An `iterator`

is a generic mechanism abstracting the details of how the elements are actually stored. As generic object orientated programming (OOP) don't really work well together, iterators are not commonly implemented via OOP.

I don't know why you want to use OOP for you `Matrix`

, i.e. whether you really want to use run-time polymorphism on matrices. If this is really important, then you will want polymorphic `Matrix::begin()`

and `Matrix::end()`

and hence the need for a polymorphic `Matrix::iterator`

. Code using such matrices will look like

```
#include <Matrix.hpp>
void foo(Matrix const&m)
{
for(a : m) { [...] }
}
```

But you will pay the price of a virtual function call (virtual table look-up) for every call to a polymorphic method of `Matrix::iterator`

. If this is not performance critical, this type of design is okay, though unusual for iterators.

However, I would prefer the generic programming approach, whereby the two matrix types may be derived from a common base, but not for the purpose of run-time polymorphism. Then each type simply has its own iterator type and its own non-virtual `begin()`

and `end()`

. Code using such matrices will look like

```
#include <Matrix.hpp>
template<typename Matrix>
typename std::enable_if<is_Matrix<Matrix>::value>:: // is_Matrix defined in Matrix.hpp
type foo(Matrix const&m)
{
for(x : m) { [...] }
}
```

Instead of SFINAE (`std::enable_if`

) you may simply `static_assert()`

the correct matrix type, though
then your function may be ambiguous with another `foo(some_arg)`

.