In this loop,

```
for (int i = 0; i < 12; i++)
{
text[i] = characters.charAt(r.nextInt(characters.length()));
}
```

Consider what happens when `r.nextInt(characters.length())`

returns the same number in two different iterations.

Similarly for `Math.random() * rl.length`

in the other loop.

## An array shuffler needs to track which elements are already shuffled

Let's say we start with:

```
a b c d e f
```

Consider the first element of the shuffled array. It needs to be randomly picked from the set `{a, b, c, d, e, f}`

with 1/6 probability for each element.

The second element of the shuffled array needs to be randomly picked from `{a, b, c, d, e, f} - {shuffled[0]}`

i.e. all elements of the original array, minus what was picked for the first position, this time with 1/5 probability.

Similarly, the third element comes from `{a, b, c, d, e, f} - {shuffled[0], shuffled[1]}`

, with 1/4 probability on each, and so on.

If you're shuffling an array *in-place*, then you can move elements around by swapping, which ends up keeping track of the remaining elements automatically. Say `e`

was the first choice. See what happens if we swap `a`

and `e`

:

```
e b c d a f
^ . . . . .
```

Since the picked element was moved to index 0, all remaining elements are now in indices 1
through 5. Now the next element just needs to be picked from between indices 1 to 5.

Let's say `b`

is picked next, thus it's swapped with itself:

```
e b c d a f
^ ^ . . . .
```

No we have the remaining element at indices 2 to 5. The algorithm can keep going in this fashion until index 4, at which point the entire array will be shuffled. Because element swapping lets you easily keep track of what's remaining, **it's easier to shuffle an array in-place**.

If you look into the JDK source, you'll see that `Collections.shuffle()`

does the same thing, with one optimization.