# How is filter implemented?

Need help on this one using scheme function Return a list containing all elements of a given list that satisfy a given predicate. For example, `(filter (lambda (x) (< x 5)) '(3 9 5 8 2 4 7))` should return `(3 2 4)`.

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Please try to explain your problem more clearly. Are you trying to figure out how to implement the filter function? –  mwd Feb 27 '12 at 1:42
Is this homework? Also, what have you tried already? –  amindfv Feb 27 '12 at 3:15
I'm forced to downvote the question until it explains what the problem is. The question currently only has a description of the filter function. I can not tell what the poster is having difficulty with yet. –  dyoo Feb 27 '12 at 4:23
It's an implentation detail that is subject to change and depends on your vendor ;D –  Thomas Eding Feb 28 '12 at 17:39

A simple way to write the `filter` procedure:

``````(define (my-filter pred lst)
(cond ((null? lst) null)
((pred (first lst))
(cons (first lst) (my-filter pred (rest lst))))
(else (my-filter pred (rest lst)))))
``````

Notice that I named the procedure `my-filter`, because a built-in procedure called `filter` already exists and it's not a good idea to overwrite its definition.

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filterb - just in case there is already a function called filter.

``````(define filterb
(lambda (pred lst)
(cond ((null? lst) '())
((pred (car lst)) (cons (car lst) (filterb pred (cdr lst))))
(else (filterb pred (cdr lst))))))
``````

Here it is, though I am sure it can be made to look nicer.

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The textbook definition of filter is the (non-tail) recursive one that other posters have shown—and it's important to understand that one. However, if you're writing it as a library function, it's useful to figure out how to do it with tail recursion, so that you don't blow up the stack or heap with long lists:

``````(define (filter pred? list)
(define (filter-aux result current-pair xs)
(cond ((null? xs)
result)
((pred? (car xs))
(set-cdr! current-pair
(cons (car xs)
'()))
(filter-aux result
(cdr current-pair)
(cdr xs)))
(else
(filter-aux result
current-pair
(cdr xs)))))
(let ((init (cons 'throw-me-out '())))
(filter-aux (cdr init) init list)))
``````

Or, using the `let loop` syntax:

``````(define (filter pred? xs)
(let ((result (cons 'throw-me-out '()))
(xs xs))
(let loop ((current-pair result))
(cond ((null? xs)
(cdr result))
((pred? (car xs))
(set-cdr! current-pair
(cons (car xs) '()))
(loop (cdr current-pair) (cdr xs)))
(else
(loop current-pair (cdr xs)))))))
``````
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For an alternate tail-recursive `filter` that doesn't require mutable lists, you could use something like this:

``````(define (my-filter f lst)
(define (iter lst result)
(cond
((null? lst) (reverse result))
((f (car lst)) (iter (cdr lst)
(cons (car lst) result)))
(else (iter (cdr lst)
result))))
(iter lst '()))
``````

Reverse requires you to walk the list a second time, but it can be implemented in O(n) time with constant stack space on immutable lists, so the overall time is still O(n).

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Try defining `filter` as an instance of fold-right:

``````(define (my-filter op xs)
(fold-right
(lambda (next result) ...)
'()
xs))
``````

Hint: use `if` and `cons`

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