# How to convert a failed computation to a successful one and vice versa

This might very well be a solution seeking a problem ... if so, I beg your indulgence!

Possible implementation:

``````class Switch' f where
switch :: f a -> f ()

instance Switch' [] where
switch []     = [()]
switch (_:_)  = []

instance Switch' Maybe where
switch Nothing   = Just ()
switch (Just _)  = Nothing
``````

The interpretation would be: given a successful computation, make it a failing one; given a failing computation, make it a successful one. I'm not sure, but this seems like it might be sort of the opposite of MonadPlus ... if you squint really hard. ???

Is there a standard typeclass or some other implementation for this concept? What would the underlying math look like, if any (i.e. is this a semigroup, a loop, etc.)?

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`switch` is almost an element of order two - it's almost self inverse, in that `switch.switch.switch` = `switch.switch`. It generates eventually repeating orbits (although eventually is the correct word, it sounds lengthy when referring to a wait of 1 iteration). `switch.switch` is idempotent. That's all the maths I thought of to throw at switch just now. –  AndrewC Oct 30 '12 at 20:41
What makes `[()]` the right thing to return, rather than, say, `[(),()..]`? –  Daniel Wagner Oct 30 '12 at 23:10
It's `return ()`, like the other example. –  AndrewC Oct 31 '12 at 0:45
@AndrewC Maybe the law could be that `switch` specialized to `m () -> m ()` is an involution. –  Petr Pudlák Oct 31 '12 at 14:53
@PetrPudlák Yes, I think that's the perfect way of putting it. Good call. Since `switch :: Switch m => m a -> m ()`, we know `switch x :: m ()`, so then all the ones I said hold automatically. Very neat. Also involution is a nicer term than the ones I used. –  AndrewC Oct 31 '12 at 15:16

I found a completely different answer, and that is the `LogicT` monad transformer. It has `lnot` defined as:

``````lnot :: MonadLogic m => m a -> m ()
``````

Inverts a logic computation. If `m` succeeds with at least one value, ```lnot m``` fails. If `m` fails, then `lnot m` succeeds the value `()`.

I believe this is exactly what you wanted.

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Yeah, that look like it. Thanks! –  Matt Fenwick Jul 26 '13 at 11:41

I've got a generic solution but it can only work for `MonadPlus` instances that obey the left catch law (and that's probably only a necessary condition, not sufficient):

``````isZero :: (MonadPlus m) => m a -> m Bool
isZero x = (x >> return False) `mplus` return True

switch :: (MonadPlus m) => m a -> m ()
switch x = isZero x >>= \r -> if r then return () else mzero
``````

It works for `STM` too.

(For lists it always returns `[()]` though, I'd say this definition won't work for anything that is satisfies left distribution.)

It's not possible to define it in this way for `Applicative`s, because `switch` inspects the value of `isZero`, and applicatives cannot do that. (And, `MonadPlus` instances that satisfy the left-catch rule rarely satisfy `Applicative` laws.)

Anyhow it'd be interesting to see if `switch . (switch :: m () -> m ()) = id` holds for this definition.

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``````switch :: (Alternative f, Eq (f a)) => f a -> f ()
switch x | x == empty = pure ()
| otherwise = empty
``````

or

``````switch :: (MonadPlus m, Eq (m a)) => m a -> m ()
switch x | x == mzero = return ()
| otherwise = mzero
``````
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@MattFenwick my mistake, I've fixed them up. –  singpolyma Oct 30 '12 at 20:52
The `Eq` constraint is unfortunate –  singpolyma Oct 30 '12 at 20:53
When my data structures contain functions, or something else not `Eq`-able, what should I do? –  Matt Fenwick Oct 31 '12 at 15:05
@MattFenwick Not sure. It's almost like we want an `isEmpty` for `Monoid`/`Alternative`. Or some typeclass that let's us do an "outer-Eq" where `outereq :: f a -> f b -> Bool` –  singpolyma Oct 31 '12 at 18:56