I am rewriting this questions since it was poorly formed .
(define (reduce f) ((lambda (value) (if (equal? value f) f (reduce value))) (let r ((f f) (g ())) (cond ((not (pair? f)) (if (null? g) f (if (eq? f (car g)) (cadr g) (r f (caddr g))))) ((and (pair? (car f)) (= 2 (length f)) (eq? 'lambda (caar f))) (r (caddar f) (list (cadar f) (r (cadr f) g) g))) ((and (not (null? g)) (= 3 (length f)) (eq? 'lambda (car f))) (cons 'lambda (r (cdr f) (list (cadr f) (gensym (cadr f)) g)))) (else (map (lambda (x) (r x g)) f)))))) ; (reduce '((lambda x x) 3)) ==> 3 ; (reduce '((lambda x (x x)) (lambda x (lambda y (x y))))) ; ==> (lambda #[promise 2] (lambda #[promise 3] (#[promise 2] #[promise 3]))) ; Comments: f is the form to be evaluated, and g is the local assignment ; function; g has the structure (variable value g2), where g2 contains ; the rest of the assignments. The named let function r executes one ; pass through a form. The arguments to r are a form f, and an ; assignment function g. Line 2: continue to process the form until ; there are no more conversions left. Line 4 (substitution): If f is ; atomic [or if it is a promise], check to see if matches any variable ; in g and if so replace it with the new value. Line 6 (beta ; reduction): if f has the form ((lambda variable body) argument), it is ; a lambda form being applied to an argument, so perform lambda ; conversion. Remember to evaluate the argument too! Line 8 (alpha ; reduction): if f has the form (lambda variable body), replace the ; variable and its free occurences in the body with a unique object to ; prevent accidental variable collision. [In this implementation a ; unique object is constructed by building a promise. Note that the ; identity of the original variable can be recovered if you ever care by ; forcing the promise.] Line 10: recurse down the subparts of f.
I have the above code which does a lambda reduction on a lambda expression ( which is what i want). My problem here is , can someone help me rewrite this implementation(since i am not that experienced with Scheme) so that i extract from the body the part that does alpha-conversion and put it in a separate function, and the part that does the beta-reduction as well. The function reduce is recursive so , the two new created functions need to be single-step , meaning that they will convert only one bounded variable and reduce only one expression.