## Setup

I have a graph library where I am trying to decompose things as much as possible, and the cleanest way to describe it that I found is the following: there is a vanilla type `node`

implementing only a list of edges:

```
class node
{
public:
int* edges;
int edge_count;
};
```

Then, I would like to be able to add interfaces to this whole mix, like so:

```
template <class T>
class node_weight
{
public:
T weight;
};
template <class T>
class node_position
{
public:
T x;
T y;
};
```

and so on. Then, the actual graph class comes in, which is templated on the actual type of node:

```
template <class node_T>
class graph
{
protected:
node_T* nodes;
public:
static graph cartesian(int n, int m)
{
graph r;
r.nodes = new node_T[n * m];
return r;
}
};
```

The twist is that it has named constructors which construct some special graphs, like a Cartesian lattice. In this case, I would like to be able to add some extra information into the graph, depending on what interfaces are implemented by `node_T`

.

What would be the best way to accomplish this?

## Possible solution

I thought of the following humble solution, through `dynamic_cast<>`

:

```
template <class node_T, class weight_T, class position_T>
class graph
{
protected:
node_T* nodes;
public:
static graph cartesian(int n, int m)
{
graph r;
r.nodes = new node_T[n * m];
if (dynamic_cast<node_weight<weight_T>>(r.nodes[0]) != nullptr)
{
// do stuff knowing you can add weights
}
if (dynamic_cast<node_position<positionT>>(r.nodes[0]) != nullptr)
{
// do stuff knowing you can set position
}
return r;
}
};
```

which would operate on `node_T`

being the following:

```
template <class weight_T, class position_T>
class node_weight_position :
public node, public node_weight<weight_T>, public node_position<position_T>
{
// ...
};
```

## Questions

Is this -- philosophically -- the right way to go? I know people don't look nicely at multiple inheritance, though with "interfaces" like these it should all be fine.

There are unfortunately problems with this. From what I know at least, `dynamic_cast<>`

involves quite a bit of run-time overhead. Hence, I run into a problem with what I had solved earlier: writing graph algorithms that require weights independently of whether the actual `node_T`

class has weights or not. The solution with this 'interface' approach would be to write a function:

```
template <class node_T, class weight_T>
inline weight_T get_weight(node_T const & n)
{
if (dynamic_cast<node_weight<weight_T>>(n) != nullptr)
{
return dynamic_cast<node_weight<weight_T>>(n).weight;
}
return T(1);
}
```

but the issue with it is that it works using run-time information (`dynamic_cast`

), yet in principle I would like to decide it at compile-time and thus make the code more efficient.

If there is a different solution that would solve both problems, especially a cleaner and better one than what I have, I would love to hear about it!

`dynamic_cast`

is used to check if a particular interface was actually implemented. The problem is that the type`node_T`

is known to the compiler at compile-time, hence there should be a way to used that knowledge and vary behavior of functions depending on the actual type. – fledgling Cxx user Nov 18 '11 at 1:38