# Scheme: Using Abstract List Functions without Recursion

How can I write a function using abstract list functions (`foldr`, `foldl`, `map`, and `filter`) without recursion that consumes a list of numbers `(list a1 a2 a3 ...)` and produces the alternating sum `a1 - a2 + a3 ...`?

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## 3 Answers

Here's a hint:

``````a1 - a2 + a3 - a4 ... aN
``````

is the same as

``````a1 - (a2 - (a3 - (a4 - ... (aN - 0) ...)))
``````

Is it obvious how to solve it now?

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Here's a possible solution:

``````(define (sum-abstract-list-functions lst)
(car
(foldl
(lambda (e acc)
(cons (+ (car acc) (* e (cdr acc)))
(- (cdr acc))))
'(0 . 1)
lst)))
``````

I'm only using `foldl`, `cons`, `car`, `cdr`. The trick? accumulating two values: the actual sum (in the `car` part of the accumulator), and the current sign (+/-1 in the `cdr` part of the accumulator). The accumulator gets initialized in 0 for the sum and +1 for the sign, and at the end I return the sum, the `car` part of the accumulator. Use it like this:

``````(sum-abstract-list-functions (list 1 2 3 4 5))
> 3
``````

EDIT :

As has been pointed out, this solution is the simplest of all:

``````(define (sum-abstract-list-functions lst)
(foldr - 0 lst))
``````
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Is this homework? Well, we can split this problem into two subproblems:

• Take a list `(a1 a2 a3 a4 ... a2n-1 a2n)` and alternately negate elements from it, to produce `(a1 (- a2) a3 (- a4) ... a2n-1 (- a2n))`.
• Sum the elements of that resulting list.

The second part is the trivial one:

``````(define (sum xs)
(foldl + 0 xs))
``````

The first is the harder one, but it's not too hard. You need to transform the list while keeping a boolean state that indicates whether you're examining an even or an odd element, and negate or not accordingly. I can see three ways of doing this:

• The mutational way: put the state into the closure that you pass to a `map`. The closure then modifies its environment from one call to the next.
• Keep the state in the fold results: the fold result is a pair that contains the "real" result and the state as an element.
• Use a different sort of abstract list function.

Here's an example of the third approach (and if this is for homework, I bet your teacher may well be incredulous you came up with it):

``````(define (contextual-foldr compute-next
compute-init
advance-context
left-context
xs)
(if (null? xs)
(compute-rightmost-result left-context)
(compute-next left-context
(car xs)
(contextual-foldr compute-next
compute-init
advance-context
(advance-context (car xs) left-context)
(cdr xs)))))

(define (contextual-map contextual-fn advance-context left-context xs)
(contextual-foldr (lambda (left elem rest)
(cons (fn left elem) rest))
'()
advance-context
left-context
xs))

(define (alternate-negations xs)
(contextual-map (lambda (negate? elem)
(if negate?
(- elem)
elem))
not
#f
xs))
``````
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