I did very similar exercise some time ago. This looks like it could be of use to you:

```
;; Define struct `point'
(defstruct point x y)
;; Define methods specializing on `point'
(defgeneric add (a b))
(defgeneric subtract (a b))
(defgeneric distance (a b))
(defgeneric projection (a))
(defmethod add ((this point) (that point))
(make-point :x (max (point-x this) (point-x that))
:y (max (point-y this) (point-y that))))
(defmethod subtract ((this point) (that point))
(make-point :x (min (point-x this) (point-x that))
:y (min (point-y this) (point-y that))))
(defmethod distance ((this point) (that point))
(let ((a (add this that)) (b (subtract this that)))
(make-point :x (- (point-x a) (point-x b))
:y (- (point-y a) (point-y b)))))
(defmethod projection ((this point))
(sqrt (+ (expt (point-x this) 2) (expt (point-y this) 2))))
;; Define helper functions
(defun angle (a b c)
(acos (/ (+ (* a a) (* b b) (- (* c c))) (* 2 a b))))
(defun radian->degree (radian) (/ (* 180 radian) pi))
;; Define struct `triangle'
(defstruct triangle
(a nil :type (or null point))
(b nil :type (or null point))
(c nil :type (or null point)))
;; Define methods specializing on `triangle'
(defgeneric angles-of (triangle))
(defgeneric sides-of (triangle))
(defgeneric points-of (triangle))
(defmethod points-of ((this triangle))
(let ((result (list (triangle-a this) (triangle-b this) (triangle-c this))))
(nconc result result)))
(defmethod sides-of ((this triangle))
(loop for (p . rest) on (points-of this)
for i from 0 below 3
collect (projection (distance p (car rest))) into result
finally (return (nconc result result))))
(defmethod angles-of ((this triangle))
(loop for (a b c) on (sides-of this)
for i from 0 below 3
collect (radian->degree (angle a b c)) into result
finally (return (nconc result result))))
;; Create some test triangle
(defvar *pythagorean-triangle*
(make-triangle :a (make-point :x 1 :y 2)
:b (make-point :x 4 :y 2)
:c (make-point :x 4 :y 6)))
;; Finally! don't forget to
(setf *print-circle* t)
;; so you can see circular lists' content
(angles-of *pythagorean-triangle*)
#1=(90.00000265626015d0 36.86989784081561d0 53.13009995842113d0 . #1#)
```

Few notes, I saw in another post there was some confusion about the form

```
(loop for <list-like expression> in some-list ...)
```

This `list-like expression`

is what is usually called "destructuring bind". It is a limited pattern matching facility. Effectively, this is a pattern which maps symbols on you defined inside the pattern to whatever values found in the list you are iterating over.

So, for example, `(loop for (x y) on '(1 2 3 4))`

will bind `x`

and `y`

to `1`

and `2`

, then `2`

, `3`

, then `3`

, `4`

and finally `4`

, `nil`

. Of course you can use more variables / you can use dotted list for the pattern etc.