# Is `data PoE a = Empty | Pair a a` a monad?

This question comes from this answer in example of a functor that is Applicative but not a Monad: It is claimed that the

``````data PoE a = Empty | Pair a a deriving (Functor,Eq)
``````

cannot have a monad instance, but I fail to see that with:

``````instance Applicative PoE where
pure x = Pair x x
Pair f g <*> Pair x y = Pair (f x) (g y)
_        <*> _        = Empty
Empty    >>= _ = Empty
Pair x y >>= f = case (f x, f y) of
(Pair x' _,Pair _ y') -> Pair x' y'
_ -> Empty
``````

The actual reason why I believe this to be a monad is that it is isomorphic to `Maybe (Pair a)` with `Pair a = P a a`. They are both monads, both traversables so their composition should form a monad, too. Oh, I just found out not always.

Which counter-example failes which monad law? (and how to find that out systematically?)

edit: I did not expect such an interest in this question. Now I have to make up my mind if I accept the best example or the best answer to the "systematically" part.

Meanwhile, I want to visualize how `join` works for the simpler `Pair a = P a a`:

``````                   P
________/ \________
/                   \
P                     P
/ \                   / \
1   2                 3   4
``````

it always take the outer path, yielding `P 1 4`, more commonly known as a diagonal in a matrix representation. For monad associativy I need three dimensions, a tree visualization works better. Taken from chi's answer, this is the failing example for join, and how I can comprehend it.

``````                  Pair
_________/\_________
/                    \
Pair                   Pair
/\                     /\
/  \                   /  \
Pair  Empty           Empty  Pair
/\                           /\
1  2                         3  4
``````

Now you do the `join . fmap join` by collapsing the lower levels first, for `join . join` collapse from the root.

• I'm sure you already noticed this, but the answerer did reply to your comment on that post that you linked. I personally am not able to construct a counterexample fitting his description at a glance, but I wanted to make you aware of his comment. – Silvio Mayolo Apr 9 '18 at 22:25
• What makes an applicative a Monad is the ability to squash it (using join) and so transform a pair of pair to a pair. You can't do it without losing some elements (going from 4 to 2) as you do in your example. That's will break the laws. For example `Pair (Pair 1 2) Empty >>= return ` returns Empty. That s not good . – mb14 Apr 9 '18 at 22:30
• I ran it in TIO and I don't get `Empty` – Silvio Mayolo Apr 9 '18 at 22:33
• I meant `>>= id` – mb14 Apr 10 '18 at 6:40
• Interesting that very similar type is actually a monad: stackoverflow.com/questions/43684258/… – Shersh Apr 10 '18 at 8:41

Apparently, it is not a monad. One of the monad "`join`" laws is

``````join . join = join . fmap join
``````

Hence, according to the law above, these two outputs should be equal, but they are not.

``````main :: IO ()
main = do
let x = Pair (Pair (Pair 1 2) Empty) (Pair Empty (Pair 7 8))
print (join . join \$ x)
-- output: Pair 1 8
print (join . fmap join \$ x)
-- output: Empty
``````

The problem is that

``````join x      = Pair (Pair 1 2) (Pair 7 8)
fmap join x = Pair Empty Empty
``````

Performing an additional `join` on those does not make them equal.

how to find that out systematically?

`join . join` has type `m (m (m a)) -> m (m a)`, so I started with a triple-nested `Pair`-of-`Pair`-of-`Pair`, using numbers `1..8`. That worked fine. Then, I tried to insert some `Empty` inside, and quickly found the counterexample above.

This approach was possible since a `m (m (m Int))` only contains a finite amount of integers inside, and we only have constructors `Pair` and `Empty` to try.

For these checks, I find the `join` law easier to test than, say, associativity of `>>=`.

