Write a procedure, (fold-right-tree op id tree), that gathers together the leaves of the tree using op, analogous to fold-right on lists. So if tree has value

(((1 2)
  (5 6))
 (8 9 10))


(fold-right-tree + 0  tree)

has value 55.

--I wanted to define code which sums all element in tree


    (#%require racket)
    (define nil empty) 

    (define (reduce op init lst)
      (if (null? lst)
          (op (car lst)
              (reduce op init (cdr lst)))))

    (define fold-right reduce)

    (define (sum-list lst)
      (if (null? lst) 0
          (+ (car lst) (sum-list (cdr lst)))

(define (leaf? x)
  (not (pair? x)))

    (define (fold-right-tree op init tree)
        (lambda (tree)
          (if (null? tree)
              (if (leaf? tree)
                  (sum-list (list tree))
                  (fold-right op init (map fold-right-tree op init tree))))))

    (fold-right-tree (lambda (x,y) (+ x y)) 0 '((1) (2 3 4) (((5)))) )

Output should return sum of tree elements, but returns #<procedure>

what is my problem in it?

I also tried this one but this time I got Error for mapping

(define (fold-right-tree op init tree)
      (if (null? tree)
          (if (leaf? tree)
              (fold-right op init (list tree))
              (+ (fold-right-tree op init (map car tree)) (fold-right-tree op init (map cdr tree))))))

(fold-right-tree sum 0 '((1) (2 3 4) (((5)))) )
  • Right off the bat, I see a bug. If tree is null?, why do you ignore the caller's init value and return 0? What if they are multiplying? Or what if they are reducing strings through some formatting function? Same remarks about your hard-coded +; you must use the caller's op! – Kaz Nov 7 at 3:12

From the problem specification, you could simply get all the leaves of the tree (with the flatten function) and then apply the relevant fold operation, like in:

(define (fold-right-tree op id tree)
  (foldr op id (flatten tree)))

(fold-right-tree + 0 '((1) (2 3 4) (((5)))))  ; => 15

This has been tested in Dr.Racket.


With suitable accessors & predicates for trees (leaf?, empty-tree?, left-subtree & right-subtree) then the obvious definition is:

(define (fold-right-tree op accum tree)
    [(empty-tree? tree)
    [(leaf? tree)
     (op accum tree)]
    [else (fold-right-tree op
                           (fold-right-tree op accum (right-subtree tree))
                           (left-subtree tree))]))

This has the advantage that it is completely agnostic about tree representation: all it knows is the names of the accessors. Indeed you could make it really agnostic:

(define (fold-right-tree op init tree
                         #:empty-tree? (empty? empty-tree?)
                         #:leaf? (lief? leaf?)
                         #:left-subtree (left left-subtree)
                         #:right-subtree (right right-subtree))
  (let frt ([a init] [t tree])
      [(empty? t) a]
      [(lief? t) (op a t)]
      [else (frt (frt a (right t)) (left t))])))

Now it will walk any kind of binary tree.

Here are suitable definitions for trees which are in fact made of conses:

;;; Tree abstraction
(define (leaf? treeish)
  (not (pair? treeish)))

(define empty-tree? null?)
(define left-subtree car)
(define right-subtree cdr)

(define cons-tree cons)
(define empty-tree '())

(define (->tree listy
                #:empty-tree (empty empty-tree)
                #:cons-tree (ctree cons-tree))
  ;; turn a cons tree into a tree
    [(null? listy) empty]
    [(pair? listy) (ctree (->tree (car listy))
                          (->tree (cdr listy)))]
    [else listy]))

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