This states that:

`Nat`

is a type.

`Zero`

has type `Nat`

. This represents the natural number 0.

If `n`

has type `Nat`

, then `Succ n`

has type `Nat`

. This represents the natural number *n*+1.

So, for example, `Succ (Succ Zero)`

represents 2, `Succ (Succ (Succ Zero))`

represents 3, `Succ (Succ (Succ (Succ Zero)))`

represents 4, and so on. (This system of defining the natural numbers from 0 and successors is called the Peano axioms.)

In fact, `Zero`

and `Succ`

are just special kinds of functions *(constructors)* that are declared to create `Nat`

values:

```
Zero :: Nat
Succ :: Nat -> Nat
```

The difference from regular functions is that you can take them apart with pattern-matching:

```
predecessor :: Nat -> Nat
predecessor Zero = Zero
predecessor (Succ n) = n
```

Nothing about this is special to recursive algebraic data types, of course, just algebraic data types; but the simple fact that an algebraic data type can have a value of the same type as one of its fields is what creates the recursion here.

`Succ`

with`1 +`

. Every natural number is`1 + (1 + ( ... (1 + 0) ... ))`

for a suitable number of operations. – Daniel Fischer Mar 31 '12 at 13:21