The mainstream representation of number, the one that took the world by storm, is positional notation. It's a representation that's tied intimately with the concept of quotient and remainder operations, which you're seeing somewhat from your recursive function defintion. Why is that?

Let's take a quick aside: positional notation is not the only viable representation for number. One way that comes up every so often is a tallying approach, where a number is either zero or one more than a number. We can use sticks. Since we're talking about programs, let's use a **data-type**.

```
Number :== Zero
| Successor(n) where n is a number
```

Read this as "A number is either Zero, or the successor of another number". Or, to code it up in a Scheme that supports structured representations (like Racket), we can write this:

```
(define-struct Zero ())
(define-struct Successor (n))
```

For example, representing **three** with this notation would be `(Successor (Successor (Successor (Zero)))`

. (This representation is called Peano, if I'm remembering right.)

Functions that deal with this kind of structured datatype often have the same **shape** as that of the datatype itself. That is, a function that works on a representation in Peano will look something like this:

```
;; a peano-eating-function-template: peano-number -> ???
(define (a-peano-eating-function-template a-num)
(cond [(Zero? a-num)
...]
[(Successor? a-num)
...
(a-peano-eating-function-template (Successor-n a-num))
...]
```

where the `...`

will be something specific to the particular problem you're trying to solve on Peano numbers. It's a matter of functions following the structure of the data that they're working on. As an concrete example of a Peano-eating function, here's one that turns a piano into a bunch of stars:

```
;; peano->stars: peano-number -> string
;; Turn a peano in a string of stars. We are all made of stars.
(define (peano->stars a-num)
(cond [(Zero? a-num)
""]
[(Successor? a-num)
(string-append "*"
(peano->stars (Successor-n a-num)))]))
```

Anyway, so datatypes lead naturally to functions with particular shapes. This leads us to going back to positional notation. Can we capture positional notation as a datatype?

It turns out that we can! Positional notation, such as decimal notation, can be described in a way similar to how the Peano number description worked. Let's call this representation **Base10**, where it looks like this:

```
Base10 :== Zero
| NonZero(q, r) where q is a Base10, and r is a digit.
Digit :== ZeroD | OneD | TwoD | ... | NineD
```

And if we want to get concrete in terms of programming in a language with structures,

```
(define-struct Zero ())
(define-struct NonZero(q r))
(define-struct ZeroD ())
(define-struct OneD ())
(define-struct TwoD ())
(define-struct ThreeD ())
(define-struct FourD ())
;; ...
```

For example, the number **forty-two** can be represented in Base10 as:

```
(NonZero (NonZero (Zero) (FourD)) (TwoD))
```

Yikes. That looks a bit... insane. But let's lean on this a little more. As before, functions that deal with Base10 will often have a shape that matches Base10's structure:

```
;; a-number-eating-function-template: Base10 -> ???
(define (a-number-eating-function-template a-num)
(cond
[(Zero? a-num)
...]
[(NonZero? a-num)
... (a-number-eating-function-template (NonZero-q a-num))
... (NonZero-r a-num)]))
```

That is, we can get the shape of a recursive function that works on Base10 pretty much for free, just by following the structure of Base10 itself.

... But this is a crazy way to deal with numbers, right? Well... remember that wacky representation for **forty-two**:

```
(NonZero (NonZero (Zero) (FourD)) (TwoD))
```

Here's another way to represent the same number.

```
((0 * 10 + 4) * 10 + 2)
```

Pretty much the same idea. Here, let's get rid of a few more parentheses. We can represent **forty-two** with the following notation:

```
42
```

Our programming languages are hardcoded to know how to deal with this notation for numbers.

What's our equivalent for checking Zero? We know that one.

```
(= n 0) ;; or (zero? n)
```

What's our equivalent for checking NonZero? Easy!

```
(> n 0)
```

What are our equivalents for NonZero-q and NonZero-r?

```
(quotient n 10)
(remainder n 10)
```

Then, we can pretty much plug-and-play to get the shape of recursive functions that deal **positionally** with their numeric inputs.

```
(define (a-decimal-eating-function-template n)
(cond [(= n 0)
...]
[(> n 0)
... (a-decimal-eating-function-template (quotient n 10))
... (remainder n 10)]))
```

Look familiar? :)

For more of this, see a textbook like How to Design Programs.