Assuming there are no isolated vertices in the graph you only need to add max(|sources|,|sinks|) edges to make it strongly connected.

Let T={t_{1},…,t_{n}} be the sinks and {s_{1},…,s_{m}} be the sources of the DAG. Assume that n <= m. (The other case is very similar). Consider a bipartite graph G(T,S) between the two sets defined as follows. G(T,S) has an edge (t_{i},s_{j}) if and only if t_{i} can be reached from s_{j}.

Let M be a maximal matching in G(T,S). Without loss of generality assume that M consists of k edges: {(t_{1},s_{1}),(t_{2},s_{2}),…,(t_{k},s_{k})}. In the original graph DAG G, add directed-edges {(t_{1}->s_{2}),(t_{2}->s_{3}),…,(t_{k−1}->s_{k}),(t_{k}->s_{1})}. It's easy to see that by adding these edges, the vertices induced by M are strongly connected in G.

Now consider the remaining vertices in G(T,S). Because M maximal, each vertex in S−M (resp. T−M)should be connected to a vertex in T (resp. S−M). So we pair up the remaining vertices arbitrarily, say {(t_{k+1},s_{k+1}),…,(t_{n},s_{n})} and add the corresponding directed edges in G. For each remaining source vertex source s_{i} (i belongs to {n+1,…,m} we add the edge (t_{1}->s_{i}) in G. Thus the total number of edges added is max(|sources|,|sinks|).

**EDIT: Adding a couple of Examples**

For the example in your input. We fist compute a maximal matching, say:

```
3--1
4--2
7--5
8--6
```

So we add the edges:

```
3->2
4->5
7->6
8->1
```

The remaining (sink) vertex not present in the matching is 9 and so we add the arc from 9 to any source vertex in the matching, say `9->1`

.

Here's another example that illustrates all the steps of the algorithm:

Input Graph:

```
12 3 5 9 10 (sources)
\|/ /|\ \/
4 6 7 8 11 (sinks)
```

Maximal Matching:

```
4--1
6--5
11--9
```

So we add the edges:

```
4->5
6->9
11->1
```

Now the remaining sinks are `{7, 8}`

and the remaining sources are `{2, 3, 10}`

. We arbitrary pair 7 with say 2 and 8 with say 3 and add:

```
7->2
8->3
```

Finally, the remaining (source) vertex is 10 and we add:

```
4->10
```