You can do this insanely fast using the union-find algorithm.

The idea is to have a forest of trees, where each tree represents elements "that are equal". You represent this tree as a simple array, where a[i] either can be the parent of i, -1 if i is the root, or say -2 if i is not yet in a tree.

In your case you would start with the simple tree:

```
1
\
5
```

The next thing you want it to join 6 and 8. However, they are both unassigned, so you you add a new tree. (That is a[6]=-1, a[8]=6):

```
1 6
\ \
5 8
```

Now you want to join 6 and 1. You find out which sets they belong to, by following their parents to the top. Coincidentally they are both roots. In this case we make the smallest tree the child of the other tree. (a[6]=1)

```
1
/ \
6 5
\
8
```

Finally we want to join 9 and 3, they are both unassigned, so we create a new tree. (a[3]=-1, a[9]=3)

```
1 9
/ \ \
6 5 3
\
8
```

Say you also have 5=3? Follow their parents till you reach the roots. You find that they are not already equal, so you merge the trees. Since the 9 controls a less high tree, we add it to one's tree, to get:

```
.1.
/ | \
6 9 5
\ \
8 3
```

As you can see it is now easy to check whether two elements are in the same set. Say you wanna test whether 8 and 3 are equal? Just follow their paths upwards, and you will see that 8 is in the set represented by one, and three in the set represented by 9. Hence they are unequal.

Using the heuristic of always putting the smaller tree under the bigger, gives you an log(n) average find or merge time. The Wikipedia article explains an extra trick, that will make it basically constant time.