# What's the absurd function in Data.Void useful for?

The `absurd` function in `Data.Void` has the following signature, where `Void` is the logically uninhabited type exported by that package:

``````-- | Since 'Void' values logically don't exist, this witnesses the logical
-- reasoning tool of \"ex falso quodlibet\".
absurd :: Void -> a
``````

I do know enough logic to get the documentation's remark that this corresponds, by the propositions-as-types correspondence, to the valid formula `⊥ → a`.

What I'm puzzled and curious about is: in what sort of practical programming problems is this function useful? I'm thinking that perhaps it's useful in some cases as a type-safe way of exhaustively handling "can't happen" cases, but I don't know enough about practical uses of Curry-Howard to tell whether that idea is on the right track at all.

EDIT: Examples preferably in Haskell, but if anybody wants to use a dependently typed language I'm not going to complain...

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A quick search shows that the `absurd` function has been used in this article dealing with the `Cont` monad: haskellforall.com/2012/12/the-continuation-monad.html –  Artyom Kazak Jan 3 '13 at 1:33
Oh, hey, I was planning to read that one anyway... Thanks! –  Luis Casillas Jan 3 '13 at 1:36
You can see `absurd` as one direction of the isomorphism between `Void` and `forall a. a`. –  Daniel Wagner Jan 3 '13 at 3:23

Life is a little bit hard, since Haskell is non strict. The general use case is to handle impossible paths. For example

``````simple :: Either Void a -> a
simple (Left x) = absurd x
simple (Right y) = y
``````

This turns out to be somewhat useful. Consider a simple type for `Pipes`

``````data Pipe a b r
= Pure r
| Await (a -> Pipe a b r)
| Yield !b (Pipe a b r)
``````

this is a strict-ified and simplified version of the standard pipes type from Gabriel Gonzales' `Pipes` library. Now, we can encode a pipe that never yields (ie, a consumer) as

``````type Consumer a r = Pipe a Void r
``````

this really never yields. The implication of this is that the proper fold rule for a `Consumer` is

``````foldConsumer :: (r -> s) -> ((a -> s) -> s) -> Consumer a r -> s
foldConsumer onPure onAwait p
= case p of
Pure x -> onPure x
Await f -> onAwait \$ \x -> foldConsumer onPure onAwait (f x)
Yield x _ -> absurd x
``````

or alternatively, that you can ignore the yield case when dealing with consumers. This is the general version of this design pattern: use polymorphic data types and `Void` to get rid of possibilities when you need to.

Probably the most classic use of `Void` is in CPS.

``````type Continuation a = a -> Void
``````

that is, a `Continuation` is a function which never returns. `Continuation` is the type version of "not." From this we get a monad of CPS (corresponding to classical logic)

``````newtype CPS a = Continuation (Continuation a)
``````

since Haskell is pure, we can't get anything out of this type.

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Huh, I can actually kinda follow that CPS bit. I'd certainly heard of the Curry-Howard double negation/CPS correspondences before, but not understood it; I'm not going to claim I fully get it now, but this certainly helps! –  Luis Casillas Jan 3 '13 at 3:38

Consider this representation for lambda terms parametrized by their free variables. (See papers by Bellegarde and Hook 1994, Bird and Paterson 1999, Altenkirch and Reus 1999.)

``````data Tm a  = Var a
| Tm a :\$ Tm a
| Lam (Tm (Maybe a))
``````

You can certainly make this a `Functor`, capturing the notion of renaming, and a `Monad` capturing the notion of substitution.

``````instance Functor Tm where
fmap rho (Var a)   = Var (rho a)
fmap rho (f :\$ s)  = fmap rho f :\$ fmap rho s
fmap rho (Lam t)   = Lam (fmap (fmap rho) t)

instance Monad Tm where
return = Var
Var a     >>= sig  = sig a
(f :\$ s)  >>= sig  = (f >>= sig) :\$ (s >>= sig)
Lam t     >>= sig  = Lam (t >>= maybe (Var Nothing) (fmap Just . sig))
``````

Now consider the closed terms: these are the inhabitants of `Tm Void`. You should be able to embed the closed terms into terms with arbitrary free variables. How?

``````fmap absurd :: Tm Void -> Tm a
``````

The catch, of course, is that this function will traverse the term doing precisely nothing. But it's a touch more honest than `unsafeCoerce`. And that's why `vacuous` was added to `Data.Void`...

Or write an evaluator. Here are values with free variables in `b`.

``````data Val b
=  b :\$\$ [Val b]                              -- a stuck application
|  forall a. LV (a -> Val b) (Tm (Maybe a))   -- we have an incomplete environment
``````

I've just represented lambdas as closures. The evaluator is parametrized by an environment mapping free variables in `a` to values over `b`.

``````eval :: (a -> Val b) -> Tm a -> Val b
eval g (Var a)   = g a
eval g (f :\$ s)  = eval g f \$\$ eval g s where
(b :\$\$ vs)  \$\$ v  = b :\$\$ (vs ++ [v])         -- stuck application gets longer
LV g t      \$\$ v  = eval (maybe v g) t        -- an applied lambda gets unstuck
eval g (Lam t)   = LV g t
``````

You guessed it. To evaluate a closed term at any target

``````eval absurd :: Tm Void -> Val b
``````

More generally, `Void` is seldom used on its own, but is handy when you want to instantiate a type parameter in a way which indicates some sort of impossibility (e.g., here, using a free variable in a closed term). Often these parametrized types come with higher-order functions lifting operations on the parameters to operations on the whole type (e.g., here, `fmap`, `>>=`, `eval`). So you pass `absurd` as the general-purpose operation on `Void`.

