C-style arrays. You could also use`std::vector`

if you wanted the ability to resize at runtime. You can pass`std::array`

instances into and return from functions without any particular effort. – Rook Nov 2 '12 at 15:28