**Important edit**: You probably have a bug in your function. I do not know about Simpson’s method and can not correct it. But you are calculating some value into `*summation*`

but at the end you forget everything about your computing and only return the result like you had defined:

(defun simpsons (f a b n)
(let ((h (/ (- b a) n)))
(* (/ h 3.0) (+ (funcall f a) (funcall f (+ (* n h) a))))))

`defparameter`

and `defvar`

are meant to define so called “special” variables. Here you need bindings that are local to your function ; `let`

would be better suited.

What’s more `defvar`

only assigns the variable if it is not already assigned. That means that if you call your function multiple times with different values you will get **wrong** results.

Regarding style lispers would make the function return the value, not print it. Just calling it in the interactive environment will print the result. And you can also use `(trace simpsons)`

to see how your function is called and its output.

Do not put closing parentheses on a line by themselves.

Finally people usually use two semicolons for comments on a line by itself while they use a single semicolon for comments at the end of the line.

Here is your function with these applied:

;; Integration by Simpson's rule; CL code
;; Found to be working correctly with 'sbcl'
(defun simpsons (f a b n)
(let ((summation 0)
(h (/ (- b a) n)))
(loop for k from 2 below (- n 1) by 2
do (setf summation (+ summation (* 2 (funcall f (+ (* k h) a))))))
(loop for k from 1 below n by 2
do (setf summation (+ summation (* 4 (funcall f (+ (* k h) a))))))
(setf summation (+ (funcall f a) (funcall f (+ (* n h) a))))
(* (/ h 3.0) summation)))
(defun cube(x)
(* x x x))
;; Passing around the function to be integrated
(simpsons 'cube 2 3 8) ; demonstrating higher-order functions

Explaination on `let`

: `let`

defines a *new* lexical binding. That is

(let ((summation 0)) …)

makes the name `summation`

bound to the value `0`

in the body of the `let`

expression. The `setf`

expressions *changes* a place which can be a bit complex to describe (see CLHS: Section 5.1 Generalized Reference). In the context

(let ((summation 0))
(setf summation (+ summation 1)))

it changes the binding of `summation`

from the value `0`

to the value `1`

. While using

(let ((summation 0))
(let ((summation (+ summation 1)))
;; Here summation is bound to the value 1
…)
;; Here summation is bound to the value 0
…)

makes **two** lexical bindings for `summation`

, the first to the value `0`

and the second, shadowing the first for the extent of the second `let`

, to the value `1`

.