# zip function in Racket/Scheme

Given two lists, return a list whose elements are lists of size two, such that for the `i`-th list, the first element is the `i`-th element of the first original list, and the second element is the `i`-th element of the second original list. If one list is smaller than the other, the resulting list is of the smallest size; and so if one of the lists is empty, return an empty list. For example:

``````> (zip '(1 2) '(3 4))
'((1 3) (2 4))

> (zip '(1 2 3) '())
'()
> (zip '() '(4 5 6))
'()
> (zip '(8 9) '(3 2 1 4))
'((8 3) (9 2))
> (zip '(8 9 1 2) '(3 4))
'((8 3) (9 4))
``````
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What have you tried so far? please post the code! otherwise people will think that you want to get you homework done for free ;) – Óscar López Feb 10 '14 at 22:16

Try so:

``````(map cons '(1 2 3) '(a b c))
``````

or so:

``````(map list '(1 2 3) '(a b c))
``````

``````(define zip (lambda (l1 l2) (map list l1 l2)))

->(zip '(1 2 3) '(x y z))
'((1 x) (2 y) (3 z))
``````
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`(map cons '(1 2 3) '(a b c)) ; ==> ((1 . a) (2 . b) (3 . c))`, not the desired result `((1 a) (2 b) (3 c))` – Sylwester May 12 '15 at 10:55
Any function can be used there, as time as the function has 2 input parameters. – alinsoar May 14 '15 at 12:30
Out of curiosity, why the lambda in the `zip` definition? It seems like `(define (zip l1 l2) (map list l1 l2))` would do just as well... ? – cat Apr 4 at 16:49
What you wrote is a syntactic sugar for what I wrote. The form you wrote is expanded in what I wrote during preprocessing. But a better syntactic sugar for composition is present in Haskell under the concept of composition (`o` operator) or under the concept of `section`. In that case there is no need to explicitly pass the name of arguments, as haskell does that for you in the preprocessing. – alinsoar Apr 9 at 10:27

Because you didn't post the code you've written, I'm guessing this is homework. I'll give you some hints to get started, this is the general structure of the solution, fill-in the blanks - it'll be much more fun if you reach the correct answer by your own means!

``````(define (zip lst1 lst2)
(cond ((<???> lst1)  ; if the first list is empty
<???>)        ; then return the empty list
((<???> lst2)  ; if the second list is empty
<???>)        ; then also return the empty list
(else          ; otherwise
(cons (list   ; cons a list with two elements:
<???>  ; the first from the first list
<???>) ; and the first from the second list
(zip <???> <???>))))) ; advance recursion over both lists
``````

I tested the above implementation with the sample inputs, and the results are as expected:

``````(zip '(1 2) '(3 4))
=> '((1 3) (2 4))

(zip '(1 2 3) '())
=> '()

(zip '() '(4 5 6))
=> '()

(zip '(8 9) '(3 2 1 4))
=> '((8 3) (9 2))

(zip '(8 9 1 2) '(3 4))
=> '((8 3) (9 4))
``````
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If you've solved the problem for the first element then you can recurse on the rest of the list:

``````(define (zip l1 l2)
(if (or (null? l1) (null? l2))
'()
(cons (list (car l1) (car l2))
(zip  (cdr l1) (cdr l2)))))
``````

provided you handle the base case where either list is empty.

``````> (zip '(1 2 3 4) '(a b))
((1 a) (2 b))
> (zip '() '(a b))
()
``````
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If your map implementation stops at the shortest list, then `zip` can be defined with `map`, Scheme's list argument and apply. Here's a hint:

``````(define (zip . lsts)
(apply <??> <??> lsts))
``````

RSFI-1's `map` is sufficient. So in Racket you add `(require (only-in srfi/1 map))`

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