How about defining a template class as follows:
template <class V, class I = int, class S = FullMatrix<V> >
S m_structure; //The matrix structure
I m_rowstart;//Row start index
I m_columnstart;//Column start index
The main constructors would be
Matrix(size_t r, size_t c);//r rows and c columns
Matrix(size_t r, size_t c, I rowStart, I columnStart);//rowstart and columnstart are given start indices
Matrix(const Matrix<V, I, S>& source);
You would then have functions to return the minimum/max row/column indices of form:
I MinRowIndex() const;
Next, you have functions to tell the number of rows/columns in the matrix.
size_t Rows() const;
Then, a function to allow replacement of elements in a row/column by another array of elements
void Row(I row, const Array<V, I>& val);//Replace row
Then, overload () to allow access to element in a given row and column
const V& operator ()(I row, I column) const;//Get Element
V& operator() (I row, I column);
Although computational tests may need to be done to check the benefit of this method as compared to maintaining a big matrix and individual start/stop indices of various submatrices (as suggested by Lagerbaer in the other thread) one advantage here is that each submatrix is independent. They can be transposed, moved around, replaced. You probably may need to maintain a higher-level matrix structure in which this Matrix is a sub-structure.
But it does seem to satisfy your question of being able to reference the submatrices independently.