As others pointed out, `fix`

somehow captures the essence of recursion. Other answers already do a great job at explaining how `fix`

works. So let's take a look from another angle and see how `fix`

can be derived by generalising, starting from a specific problem: we want to implement the factorial function.

Let's first define a non recursive factorial function. We will use it later to "bootstrap" our recursive implementation.

```
factorial n = product [1..n]
```

We approximate the factorial function by a sequence of functions: for each natural number `n`

, `factorial_n`

coincides with `factorial`

up to and including `n`

. Clearly `factorial_n`

converges towards `factorial`

for `n`

going towards infinity.

```
factorial_0 n = if n == 0 then 1 else undefined
factorial_1 n = n * factorial_0(n - 1)
factorial_2 n = n * factorial_1(n - 1)
factorial_3 n = n * factorial_2(n - 1)
...
```

Instead of writing `factorial_n`

out by hand for every `n`

, we implement a factory function that creates these for us. We do this by factoring the commonalities out and abstracting over the calls to `factorial_[n - 1]`

by making them a parameter to the factory function.

```
factorialMaker f n = if n == 0 then 1 else n * f(n - 1)
```

Using this factory, we can create the same converging sequence of functions as above. For each `factorial_n`

we need to pass a function that calculates the factorials up to `n - 1`

. We simply use the `factorial_[n - 1]`

from the previous step.

```
factorial_0 = factorialMaker undefined
factorial_1 = factorialMaker factorial_0
factorial_2 = factorialMaker factorial_1
factorial_3 = factorialMaker factorial_2
...
```

If we pass our real factorial function instead, we materialize the limit of the series.

```
factorial_inf = factorialMaker factorial
```

But since that limit is the real factorial function we have `factorial = factorial_inf`

and thus

```
factorial = factorialMaker factorial
```

Which means that `factorial`

is a fixed-point of `factorialMaker`

.

Finally we derive the function `fix`

, which returns `factorial`

given `factorialMaker`

. We do this by abstracting over `factorialMaker`

and make it an argument to `fix`

. (i.e. `f`

corresponds to `factorialMaker`

and `fix f`

to `factorial`

):

```
fix f = f (fix f)
```

Now we find `factorial`

by calculating the fixed-point of `factorialMaker`

.

```
factorial = fix factorialMaker
```

`fix error`

in ghci and feel good about yourself."`fix`

as`fix f = f (fix f)`

. Short, simple, works, and identical to the mathematical definition.`fix (1:) !! (10^8)`

. The original does it in constant memory, yours takes linear memory (which makes it quite a bit slower, too). That is, using the let "ties a tighter knot", and allows a circular data structure to be generated, whereas yours does not.`fix`

too! helped me understand`fix`

a lot.1more comment