# for fixed point combinator Y, what is \x.f(xx)

For the Y combinator theorem,

`````` For every function F there exists an X such that FX=X
``````

what's the `F` mean here? what's the fixed point for `F(x) = x +1`? My understanding is that `x+1=x` does not have a solution?

For the Proof below:

``````For any function F, let W be the function λx.F(xx) and let X = WW.
We claim that X is a fixed point of F. Demonstrated as follows

X = WW
X = λx.F(xx) W
X = F(WW)
X = FX
``````

How's `λx.F(xx)` defined? again using `F(x) = x + 1` as example, what's `F(xx)` mean?

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You are right in that the equation `x+1 = x` has no solution when `x` is a number. What's going on here is that `x` is not restricted to being a number; it can be a function of functions.

About `xx`: In general in lambda calculus `f x` is a function application, so `xx` is "x applied to x", or `x(x)`. Note how x is both the function that is being applied and the value being passed to it.

So, if `F(x) = x+1`, you have `F(xx) = x(x)+1`, `W = λx.(x(x)+1)`, and `X=W(W)` would be the function:

``````X = W(W) = (λx.(x(x)+1)) (λy.(y(y)+1))
``````

This may seem very abstract because if you try to expand X on any concrete value you'll find that the process never ends. But don't let that bother you; in spite of that `X` is a fixed point of `F` because

``````F(X) = F(W(W))             by definition of X = W(W)
= (λx.F(x(x))) W      using the fact that (λt.f(t))x is f(x)
= W(W)                by definition of W = λx.F(x(x))
= X                   by definition of X = W(W).
``````
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can `X` here be further simplified for `F(x) = x+1`? –  ahala Jan 2 at 1:40
You can't really simplify `X`, you can only expand it more and more. For example using just the basic fact that `(λt.f(t))x` is `f(x)` you can expand `X = (λx.(x(x)+1)) (λy.(y(y)+1))` to `(λy.(y(y)+1))((λy.(y(y)+1))) + 1`, and you can expand that further and further to get `X = (λx.(x(x)+1))((λx.(x(x)+1))) + n` for any positive integer `n`. –  Joni Jan 2 at 2:05
This is of course just restating the fact that X being the fixed point of F(x)=x+1 implies that X=X+1=…=X+n. –  Joni Jan 2 at 9:38

There seems to be a bit confusion what fixed point for functions is and also about the lambda calculus notation.

First `λx.F(xx)` is a function taking an argument x and "applying" x to x and "then" "applying" F to the result, so more like `function (x) { return F(x(x)); }`, but do not take it literally, because in lambda calculus it is about substitutions of parameters and there is no order in which you need to do substitutions (what I used for simplification is applicative order).

So the proof rewritten to C-like syntax (actually JavaScript, as it has 1st class functions) with simple text-rewrite semantics would look like:

``````var W = function (x) { return F(x(x)); }
var X = W(W);

W(W) => (function (x) { return F(x(x)); }(W))
=> return F(W(W))
=> return F(X)
=> F(X)
``````

Now back to fixed point. You give an algebraic example where fixed point does not exists... for functions it would be more like "find a fixed point of `ADD1(x) = x + 1`"

``````var F = function (x) { return x + 1; }
var W = function (x) { return F(x(x)); }
= function (x) { return function (x) { return x + 1; }(x(x)); }
var X = W(W);

W(W) => function (x) { return function (x) { return x + 1; }(x(x)); }(W)
=> return function (x) { return x + 1; }(W(W))
=> return W(W) + 1
=> W(W) + 1
=> X + 1
=> F(X)
``````

I hope that the familiar syntax made it less confusing rather than more :)

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The fixed point `X = function (x){while(true)++x; return(x);}` ? an infinite loop? –  ahala Jan 2 at 2:47
Infinite loop only when evaluated eagerly... but lambda calculus is telling you neither that you need to do all substitutions nor in which order. It just gives you some identities. –  jJ' Jan 2 at 3:07
In addition, the fixed point definition X = FX = FFX = FFFX ... is infinite in the same sense... –  jJ' Jan 2 at 3:14