6

A corrected quiz in my textbook is asking me how many of f's arguments are strict, f being:

f x 0 z = x == z
f x y z = x

My initial thought was that all of f's arguments are to be considered strict, since y is being evaluated to check if its equal to 0, and x and z are compared to see that they're both equal. And yet the answer is that only x and y are strict.

Any clues as to why?

2 Answers 2

8

First of all, you need a very precise definition of "strict" in order for this to make sense. A function f is strict iff evaluating f x to whnf causes x to be evaluated to whnf. The interaction this has with currying is a bit awkward, and I'm going to ignore some of the potential weirdness that introduces.

Assuming the type here is f :: Bool -> Int -> Bool -> Bool your analysis of the behavior wrt y is correct - evaluating f x y z to whnf will always require evaluating y to determine which equation to choose. As that is the only factor determining which equation to use, we have to split the analysis for x and z. In the first equation, evaluating the result to whnf results in both x and z being evaluated. In the second equation, evaluating the result to whnf results in evaluating x to whnf.

Since x is evaluated in both branches, this function is strict in x. This is a little bit amusing - it's strict in the way id is strict. But that's still valid! z, however, is a different story. Only one of the branches causes z to be evaluated, so it's not evaluated strictly - it's only evaluated on demand. Usually we talk about this happening where evaluation is guarded behind a constructor or when a function is applied and the result isn't evaluated, but being conditionally evaluated is sufficient. f True 1 undefined evaluates to True. If f was strict in z, that would have to evaluate to undefined.

8

It turns out that whether f is strict in its second argument depends on what type it gets resolved to.

Here's proof:

data ModOne = Zero
instance Eq ModOne where
    _ == _ = True -- after all, they're both Zero, right?
instance Num ModOne -- the method implementations literally don't matter

f x 0 z = x == z
f x y z = x

Now in ghci:

> f True (undefined :: ModOne) True
True
> f True (undefined :: Int) True
*** Exception: Prelude.undefined

And, in a related way, whether f is strict in its third argument depends on what values you pick for the first two. Proof, again:

> f True 1 undefined
True
> f True 0 undefined
*** Exception: Prelude.undefined

So, there isn't really a simple answer to this question! f is definitely strict in its first argument; but the other two are conditionally one or the other depending on circumstances.

2
  • Nice example! Presumably this indicates that pattern matching for instances of Num actually uses Eq under the covers? (Eq is a superclass of Num so I guess this wouldn't be crazy.) Is this behaviour specified in the Haskell report somewhere or is it just how GHC chooses to do it? Commented Feb 11, 2021 at 7:35
  • 1
    @RobinZigmond Yes, it uses (==) under the covers. That behavior is specified here. Commented Feb 11, 2021 at 15:29

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.