# curry in scheme

I have this `curry` function:

``````(define curry
(lambda (f) (lambda (a) (lambda (b) (f a b)))))
``````

I think it's like `(define curry (f a b))`.

my assignment is to write a function `consElem2All` using `curry`，which should work like

``````(((consElem2All cons) 'b) '((1) (2 3) (4)))
>((b 1) (b 2 3) (b 4))
``````

I have wrote this function in a regular way:

``````(define (consElem2All0 x lst)
(map (lambda (elem) (cons x elem)) lst))
``````

but still don't know how to transform it with `curry`. Can anyone help me?

bearzk

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You should begin by reading about currying. If you don't understand what curry is about, it may be really hard to use it... In your case, http://www.engr.uconn.edu/~jeffm/Papers/curry.html may be a good start.

One very common and interesting use of currying is with functions like reduce or map (for themselves or their arguments).

# Let's define two currying operators!

``````(define curry2 (lambda (f) (lambda (arg1) (lambda (arg2) (f arg1 arg2)))))
(define curry3 (lambda (f) (lambda (arg1) (lambda (arg2) (lambda (arg3) (f arg1 arg2 arg3))))))
``````

Then a few curried mathematical functions:

``````(define mult (curry2 *))
(define double (mult 2))

``````

And then come the curried reduce/map:

``````(define creduce (curry3 reduce))
(define cmap (curry2 map))
``````

# Using them

First reduce use cases:

``````(define sum ((creduce +) 0))
(sum '(1 2 3 4)) => 10

(define product (creduce * 1))
(product '(1 2 3 4)) => 24
``````

And then map use cases:

``````(define doubles (cmap double))
(doubles '(1 2 3 4)) => (2 4 6 8)

(define bump (cmap increment))
(bump '(1 2 3 4)) => (2 3 4 5)
``````

I hope that helps you grasp the usefulness of currying...

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Nitpicks: Your add definition is missing its closing parenthesis and your (creduce + 0) calls should be ((creduce +) 0) as creduce expects one argument. –  Julien Rousseau Aug 4 '13 at 13:29
I usually forbid myself to post code I didn't copy/pasted from a successful running code. Nice catch! –  Nowhere man Aug 4 '13 at 22:56

So your version of curry takes a function with two args, let's say:

``````(define (cons a b) ...)
``````

and turns that into something you can call like this:

``````(define my-cons (curry cons))
((my-cons 'a) '(b c)) ; => (cons 'a '(b c)) => '(a b c)
``````

You actually have a function that takes three args. If you had a `curry3` that managed 3-ary functions, you could do something like:

``````(define (consElem2All0 the-conser x lst) ...)
``````

(like you did, but allowing cons-like functions other than cons to be used!)

and then do this:

``````(define consElem2All (curry3 consElem2All0))
``````

You don't have such a `curry3` at hand. So you can either build one, or work around it by "manually" currying the extra variable yourself. Working around it looks something like:

``````(define (consElem2All0 the-conser)
(lambda (x lst) ...something using the-conser...))
(define (consElem2All the-conser)
(curry (consElem2All0 the-conser)))
``````

Note that there's one other possible use of curry in the map expression itself, implied by you wrapping a lambda around cons to take the element to pass to cons. How could you curry `x` into `cons` so that you get a one-argument function that can be used directly to map?...

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``````(define (consElem2All0 x lst)
(map ((curry cons) x) lst))
``````
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