Imagine you have your function already. What does it get? What must it produce?

Given an atom, what does it return? Given a simple list of atoms, what should it return?

```
(defun condense (x)
(typecase x
(number
; then what?
(condense-number x))
(list
; then what?
(if (all-atoms x)
(condense-list-of-atoms x) ; how to do that?
(process-further-somehow
(condense-lists-inside x))))
; what other clauses, if any, must be here?
))
```

What must `condense-lists-inside`

do? According to your description, it is to condense the nested lists inside - each into *a number*, and leave the atoms intact. So it will leave a list of numbers. To *process* that *further somehow*, we already "have" a function, `condense-list-of-atoms`

, right?

Now, how to implement `condense-lists-inside`

? That's easy,

```
(defun condense-lists-inside (xs)
(mapcar #'dowhat xs))
```

Do *what*? Why, `condense`

, of course! Remember, we imagine we have it already. As long as it gets what it's meant to get, it shall produce what it is designed to produce. Namely, given an atom or a list (with possibly nested lists inside), it will produce *a number*.

So now, fill in the blanks, and simplify. In particular, see whether you really need the `all-atoms`

check.

**edit:** actually, using `typecase`

was an unfortunate choice, as it treats NIL as LIST. We need to treat NIL differently, to return a "zero value" instead. So it's better to use the usual `(cond ((null x) ...) ((numberp x) ...) ((listp x) ...) ... )`

construct.

About your new code: you've erred: to process the list of atoms returned after `(mapcar #'condense x)`

, we have a function `calculate`

that does that, no need to go so far back as to `condense`

itself. When you substitute `calculate`

there, it will become evident that the check for `all-atoms`

is not needed at all; it was only a pedagogical device, to ease the development of the code. :) It is OK to make superfluous choices when we develop, if we then simplify them away, *after* we've achieved the goal of *correctness*!

But, removing the `all-atoms`

check will break your requirement #2. The calculation will then proceed as follows

```
(CONDENSE '(2 3 4 (3 1 1 1) (2 3 (1 2)) 5))
==
(calculate (mapcar #'condense '(2 3 4 (3 1 1 1) (2 3 (1 2)) 5)))
==
(calculate (list 2 3 4 (condense '(3 1 1 1)) (condense '(2 3 (1 2))) 5))
==
(calculate (list 2 3 4 (calculate '(3 1 1 1))
(calculate (list 2 3 (calculate '(1 2)))) 5))
==
(calculate (list 2 3 4 6 (calculate '(2 3 3)) 5))
==
(calculate (list 2 3 4 6 8 5))
==
28
```

I.e. it'll proceed in left-to-right fashion instead of the from the deepest-nested level out. Imagining the nested list as a tree (which it is), this would "munch" on the tree from its deepest left corner up and to the right; the code with `all-atoms`

check would proceed strictly by the levels up.

*So the final simplified code is:*

```
(defun condense (x)
(if (listp x)
(reduce #'+ (mapcar #'condense x))
(abs x)))
```

**a remark:** Looking at that last illustration of reduction sequence, a clear picture emerges - of *replacing* each node in the argument *tree* with a *calculate* application. That is a clear case of *folding*, just such that is done over a tree instead of a plain list, as `reduce`

is.

This can be directly coded with what's known as "car-cdr recursion", replacing each `cons`

cell with an application of a combining function `f`

on two results of recursive calls into `car`

and `cdr`

components of the cell:

```
(defun condense (x) (reduce-tree x #'+ 0))
(defun reduce-tree (x f z)
(labels ((g (x)
(cond
((consp x) (funcall f (g (car x)) (g (cdr x))))
((numberp x) x)
((null x) z)
(T (error "not a number")))))
(g x)))
```

As you can see this version is highly recursive, which is not that good.

`condense`

you need to close all parens and put a quote before`(2`

. – Vsevolod Dyomkin Jun 5 '12 at 5:49