There's quite a bit going on here, from the mechanics of lazy evaluation, to the definition of a fixed point to the *method* of finding a fixed point. In short, I believe you may be incorrectly interchanging the **fixed point of function application in the lambda calculus** with your needs.

It may be helpful to note that your implementation of finding the fixed-point (utilizing `iterate`

) requires a starting value for the sequence of function application. Contrast this to the `fix`

function, which requires no such starting value (As a heads up, the types give this away already: `findFixedPoint`

is of type `(a -> a) -> a -> a`

, whereas `fix`

has type `(a -> a) -> a`

). This is inherently because the two functions do subtly different things.

Let's dig into this a little deeper. First, I should say that you may need to give a little bit more information (your implementation of pairwise, for example), but with a naive first-try, and my (possibly flawed) implementation of what I believe you want out of pairwise, your `findFixedPoint`

function is equivalent in *result* to `fix`

, for a **certain class of functions only**

Let's take a look at some code:

```
{-# LANGUAGE RankNTypes #-}
import Control.Monad.Fix
import qualified Data.List as List
findFixedPoint :: forall a. Eq a => (a -> a) -> a -> a
findFixedPoint f = fst . List.head
. List.dropWhile (uncurry (/=)) -- dropWhile we have not reached the fixed point
. pairwise (,) -- applies (,) to adjacent list elements
. iterate f
pairwise :: (a -> a -> b) -> [a] -> [b]
pairwise f [] = []
pairwise f (x:[]) = []
pairwise f (x:(xs:xss)) = f x xs:pairwise f xss
```

contrast this to the definition of `fix`

:

```
fix :: (a -> a) -> a
fix f = let x = f x in x
```

and you'll notice that we're finding a very different kind of **fixed-point** (i.e. we abuse lazy evaluation to generate a fixed point for function application in the mathematical sense, where we only stop evaluation **iff*** the resulting function, applied to itself, evaluates to the same function).

For illustration, let's define a few functions:

```
lambdaA = const 3
lambdaB = (*)3
```

and let's see the difference between `fix`

and `findFixedPoint`

:

```
*Main> fix lambdaA -- evaluates to const 3 (const 3) = const 3
-- fixed point after one iteration
3
*Main> findFixedPoint lambdaA 0 -- evaluates to [const 3 0, const 3 (const 3 0), ... thunks]
-- followed by grabbing the head.
3
*Main> fix lambdaB -- does not stop evaluating
^CInterrupted.
*Main> findFixedPoint lambdaB 0 -- evaluates to [0, 0, ...thunks]
-- followed by grabbing the head
0
```

now if we can't specify the starting value, what is `fix`

used for? It turns out that by adding `fix`

to the lambda calculus, we gain the ability to specify the evaluation of recursive functions. Consider `fact' = \rec n -> if n == 0 then 1 else n * rec (n-1)`

, we can compute the fixed point of `fact'`

as:

```
*Main> (fix fact') 5
120
```

where in evaluating `(fix fact')`

repeatedly applies `fact'`

itself until we reach the *same* **function**, which we then call with the value `5`

. We can see this in:

```
fix fact'
= fact' (fix fact')
= (\rec n -> if n == 0 then 1 else n * rec (n-1)) (fix fact')
= \n -> if n == 0 then 1 else n * fix fact' (n-1)
= \n -> if n == 0 then 1 else n * fact' (fix fact') (n-1)
= \n -> if n == 0 then 1
else n * (\rec n' -> if n' == 0 then 1 else n' * rec (n'-1)) (fix fact') (n-1)
= \n -> if n == 0 then 1
else n * (if n-1 == 0 then 1 else (n-1) * fix fact' (n-2))
= \n -> if n == 0 then 1
else n * (if n-1 == 0 then 1
else (n-1) * (if n-2 == 0 then 1
else (n-2) * fix fact' (n-3)))
= ...
```

So what does all this mean? depending on the function you're dealing with, you won't necessarily be able to use `fix`

to compute the kind of fixed point you want. This is, to my knowledge, dependent on the function(s) in question. Not all functions have the kind of fixed point computed by `fix`

!

*I've avoided talking about domain theory, as I believe it would only confuse an already subtle topic. If you're curious, `fix`

finds a *certain* **kind** of fixed point, namely the least available fixed point of the poset the function is specified over.