I couldn't understand the Y-combinator, so I tried to implement a function that enabled recursion without native implementation. After some thinking, I ended up with this:

```
Y = λx.(λv.(x x) v)
```

Which is shorter than the actual one:

```
Y = λf.(λx.f (x x)) (λx.f (x x))
```

And, for my surprise, worked. Some examples:

```
// JavaScript
Y = function(x){
return function(v){
return x(x, v);
};
};
sum = Y(function(f, n){
return n == 0 ? 0 : n + f(f, n - 1);
});
sum(4);
; Scheme
(define Y (lambda (x) (lambda (v) (x x v))))
(define sum (Y
(lambda (f n)
(if (equal? n 0)
0
(+ n (f f (- n 1)))))))
(sum 4)
```

Both snippets output 10 (summation from 0 to 4) as expected.

What is this, why it is shorter and why we prefer the longer version?

`x`

to`x`

, instead of passing the application of`x`

to`v`

to`x`

. What you've implemented is`Y = λx.(λv.(x x) v)`

. – outis Dec 22 '12 at 23:58