Trying it in MIT Scheme works

```
(define ((K x) y) x)
;Value: k
((k 3) 4)
;Value: 3
```

Apparently, these are the definitions for `K`

and `S`

combinators from a combinatorial logic SKI calculus.

We can define the same function explicitly,

```
(define k (lambda (x) (lambda (y) x)))
;Value: k
((k 3) 4)
;Value: 3
```

Apparently, MIT-Scheme does that for us, just as in case of regular definitions like `(define (fun foo) bar)`

being translated to `(define fun (lambda (foo) bar))`

.

The `S`

combinator would be defined explicitly as

```
(define S (lambda (x) (lambda (y) (lambda (z)
((x z) (y z))))))
(define ((add a) b) (+ a b))
;Value: add
(define (add1 a) (+ a 1))
;Value: add1
(((s add) add1) 3)
;Value: 7
```

This is how currying languages (like e.g. Haskell) work, where every function is a function of one argument. Haskell is very close to the combinatorial logic in that respect, there's no parentheses used at all, and we can write the same definitions simply as

```
_K x y = x
_S x y z = x z (y z)
```

So that `_S (+) (1+) 3`

produces `7`

.