**U combinator**

The U combinator takes a function and applies it to itself. So the function you give it should at least have one parameter that will bind to the function (itself)

In the example below, we have no exit condition, so we will just loop indefinitely until a stack overflow happens

```
const U = f => f (f)
U (f => (console.log ('stack overflow imminent!'), U (f)))
```

We can stop the infinite recursion using a variety of techniques. Here, I'll write our anonymous function to return *another* anonymous function that's waiting for an input; in this case, some number. When a number is supplied, if it is greater than 0, we will continue recurring, otherwise return 0.

```
const log = x => (console.log (x), x)
const U = f => f (f)
// when our function is applied to itself, we get the inner function back
U (f => x => x > 0 ? U (f) (log (x - 1)) : 0)
// returns: (x => x > 0 ? U (f) (log (x - 1)) : 0)
// where f is a reference to our outer function
// watch when we apply an argument to this function, eg 5
U (f => x => x > 0 ? U (f) (log (x - 1)) : 0) (5)
// 4 3 2 1 0
```

What's not immediately apparent here is that our function, when first applied to itself using the `U`

combinator, it returns a function waiting for the first input. If we gave a name to this, can effectively construct recursive functions using lambdas (anonymous functions)

```
const log = x => (console.log (x), x)
const U = f => f (f)
const countDown = U (f => x => x > 0 ? U (f) (log (x - 1)) : 0)
countDown (5)
// 4 3 2 1 0
countDown (3)
// 2 1 0
```

Only this isn't *direct* recursion – a function that calls itself using its own name. Our definition of `countDown`

does not reference itself inside of its body and still recursion is possible

```
// direct recursion references itself by name
const loop = (params) => {
if (condition)
return someValue
else
// loop references itself to recur...
return
```**loop** (adjustedParams)
}
// U combinator does not need a named reference
// no reference to `countDown` inside countDown's definition
const countDown = U (f => x => x > 0 ? U (f) (log (x - 1)) : 0)

**How to remove self-reference from an existing function using U combinator**

Here I'll show you how to take a recursive function that uses a reference to itself and change it to a function that employs the U combinator to in place of the self reference

```
const factorial = x =>
x === 0 ? 1 : x * factorial (x - 1)
console.log (factorial (5)) // 120
```

Now using the U combinator to replace the inner reference to `factorial`

```
const U = f => f (f)
const factorial = U (f => x =>
x === 0 ? 1 : x * U (f) (x - 1))
console.log (factorial (5)) // 120
```

The basic replacement pattern is this. Make a mental note, we will be using a similar strategy in the next section

```
// self reference recursion
const foo = x => ... foo (nextX) ...
// remove self reference with U combinator
const foo = U (f => x => ... U (f) (nextX) ...)
```

**Y combinator**

related: the U and Y combinators explained using a mirror analogy

In the previous section we saw how to transform self-reference recursion into a recursive function that does not rely upon a named function using the U combinator. There's a bit of an annoyance tho with having to remember to always pass the function to itself as the first argument. Well, the Y-combinator builds upon the U-combinator and removes that tedious bit. This is a good thing because removing/reducing complexity is the primary reason we make functions

First, let's derive our very own Y-combinator

```
// standard definition
const Y = f => f (Y (f))
// prevent immediate infinite recursion in applicative order language (JS)
const Y = f => f (
```**x =>** Y (f) **(x)**)
// remove reference to self using U combinator
const Y = **U (h =>** f => f (x => **U (h)** (f) (x))**)**

Now we will see how it's usage compares to the U-combinator. Notice, to recur, instead of `U (f)`

we can simply call `f ()`

```
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
Y (f => (console.log ('stack overflow imminent!'), f ()))
```

Now I'll demonstrate the `countDown`

program using `Y`

– you'll see the programs are almost identical but the Y combinator keeps things a bit cleaner

```
const log = x => (console.log (x), x)
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
const countDown = Y (f => x => x > 0 ? f (log (x - 1)) : 0)
countDown (5)
// 4 3 2 1 0
countDown (3)
// 2 1 0
```

And now we'll see `factorial`

as well

```
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
const factorial = Y (f => x =>
x === 0 ? 1 : x * f (x - 1))
console.log (factorial (5)) // 120
```

As you can see, `f`

becomes the mechanism for recursion itself. To recur, we call it like an ordinary function. We can call it multiple times with different arguments and the result will still be correct. And since it's an ordinary function parameter, we can name it whatever we like, such as `recur`

below -

```
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
const fibonacci = Y (recur => n =>
n < 2 ? n : recur (n - 1) + (n - 2))
console.log (fibonacci (10)) // 55
```

**U and Y combinator with more than 1 parameter**

In the examples above, we saw how we can loop and pass an argument to keep track of the "state" of our computation. But what if we need to keep track of additional state?

