In your first example, your function will recursively compute `1+1+1+1+0 = 4`

to find the correct result.

In your second example, it will run through the whole list, add 1 per (non-matching) element, and finally **add** `nil`

. So it actually computes `1+1+1+1+1+1+nil`

, which is incorrect since `nil`

is not a number, hence the error message. If you replace `nil`

by zero, it computes `1+1+1+1+1+1+0`

which is wrong.

So your basic problem is that you recursively add `1`

and, reaching the end of the list, you would like to throw away what you computed until then. But you have an addition pending which you cannot escape.

The easiest way is to change from a recursive to a tail-recursive solution, which is technically a plain `goto`

. Here the addition is done by incrementing a variable, not by unwinding the call stack, which makes it easy to throw away the result from the previous additions and just return `nil`

because there is no addition pending.

A (tail-)recursive solution could be:

```
(defun myposition (letter lst)
(labels ((sub (lst pos)
(cond
((null lst) nil)
((equal (car lst) letter) pos)
(t (sub (cdr lst) (1+ pos))))))
(if (atom lst) nil (sub lst 0))))
```

This will work in Common Lisp, but technically, if your implementation does no tail call optimisation, it might still blow the stack for large lists. That's why Common Lisp prefers iterative solutions, such as using the `loop`

macro:

```
(defun myposition (letter lst)
(when (consp lst)
(loop for c in lst for i from 0
when (equal c letter) return i)))
```