The second rule basically says that `F`

is the factorial of `N`

**if** `N`

is greater than zero **and** there is a number `N1`

which is the result of `N-1`

**and** `F1`

is the factorial of `N1`

**and** `F`

is the product of `N`

and `F1`

.

**Example**

Let's say that you want to find the factorial of 3.

```
-? factorial(3,F).
```

Prolog puts `factorial(3,F)`

on the stack of goals and then looks for rules whose head match the first goal. There are two rules for `factorial/2`

(the fact `factorial(0,1)`

can be seen as a rule without body), but for the first 0 does not unify with 5 so it cannot be used. The second unifies with `N`

being instantiated to 5 and Prolog adds the conditions to the stack which becomes:

```
3 > 0, N1 is 3-1, factorial(N1,F1), F is 3*F1
```

The first goal is satisfied as 3 is greater than zero. The second one is satisfied by binding `N1`

to the result of the arithmetic evaluation of `3-1`

so the stack of goals is now:

```
factorial(2,F1), F is 3*F1
```

Again, Prolog looks for rules that might be used to satisfy `factorial(2,F1)`

and uses the second one (`N`

unifies with 2 and `F`

with `F1`

and different names are used for the variables) :

```
2 > 0, N2 is 2-1, factorial(N2,F2), F1 is 2*F2, F is 3*F1
```

Next, `2 > 0`

is true and `N2`

is unified with the arithmetic result of `2-1`

so the stack of goals becomes:

```
factorial(1,F2), F1 is 2*F2, F is 3*F1
```

Using again the second rule for `factorial/2`

:

```
1 > 0, N3 is 1-1, factorial(N3,F3), F2 is 1*F3, F1 is 2*F2, F is 3*F1
```

`N3`

becomes zero (when `N3 is 1-1`

is being satisfied):

```
factorial(0,F3), F2 is 1 * F3, F1 is 2*F2, F is 3*F1
```

At this point, the first rule for `factorial/2`

can be used to satisfy `factorial(0, F3)`

, but a **choice point** is created as there are more rules that can be used. So, `factorial(0,F3)`

succeeds by instantiating `F3`

to 1.

```
F2 is 1 * 1, F1 is 2 * F2, F is 3 * F3
```

By satisfying all the goals left on the stack, `F`

becomes 6 and you get your first solution. But, there was a choice point for `factorial(0, F3)`

. The second rule can be used at that point:

```
0>0, N4 is 0-1, factorial(N4,F4), F3 is 0*F4, F2 is 1*F3, F1 is 2*F2, F is 3*F3
```

But `0>0`

fails and the execution stops as there where no other choice points to backtrack to.

You can avoid leaving that useless choice point for `factorial(0,_)`

by using a [green] cut operator.

```
factorial(0, 1) :- !.
```