19

In Haskell, this is a simple (naive) definition of a fixed point

fix :: (a -> a) -> a
fix f = f (fix f)

But, here is how Haskell actually implements it (more efficient)

fix f = let x = f x in x

My question is why is the second one more efficient than the first?

22

The slow fix calls f on each step of recursion, while the fast one calls f exactly once. It can be visualized with tracing:

import Debug.Trace

fix  f = f (fix f)
fix' f = let x = f x in x

facf :: (Int -> Int) -> Int -> Int
facf f 0 = 1
facf f n = n * f (n - 1)

tracedFacf x = trace "called" facf x

fac  = fix tracedFacf
fac' = fix' tracedFacf

Now try some running:

> fac 3
called
called
called
called
6
> fac' 3
called
6

In more detail, let x = f x in x results in a lazy thunk being allocated for x, and a pointer to this thunk is passed to f. On first evaluating fix' f, the thunk is evaluated and all references to it (here specifically: the one we pass to f) are redirected to the resulting value. It just happens that x is given a value that also contains a reference to x.

I admit this can be rather mind-bending. It's something that one should get used to when working with laziness.

  • 3
    I guess I'm somewhat unable to parse english today but if you say "calls f exactly once" you are not talking about evaluating f for some point right? because obviously you'll have to call facf a couple of times no matter what magic is involved (moving the trace into facf will show it) – Carsten May 21 '16 at 18:42
  • 2
    facf isn't recursive, we call it once, and fix' returns a function object. When we call that function object with a numeric argument, it calls itself recursively possibly multiple times (which can be again traced as you say). – András Kovács May 21 '16 at 18:46
  • Thanks for the explanation. I have a more general question. Can all recursive functions be 'optimized' by using this let binding approach? If so, why doesn't GHC internally use this technique to optimize recursions? I would assume the naive way of writing recursive functions is easier to read and understand. – Vijaya Rani May 21 '16 at 20:27
  • @VijayaRani simple recursive definitions are already about as fast and optimizable as they can be. It's just the slow fix definition that introduces overhead compared to simple recursive definitions. – András Kovács May 21 '16 at 20:33
  • 1
    Is this something that is actually guaranteed by the language specification or does it rely on private internal implementation details of one particular version of one particular implementation? – Jörg W Mittag May 22 '16 at 5:45
10

I don't think this always (or necessarily ever) helps when you're calling fix with a function that takes two arguments to produce a function taking one argument. You'd have to run some benchmarks to see. But you can also call it with a function taking one argument!

fix (1 :)

is a circular linked list. Using the naive definition of fix, it would instead be an infinite list, with new pieces built lazily as the structure is forced.

5

I believe this has been asked already, but I couldn't find the answer. The reason is that the first version

fix f = f (fix f)

is a recursive function, so it can't be inlined and then optimized. From the GHC manual:

For example, for a self-recursive function, the loop breaker can only be the function itself, so an INLINE pragma is always ignored.

But

fix f = let x = f x in x

isn't recursive, the recursion is moved into the let binding, so it's possible to inline it.

Update: I did some tests and while the former version doesn't inline while the latter does, it doesn't seem to be crucial for performance. So the other explanations (a single object on heap vs creating one every iteration) seem to be more accurate.

  • I don't think there is any inlining involved. – András Kovács May 21 '16 at 18:03
  • @AndrásKovács Correct. Both variants of fix get compiled in a different way, one via a let rec binding, the other via rec. (-ddump-simpl). – Zeta May 21 '16 at 18:54

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