As I mentioned in the comments, it's not practical to represent matrices using vector-of-vector for a few reasons:

- It is fiddly to set up;
- It is difficult to change;
- Cache locality is bad.

Here is a very simple class I have created that will hold a 2D matrix in a single vector. This is pretty much how software like MATLAB does it... albeit a huge simplification.

```
template <class T>
class SimpleMatrix
{
public:
SimpleMatrix( int rows, int cols, const T& initVal = T() );
// Size and structure
int NumRows() const { return m_rows; }
int NumColumns() const { return m_cols; }
int NumElements() const { return m_data.size(); }
// Direct vector access and indexing
operator const vector<T>& () const { return m_data; }
int Index( int row, int col ) const { return row * m_cols + col; }
// Get a single value
T & Value( int row, int col ) { return m_data[Index(row,col)]; }
const T & Value( int row, int col ) const { return m_data[Index(row,col)]; }
T & operator[]( size_t idx ) { return m_data[idx]; }
const T & operator[]( size_t idx ) const { return m_data[idx]; }
// Simple row or column slices
vector<T> Row( int row, int colBegin = 0, int colEnd = -1 ) const;
vector<T> Column( int row, int colBegin = 0, int colEnd = -1 ) const;
private:
vector<T> StridedSlice( int start, int length, int stride ) const;
int m_rows;
int m_cols;
vector<T> m_data;
};
```

This class is basically sugar-coating around a single function -- `StridedSlice`

. The implementation of that is:

```
template <class T>
vector<T> SimpleMatrix<T>::StridedSlice( int start, int length, int stride ) const
{
vector<T> result;
result.reserve( length );
const T *pos = &m_data[start];
for( int i = 0; i < length; i++ ) {
result.push_back(*pos);
pos += stride;
}
return result;
}
```

And the rest is pretty straight-forward:

```
template <class T>
SimpleMatrix<T>::SimpleMatrix( int rows, int cols, const T& initVal )
: m_data( rows * cols, initVal )
, m_rows( rows )
, m_cols( cols )
{
}
template <class T>
vector<T> SimpleMatrix<T>::Row( int row, int colBegin, int colEnd ) const
{
if( colEnd < 0 ) colEnd = m_cols-1;
if( colBegin <= colEnd )
return StridedSlice( Index(row,colBegin), colEnd-colBegin+1, 1 );
else
return StridedSlice( Index(row,colBegin), colBegin-colEnd+1, -1 );
}
template <class T>
vector<T> SimpleMatrix<T>::Column( int col, int rowBegin, int rowEnd ) const
{
if( rowEnd < 0 ) rowEnd = m_rows-1;
if( rowBegin <= rowEnd )
return StridedSlice( Index(rowBegin,col), rowEnd-rowBegin+1, m_cols );
else
return StridedSlice( Index(rowBegin,col), rowBegin-rowEnd+1, -m_cols );
}
```

Note that the `Row`

and `Column`

functions are set up in such a way that you can easily request an entire row or column, but are a little more powerful because you can slice a range by passing one or two more parameters. And yes, you can return the row/column in reverse by making your start value larger than your end value.

There is no bounds-checking built into these functions, but you can easily add that.

You could also add something to return an area slice as another `SimpleMatrix<T>`

.

Have fun.

againstrepresenting a matrix in this way. Cache locality will be terrible, and trivial operations like slicing, reshaping or transposing a matrix become a total pain in the arse. – paddy Apr 3 '13 at 3:45considerabledifference in the complexity of the possible solutions. I'm with paddy, on this, by the way. The only reason to use vector-of-vector is to benefit from variable row widths, which by definition a true matrix willnothave. – WhozCraig Apr 3 '13 at 5:23`array<array<double, cols>, rows>> matrix;`

This will put the data in one consecutive memory area, improving cache efficiency. – ogni42 Apr 3 '13 at 7:29