How does x ever come to mean fix x in the first definition?

```
fix f = let x = f x in x
```

**Let bindings in Haskell are recursive**

First of all, realize that Haskell allows recursive let bindings. What Haskell calls "let", some other languages call "letrec". This feels pretty normal for function definitions. For example:

```
ghci> let fac n = if n == 0 then 1 else n * fac (n - 1) in fac 5
120
```

But it can seem pretty weird for value definitions. Nevertheless, values can be recursively defined, due to Haskell's non-strictness.

```
ghci> take 5 (let ones = 1 : ones in ones)
[1,1,1,1,1]
```

See A gentle introduction to Haskell sections 3.3 and 3.4 for more elaboration on Haskell's laziness.

**Thunks in GHC**

In GHC, an as-yet-unevaluated expression is wrapped up in a "thunk": a promise to perform the computation. Thunks are only evaluated when they absolutely *must* be. Suppose we want to `fix someFunction`

. According to the definition of `fix`

, that's

```
let x = someFunction x in x
```

Now, what GHC sees is something like this.

```
let x = MAKE A THUNK in x
```

So it happily makes a thunk for you and moves right along until you demand to know what `x`

actually is.

**Sample evaluation**

That thunk's expression just happens to refer to itself. Let's take the `ones`

example and rewrite it to use `fix`

.

```
ghci> take 5 (let ones recur = 1 : recur in fix ones)
[1,1,1,1,1]
```

So what will that thunk look like?

We can inline `ones`

as the anonymous function `\recur -> 1 : recur`

for a clearer demonstration.

```
take 5 (fix (\recur -> 1 : recur))
-- expand definition of fix
take 5 (let x = (\recur -> 1 : recur) x in x)
```

Now then, what *is* `x`

? Well, even though we're not quite sure what `x`

is, we can still go through with the function application:

```
take 5 (let x = 1 : x in x)
```

Hey look, we're back at the definition we had before.

```
take 5 (let ones = 1 : ones in ones)
```

So if you believe you understand how *that* one works, then you have a good feel of how `fix`

works.

Is there any advantage to using the first definition over the second?

Yes. The problem is that the second version can cause a **space leak**, even with optimizations. See GHC trac ticket #5205, for a similar problem with the definition of `forever`

. This is why I mentioned thunks: because `let x = f x in x`

allocates only one thunk: the `x`

thunk.