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
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)
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
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.
That thunk's expression just happens to refer to itself. Let's take the
ones example and rewrite it to use
ghci> take 5 (let ones recur = 1 : recur in fix ones)
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
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