For another example, imagine using `Either e v` to capture computations which hopefully give you a `v` but might raise an exception of type `e`. You might use this approach to document risk of bad behaviour uniformly. For perfectly well behaved computations in this setting, take `e` to be `Void`, then use

``````either absurd id :: Either Void v -> v
``````

to run safely or

``````either absurd Right :: Either Void v -> Either e v
``````

to embed safe components in an unsafe world.

Oh, and one last hurrah, handling a "can't happen". It shows up in the generic zipper construction, everywhere that the cursor can't be.

``````class Differentiable f where
type D f :: * -> *              -- an f with a hole
plug :: (D f x, x) -> f x       -- plugging a child in the hole

newtype K a     x  = K a          -- no children, just a label
newtype I       x  = I x          -- one child
data (f :+: g)  x  = L (f x)      -- choice
| R (g x)
data (f :*: g)  x  = f x :&: g x  -- pairing

instance Differentiable (K a) where
type D (K a) = K Void           -- no children, so no way to make a hole
plug (K v, x) = absurd v        -- can't reinvent the label, so deny the hole!
``````

I decided not to delete the rest, even though it's not exactly relevant.

``````instance Differentiable I where
type D I = K ()
plug (K (), x) = I x

instance (Differentiable f, Differentiable g) => Differentiable (f :+: g) where
type D (f :+: g) = D f :+: D g
plug (L df, x) = L (plug (df, x))
plug (R dg, x) = R (plug (dg, x))

instance (Differentiable f, Differentiable g) => Differentiable (f :*: g) where
type D (f :*: g) = (D f :*: g) :+: (f :*: D g)
plug (L (df :&: g), x) = plug (df, x) :&: g
plug (R (f :&: dg), x) = f :&: plug (dg, x)
``````

Actually, maybe it is relevant. If you're feeling adventurous, this unfinished article shows how to use `Void` to compress the representation of terms with free variables

``````data Term f x = Var x | Con (f (Term f x))   -- the Free monad, yet again
``````

in any syntax generated freely from a `Differentiable` and `Traversable` functor `f`. We use `Term f Void` to represent regions with no free variables, and `[D f (Term f Void)]` to represent tubes tunnelling through regions with no free variables either to an isolated free variable, or to a junction in the paths to two or more free variables. Must finish that article sometime.

For a type with no values (or at least, none worth speaking of in polite company), `Void` is remarkably useful. And `absurd` is how you use it.

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I'm thinking that perhaps it's useful in some cases as a type-safe way of exhaustively handling "can't happen" cases

This is precisely right.

You could say that `absurd` is no more useful than `const (error "Impossible")`. However, it is type restricted, so that its only input can be something of type `Void`, a data type which is intentionally left uninhabited. This means that there is no actual value that you can pass to `absurd`. If you ever end up in a branch of code where the type checker thinks that you have access to something of type `Void`, then, well, you are in an absurd situation. So you just use `absurd` to basically mark that this branch of code should never be reached.

"Ex falso quodlibet" literally means "from [a] false [proposition], anything follows". So when you find that you are holding a piece of data whose type is `Void`, you know you have false evidence in your hands. You can therefore fill any hole you want (via `absurd`), because from a false proposition, anything follows.

I wrote a blog post about the ideas behind Conduit which has an example of using `absurd`.

http://unknownparallel.wordpress.com/2012/07/30/pipes-to-conduits-part-6-leftovers/#running-a-pipeline

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Generally, you can use it to avoid apparently-partial pattern matches. For example, grabbing an approximation of the data type declarations from this answer:

``````data RuleSet a            = Known !a | Unknown String
data GoRuleChoices        = Japanese | Chinese
type LinesOfActionChoices = Void
type GoRuleSet            = RuleSet GoRuleChoices
type LinesOfActionRuleSet = RuleSet LinesOfActionChoices
``````

Then you could use `absurd` like this, for example:

``````handleLOARules :: (String -> a) -> LinesOfActionsRuleSet -> a
handleLOARules f r = case r of
Known   a -> absurd a
Unknown s -> f s
``````
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There are different ways how to represent the empty data type. One is an empty algebraic data type. Another way is to make it an alias for ∀α.α or

``````type Void' = forall a . a
``````

in Haskell - this is how we can encode it in System F (see Chapter 11 of Proofs and Types). These two descriptions are of course isomorphic and the isomorphism is witnessed by `\x -> x :: (forall a.a) -> Void` and by `absurd :: Void -> a`.

In some cases, we prefer the explicit variant, usually if the empty data type appears in an argument of an function, or in a more complex data type, such as in Data.Conduit:

``````type Sink i m r = Pipe i i Void () m r
``````

In some cases, we prefer the polymorphic variant, usually the empty data type is involved in the return type of a function.

`absurd` arises when we're converting between these two representations.

For example, `callcc :: ((a -> m b) -> m a) -> m a` uses (implicit) `forall b`. It could be as well of type `((a -> m Void) -> m a) -> m a`, because a call to the contination doesn't actually return, it transfers control to another point. If we wanted to work with continuations, we could define

``````type Continuation r a = a -> Cont r Void
``````

(We could use `type Continuation' r a = forall b . a -> Cont r b` but that'd require rank 2 types.) And then, `vacuousM` converts this `Cont r Void` into `Cont r b`.

(Also note that you can use haskellers.com to search for usage (reverse dependencies) of a certain package, like to see who and how uses the void package.)

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