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Howcome in Haskell, when there is a value that would be discarded, () is used instead of ?

Examples (can't really think of anything other than IO actions at the moment):

mapM_ :: (Monad m) => (a -> m b) -> [a] -> m ()
foldM_ :: (Monad m) => (a -> b -> m a) -> a -> [b] -> m ()
writeFile :: FilePath -> String -> IO ()

Under strict evaluation, this makes perfect sense, but in Haskell, it only makes the domain bigger.

Perhaps there are "unused parameter" functions d -> a which are strict on d (where d is an unconstrained type parameter and does not appear free in a)? Ex: seq, const' x y = yseqx.

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For most everyday Haskell programming, we like to pretend there is no such thing as _|_... we only whip that out when in the more formal mode. I.e. we like to pretend that data Foo = A | B only has two possible values instead of three; so there is only one value of type (). You could throw the term "fully defined" in there if you like. –  luqui Jun 18 '12 at 4:34
    
What would the alternative be? i.e. what's a sensible type for writeFile or mapM_? –  dbaupp Jun 18 '12 at 4:41
    
@dbaupp: writeFile :: FilePath -> String -> a, mapM_ :: (Monad m) => (a -> m b) -> [a] -> m z –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Jun 18 '12 at 13:46
    
@Longpoke, you'd need a Monad constraint in the first one, otherwise it could be used in pure code. –  dbaupp Jun 18 '12 at 14:13
    
@dbaupp: typo. writeFile :: FilePath -> String -> IO a –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Jun 18 '12 at 14:17

6 Answers 6

I think this is because you need to specify the type of the value to be discarded. In Haskell-98, () is the obvious choice. And as long as you know the type is (), you may as well make the value () as well (presuming evaluation proceeds that far), just in case somebody tries to pattern-match on it or something. I think most programmers don't like introducing extra ⊥'s into code because it's just an extra trap to fall into. I certainly avoid it.

Instead of (), it is possible to create an uninhabited type (except by ⊥ of course).

{-# LANGUAGE EmptyDataDecls #-}

data Void

mapM_ :: (Monad m) => (a -> m b) -> [a] -> m Void

Now it's not even possible to pattern-match, because there's no Void constructor. I suspect the reason this isn't done more often is because it's not Haskell-98 compatible, as it requires the EmptyDataDecls extension.

Edit: you can't pattern-match on Void, but seq will ruin your day. Thanks to @sacundim for pointing this out.

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I wonder if Void will be used for such things in "Haskell Prime". Are there any downsides (besides breaking backwards compatibility) of using Void in this way, instead of ()? –  Dan Burton Jun 18 '12 at 8:34
    
@DanBurton - none that I can see, although introducing it for all the standard libs would be a major change so I think it's unlikely to happen. –  John L Jun 18 '12 at 9:16
    
@JohnL: +1, but I don't think that Void is valid replacment for (). () signalizes there's exactly one value (and as such it doesn't carry any additional information), on the other hand Void signalizes the lack of value. It also plays nice with logic - you can always consturct value of the trivially-true type (the fact that Haskell isn't consistent under CH is another thing). If anything, we should probably force pattern matching on non m () (even if that means having to write _ <- to explicitly ignore the value); it makes the code a bit safer. –  Vitus Jun 18 '12 at 11:46
    
@JohnL Ok, now write mapM_ without using bottom :-) –  sclv Jun 18 '12 at 13:23
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@sclv: void :: Void;void = error "void value used (probably by a strictness annotation)"; mapM_' f xs = mapM_ f xs >> return void; @JohnL, I'm not sure what you mean by "pattern matching on non m ()" –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Jun 18 '12 at 14:05

Well, bottom type literally means an unterminating computation, and unit type is just what it is - a type inhabited with single value. Clearly, monadic computations usually meant to be finished, so it simply doesn't make sense to make them return undefined. And, of course, it is simply a safety measure - just like John L said, what if someone pattern matches on monadic result? So monadic computations return the 'lowest' possible (in Haskell 98) type - unit.