We *could* use compound data like an Array or something...

```
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
const fibonacci = Y (f => ([a, b, x]) =>
x === 0 ? a : f ([b, a + b, x - 1]))
// starting with 0 and 1, generate the 7th number in the sequence
console.log (fibonacci ([0, 1, 7]))
// 0 1 1 2 3 5 8 13
```

But this is bad because it's exposing internal state (counters `a`

and `b`

). It would be nice if we could just call `fibonacci (7)`

to get the answer we want.

Using what we know about curried functions (sequences of unary (1-paramter) functions), we can achieve our goal easily without having to modify our definition of `Y`

or rely upon compound data or advanced language features.

Look at the definition of `fibonacci`

closely below. We're immediately applying `0`

and `1`

which are bound to `a`

and `b`

respectively. Now fibonacci is simply waiting for the last argument to be supplied which will be bound to `x`

. When we recurse, we must call `f (a) (b) (x)`

(not `f (a,b,x)`

) because our function is in curried form.

```
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
const fibonacci = Y (f => a => b => x =>
x === 0 ? a : f (b) (a + b) (x - 1)) (0) (1)
console.log (fibonacci (7))
// 0 1 1 2 3 5 8 13
```

This sort of pattern can be useful for defining all sorts of functions. Below we'll see two more functions defined using the `Y`

combinator (`range`

and `reduce`

) and a derivative of `reduce`

, `map`

.

```
const U = f => f (f)
const Y = U (h => f => f (x => U (h) (f) (x)))
const range = Y (f => acc => min => max =>
min > max ? acc : f ([...acc, min]) (min + 1) (max)) ([])
const reduce = Y (f => g => y => ([x,...xs]) =>
x === undefined ? y : f (g) (g (y) (x)) (xs))
const map = f =>
reduce (ys => x => [...ys, f (x)]) ([])
const add = x => y => x + y
const sq = x => x * x
console.log (range (-2) (2))
// [ -2, -1, 0, 1, 2 ]
console.log (reduce (add) (0) ([1,2,3,4]))
// 10
console.log (map (sq) ([1,2,3,4]))
// [ 1, 4, 9, 16 ]
```

**IT'S ALL ANONYMOUS OMG**

Because we're working with pure functions here, we can substitute any named function for its definition. Watch what happens when we take fibonacci and replace named functions with their expressions

```
/* const U = f => f (f)
*
* const Y = U (h => f => f (x => U (h) (f) (x)))
*
* const fibonacci = Y (f => a => b => x => x === 0 ? a : f (b) (a + b) (x - 1)) (0) (1)
*
*/
/*
* given fibonacci (7)
*
* replace fibonacci with its definition
* Y (f => a => b => x => x === 0 ? a : f (b) (a + b) (x - 1)) (0) (1) (7)
*
* replace Y with its definition
* U (h => f => f (x => U (h) (f) (x))) (f => a => b => x => x === 0 ? a : f (b) (a + b) (x - 1)) (0) (1) (7)
//
* replace U with its definition
* (f => f (f)) U (h => f => f (x => U (h) (f) (x))) (f => a => b => x => x === 0 ? a : f (b) (a + b) (x - 1)) (0) (1) (7)
*/
let result =
(f => f (f)) (h => f => f (x => h (h) (f) (x))) (f => a => b => x => x === 0 ? a : f (b) (a + b) (x - 1)) (0) (1) (7)
console.log (result) // 13
```

And there you have it – `fibonacci (7)`

calculated recursively using nothing but anonymous functions

`arguments.callee`

exists, and this functnio doesn't do anything useful. I was looking up Y combinator`:P`

. Damn, that stuff willneverget useful... – Kobi Oct 7 '10 at 16:42