The definition of a fixed-point combinator is a function `F`

which takes a function `f`

and returns a function `p`

such that

Given `F(f) = p`

then `p = f(p)`

There are many possible fixed point combinators that could be written. Don't let the straightforwardness make you think that something isn't a fixed-point combinator; here is a standard definition in JavaScript, which is very simple:

```
var fix = function(f) {
return function(x) {
return f(fix(f))(x)
}
};
```

A usage might be then to compute the fixed-point for factorial, with:

```
var fact = function(f) {
return function(n) { return (n == 0) ? 1 : (n * f(n - 1)) }
};
alert(fix(fact)(7)); // alerts us with 5040.
```

For an example of a different fixed point combinator (the Y combinator) see this helpful blog post.

Let's see if your `until`

combinator computes fixed-points. Since you are working with monadic functions the fixed-point definition changes slightly to handle the monadic structure, where `F`

is a (monadic) fixed-point combinator when

Given `F(f) = p`

then `p = f* . p`

where `f* . p`

means the Kleisli composition of the function `p`

with the function `f`

(in your code you would write this `kleisli(p, f)`

, you can think of `*`

as `bind`

). I'll use this notation as it is shorter than writing JavaScript.

Let's unroll the definition of `until`

then and see what we get:

```
until(f) = (until(f))* . f
= (until(f)* . f)* . f
= ((... . f)* . f)* . f
= ... . f* . f* . f (associativity of bind for a monad: (g* . f)* = g* . f*)
= p
```

Does `p = f* . p`

?

```
... . f* . f* . f =?= f* . ... . f* . f* . f
```

Yes- I believe so. Although I don't think this is a useful fixed point. (I'm afraid I don't have a good argument for this yet- but I think this is basically a greatest-fixed point which will just diverge).

To me, it looks like the arguments to `kleisli`

in `until`

should have been swapped. That is, we wish to do the Kleisli equivalent of application in the `fix`

example, so we need to pass the monadic result of the recursive call `until(f)`

to `f`

:

```
var until = function(f) {
return function(a) {
return kleisli(until(f), f)(a);
};
};
```

Let's unroll this new definition of `until`

:

```
until(f) = f* . until(f)
= f* . (f* . until(f))
= f* . f* . ...
= p
```

Does `p = f* . p`

? Yes it does:

```
f* . f* ... = f* . (f* . f* . ...)
```

since adding one more composition of f* onto an infinite chain of f* composition is the same function.

Using your `kleisli`

function I had some problems with divergence (some evaluation is happening too soon so the computation runs until I run out of stack space). Instead, the following seems to work for me:

```
var until = function(f) {
return function(a) {
return bind(f,until(f)(a));
};
};
```

For more on fixed-points for monadic code you might like to check out the work of Erkök and Launchbury.