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⊥ isn't necessarily nontermination, pattern match failure is also ⊥, for example. –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Jun 18 '12 at 13:55
    
I guess if you define print' :: Show a => a -> IO z; print' a = print a >> return undefined, print' 'a' >>= \"blah" -> print' 'b' will compile and fail at runtime. Using an empty sum type as John L wrote would fix this. –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Jun 18 '12 at 14:00
    
@Longpoke: pattern match failure and similar errors are also considered nontermination in Haskell's semantics. –  Luis Casillas Jun 18 '12 at 17:02
    
@sacundim I see ⊥ as "failure to evaluate to a well-defined value of the expression's type". Nontermination, pattern match failures, explicitly thrown exceptions, out of memory errors, power failure kills the machine; all of these are just categorisation of different kinds of ⊥. You can say that a power failure is considered nontermination, but I'd rather say that nontermination and power failure are both kinds of ⊥; they're indistinguishable from the point of view of Haskell's pure semantics, but you can tell from outside by whether the program hangs or the monitor goes black. –  Ben Jan 23 '13 at 7:16
    
No, I would have to insist that power failure is not a form of ⊥. Why? Because the semantics of Haskell is clearly intended to be compositional: the denotation of an expression is a function of the denotation of its subparts. Since evaluation of any expression is nondeterministically subject to a power failure, then the semantics would have to say that every expression nondeterministically denots either its true value or ⊥—which is clearly not right. –  Luis Casillas Jan 23 '13 at 17:04

So, maybe we could have the following signatures:

mapM_     :: (Monad m) => (a -> m b) -> [a] -> m z
foldM_    :: (Monad m) => (a -> b -> m a) -> a -> [b] -> m z
writeFile :: FilePath -> String -> IO z

We'd reimplement the functions in question so that any attempt to bind the z in m z or IO z would bind the variable to undefined or any other bottom.

What do we gain? Now people can write programs that force the undefined result of these computations. How is that a good thing? All it means is that people can now write programs that fail to terminate for no good reason, that were impossible to write before.

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These failing programs aren't impossible to write now. You can always introduce ⊥. But I upvoted because you reminded me of something I overlooked. –  John L Jun 19 '12 at 0:05

() is , i.e. the unit type, not the (the bottom type). The big difference is that the unit type is inhabited, so that it has a value (() in Haskell), on the other hand, the bottom type is uninhabited, so that you can't write functions like that:

absurd : ⊥
absurd = -- no way

Of course you can do this in Haskell since the "bottom type" (there is no such thing, of course) is inhabited here with undefined. This makes Haskell inconsistent.

Functions like this:

disprove : a → ⊥
disprove x = -- ...

can be written, it is the same as

disprove : ¬ a
disprove x = -- ...

i.e. it disproving the type a, so that a is an absurd.

In any case, you can see how the unit type is used in different languages, as () :: () in Haskell, () : unit in ML, () : Unit in Scala and tt : ⊤ in Agda. In languages like Haskell and Agda (with the IO monad) functions like putStrLn should have a type String → IO ⊤, not the String → IO ⊥ since this is an absurd (logically it states that there is no strings that can be printed, this is just not right).


DISCLAIMER: previous text use Agda notation and it is more about Agda than Haskell.

In Haskell if we have

data Void

It doesn't mean that Void is uninhabited. It is inhabited with undefined, non-terminating programs, errors and exceptions. For example:

data Void

instance Show Void where
  show _ = "Void"

data Identity a = Identity { runIdentity :: a }

mapM__ :: (a -> Identity b) -> [a] -> Identity Void
mapM__ _ _ = Identity undefined

then

print $ runIdentity $ mapM__ (const $ Identity 0) [1, 2, 3]
-- ^ will print "Void".
case runIdentity $ mapM__ (const $ Identity 0) [1, 2, 3] of _ -> print "1"
-- ^ will print "1".
let x = runIdentity $ mapM__ (const $ Identity 0) [1, 2, 3]
x `seq` print x
-- ^ will thrown an exception.

But it also doesn't mean that Void is ⊥. So

mapM_ :: Monad m => (a -> m b) -> [a] -> m Void

where Void is decalred as empty data type, is ok. But

mapM_ :: Monad m => (a -> m b) -> [a] -> m ⊥

is nonsence, but there is no such type as ⊥ in Haskell.

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Also if you allow mapM_ : ∀ {A B M} → RawMonad M → (A → M B) → List A → M ⊥, you can write absurd : ⊥ ; absurd = mapM_ IdentityMonad id []. –  Vitus Jun 18 '12 at 19:39
    
@Vitus, right, also it's true for every monad M for which runM : M A → A can be written. Maybe not for IO. In fact, IO ⊥ can be inhabited. Since IO is an abstract type this is depending on it implementation. –  JJJ Jun 18 '12 at 20:32
    
The question specifically mentions Haskell and this answer uses non-Haskell notation and refers to non-Haskell concepts, I find it somewhat confusing. Also, you said that String → IO ⊥ means that no strings can be printed, but I don't see that – surely it just means you can't do anything after printing a string? (for example, it would be legitimate for forever to have type m a -> m Void) –  Ben Millwood Jun 28 '12 at 18:42
    
Also, what on earth do you mean when you say the bottom type is inhabited, but also doesn't exist? –  Ben Millwood Jun 28 '12 at 18:45
    
Hi @Ben . This answer uses Agda notation. Haskell is inconsistent sometimes, Agda is consistent and closely related to Haskell, so IMHO it is a good thing to peek on Agda when thinking about such theoretic issues. About String → IO ⊥. I suppose that IO ⊥ is uninhabited. It is a question though, one can implement IO to have some nullary constructor like emptyIO :: IO a, then putStrLn :: String → IO ⊥ or foreverIO :: IO a → IO ⊥ would be ok. But if IO ⊥ is uninhabited, then for the function foo :: String → IO ⊥ the term foo "whatever" would be an absurd. –  JJJ Jun 28 '12 at 19:29

You're getting confused between types and values.

