Just as the title says: what guarantees are there for a Haskell function returning unit to be evaluated? One would think that there is no need to run any kind of evaluation in such a case, the compiler could replace all such calls with an immediate ()
value unless explicit requests for strictness are present, in which case the code might have to decide whether it should return ()
or bottom.
I have experimented with this in GHCi, and it seems like the opposite happens, that is, such a function appears to be evaluated. A very primitive example would be
f :: a -> ()
f _ = undefined
Evaluating f 1
throws an error due to the presence of undefined
, so some evaluation definitely happens. It is not clear how deep the evaluation goes, though; sometimes it appears to go as deep as it is necessary to evaluate all calls to functions returning ()
. Example:
g :: [a] -> ()
g [] = ()
g (_:xs) = g xs
This code loops indefinitely if presented with g (let x = 1:x in x)
. But then
f :: a -> ()
f _ = undefined
h :: a -> ()
h _ = ()
can be used to show that h (f 1)
returns ()
, so in this case not all unit-valued subexpressions are evaluated. What is the general rule here?
ETA: of course I know about laziness. I'm asking what prevents compiler writers from making this particular case even lazier than usually possible.
ETA2: summary of the examples: GHC appears to treat ()
exactly as any other type, i.e. as if there was a question about which regular value inhabiting the type should be returned from a function. The fact that there's only one such value does not seem to be (ab)used by the optimization algorithms.
ETA3: when I say Haskell, I mean Haskell-as-defined-by-the-Report, not Haskell-the-H-in-GHC. Seems to be an assumption not shared as widely as I imagined (which was 'by 100% of the readers'), or I would probably have been able to formulate a clearer question. Even so, I regret changing the title of the question, as it originally asked what guarantees are there for such a function being called.
ETA4: it would seem that this question has run its course, and I'm considering it unanswered. (I was looking for a 'close question' function but only found 'answer your own question' and as it cannot be answered, I did not go down that route.) No one brought up anything from the Report that would decide it either way, which I'm tempted to interpret as a strong but not definite 'no guarantee for the language as such' answer. All we know is that the current GHC implementation will not skip the evaluation of such a function.
I've run into the actual problem when porting an OCaml app to Haskell. The original app had a mutually recursive structure of many types, and the code declared a number of functions called assert_structureN_is_correct
for N in 1..6 or 7, each of which returned unit if the structure was indeed correct and threw an exception if it was not. In addition, these functions called each other as they decomposed the correctness conditions. In Haskell this is better handled using the Either String
monad, so I transcribed it that way, but the question as a theoretical issue remained. Thanks for all the inputs and replies.
h1::()->() ; h1 () = ()
andh2::()->() ; h2 _ = ()
. Run bothh1 (f 1)
andh2 (f 1)
, and see that only the first one demands(f 1)
.f 1
is "replaced" byundefined
in all cases.... -> ()
can 1) terminate and return()
, 2) terminate with an exception/runtime error and fail to return anything, or 3) diverge (infinite recursion). GHC does not optimize the code assuming only 1) can happen: iff 1
is demanded, it does not skip its evaluation and return()
. The Haskell semantics is to evaluate it and see what happens among 1,2,3.()
(either the type or the value) in this question. All the same observations happen if you replace() :: ()
with, say,0 :: Int
everywhere. These are all just boring old consequences of lazy evaluation.()
type,()
andundefined
.