# Getting the sum of the elements in the tree in Scheme

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)
3)
(4
(5 6))
7
(8 9 10))
``````

then

``````(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)
init
(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)
0
(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)
0
(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)
(cond
[(empty-tree? tree)
accum]
[(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])
(cond
[(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
(cond
[(null? listy) empty]
[(pair? listy) (ctree (->tree (car listy))
(->tree (cdr listy)))]
[else listy]))
``````