In writeFile :: FilePath -> String -> IO (), the () is the unit type. The value you get for x by doing x <- writeFile foo bar in a do block is (normally) the value (), which is the sole non-bottom inhabitant of the type ().

OTOH is a value. Since is a member of every type, it's also usable as a value for the type (). If you're discarding that x above without using it (we normally don't even extract it into a variable), it may very well be and you'd never know. In that sense you already have what you want; if you're ever writing a function whose result you expect to be always ignored, you could use . But since is a value of every type, there is no type , and so there is no type IO ⊥.

But really, they represent different conceptual things. The type () is the type of values that contain zero information (which is why there is only one value; if there were two or more values then () values would contain at least as much information as values of Bool). IO () is the type of IO actions that generate a value with no information, but may effects that will happen as a result of generating that non-informative value.

is in some sense a non-value. 1 `div` 0 gives because there is no value that could be used as the result of that expression which satisfies the laws of integer division. Throwing an exception gives because functions that contain exception throws do not give you a value of their type. Non-termination gives because the expression never terminates with a value. is a way of treating all of these non-values as if they were a value for some purposes. As far as I can tell it's mainly useful because Haskell's laziness means that and a data structure containing (i.e. [⊥]) are distinguishable.

The value () is not like the cases where we use . writeFile foo bar doesn't have an "impossible value" like return $ 1 `div` 0, it just has no information in its value (other than that contained in the monadic structure). There are perfectly sensible things I could do with the () I get from doing x <- writeFile foo bar; they're just not very interesting and so nobody ever does them. This is distinctly different from x <- return $ 1 `div` 0, where doing anything with that value has to give me another ill-defined value.

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By "⊥" as a type, I meant any type that can only have ⊥ as a value, such as a in Integer -> a, or the "Void" type in John's answer –  L̲̳o̲̳̳n̲̳̳g̲̳̳p̲̳o̲̳̳k̲̳̳e̲̳̳ Jun 19 '12 at 14:25
    
This is the only answer that IMO really makes clear the conceptual difference between "only one value" (i.e. Void) and "only one defined value" (i.e. ()). To me, that's what the question is all about. –  Ben Millwood Jun 28 '12 at 18:47
    
I find 1/0 gives Infinity, not ⊥. –  TorosFanny Jan 23 '13 at 6:40
    
@TorosFanny That's what I get for not checking my examples! If you use integer math it does what I claim, so 1 `div` 0. –  Ben Jan 23 '13 at 7:04
    
@Ben Yes, but this mistake is misleading. Could I fix it? –  TorosFanny Jan 23 '13 at 7:13

I would like to point out one severe downside to writing one particular form of returning ⊥: if you write types like this, you get bad programs:

mapM_ :: (Monad m) => (a -> m b) -> [a] -> m z

This is way too polymorphic. As an example, consider forever :: Monad m => m a -> m b. I encountered this gotcha a long time ago and I'm still bitter:

main :: IO ()
main = forever putStrLn "This is going to get printed a lot!"

The error is obvious and simple: missing parentheses.

  • It typechecks. This is exactly the sort of error that the type system is supposed to catch easily.
  • It silently infinite loops at runtime (without printing anything). It is a pain to debug.

Why? Well, because r -> is a monad. So m b matches virtually anything. For example:

forever :: m a -> m b
forever putStrLn :: String -> b
forever putStrLn "hello!" :: b -- eep!
forever putStrLn "hello" readFile id flip (Nothing,[17,0]) :: t -- no type error.

This sort of thing inclines me to the view that forever should be typed m a -> m Void.

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If forever :: Monad m => m a -> m Void then x in x <- forever ... would not make any sense. And it's right because forever cannot return. forever :: Monad m => m a -> m () solve the problem as well, but x in x <- forever ... would be (), maybe it's not right. –  JJJ Jun 30 '12 at 16:47
    
() would be an improvement over just b, but conceptually Void is correct, I think, since indeed x <- forever ... will never give a value to x (as the original polymorphic type witnesses!) –  Ben Millwood Jul 1 '12 at 0:27

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