• Well played. You can make the `Empty` disappear by positioning them carefully. Good answer! – Silvio Mayolo Apr 9 '18 at 22:57

QuickCheck immediately finds a counterexample to associativity.

``````{-# LANGUAGE DeriveFunctor #-}

import Test.QuickCheck

data PoE a = Empty | Pair a a deriving (Functor,Eq, Show)

instance Applicative PoE where
pure x = Pair x x
Pair f g <*> Pair x y = Pair (f x) (g y)
_        <*> _        = Empty
Empty    >>= _ = Empty
Pair x y >>= f = case (f x, f y) of
(Pair x' _,Pair _ y') -> Pair x' y'
_ -> Empty

instance Arbitrary a => Arbitrary (PoE a) where
arbitrary = oneof [pure Empty, Pair <\$> arbitrary <*> arbitrary]

prop_assoc :: PoE Bool -> (Bool -> PoE Bool) -> (Bool -> PoE Bool) -> Property
prop_assoc m k h =
((m >>= k) >>= h) === (m >>= (\a -> k a >>= h))

main = do
quickCheck \$ \m (Fn k) (Fn h) -> prop_assoc m k h
``````

Output:

``````*** Failed! Falsifiable (after 35 tests and 3 shrinks):
Pair True False
{False->Pair False False, True->Pair False True, _->Empty}
{False->Pair False True, _->Empty}
Pair False True /= Empty
``````
• It's funny, I used `Bool` and no counterexample was found; I thought maybe the laws held just for bool because of some anomaly. But I guess it's just the imperfection of randomness.. – luqui Apr 9 '18 at 23:06

Since you are interested in how to do it systematically, here's how I found a counterexample with quickcheck:

``````{-# LANGUAGE DeriveFunctor #-}

import Test.QuickCheck

``````

Defining an arbitrary instance to generate random `PoE`s.

``````instance (Arbitrary a) => Arbitrary (PoE a) where
arbitrary = do
emptyq <- arbitrary
if emptyq
then return Empty
else Pair <\$> arbitrary <*> arbitrary
``````

And tests for the monad laws:

``````prop_right_id m = (m >>= return) == m
where
_types = (m :: PoE Int)

prop_left_id fun x = (return x >>= f) == f x
where
_types = fun :: Fun Int (PoE Int)
f = applyFun fun

prop_assoc fun gun hun x = (f >=> (g >=> h)) x == ((f >=> g) >=> h) x
where
_types = (fun :: Fun Int (PoE Int),
gun :: Fun Int (PoE Int),
hun :: Fun Int (PoE Int),
x :: Int)
f = applyFun fun
g = applyFun gun
h = applyFun hun
``````

I don't get any failures for the identity laws, but `prop_assoc` does generate a counterexample:

``````ghci> quickCheck prop_assoc
*** Failed! Falsifiable (after 7 tests and 36 shrinks):
{6->Pair 1 (-1), _->Empty}
{-1->Pair (-3) (-4), 1->Pair (-1) (-2), _->Empty}
{-3->Empty, _->Pair (-2) (-4)}
6
``````

Not that it's terribly helpful for understanding why the failure occurs, it does give you a place to start. If we look carefully, we see that we are passing `(-3)` and `(-2)` to the third function; `(-3)` maps to `Empty` and `(-2)` maps to a `Pair`, so we can't defer to the laws of either of the two monads `PoE` is composed of.

This kind of potential `Monad` instance can be concisely described as "taking the diagonal". It is easier to see why if we use the `join` presentation. Here is `join` for the `Pair` type you mention:

``````join (P (P a00 a11) (P a10 a11)) = P a00 a11
``````

Taking the diagonal, however, is only guaranteed to give a lawful `join` for fixed length (or infinite) lists. That's because of the associativity law:

``````join . join = join . fmap join
``````

If the n-th list in a list of lists doesn't have an n-th element, it will lead to the diagonal being trimmed: it will end before its n-th element. `join . join` takes the outer diagonal (of a list of lists of lists) first, while `join . fmap join` takes the inner diagonals first. It may be possible for an insufficiently long innermost list which is not in the outer diagonal to trim `join . fmap join`, but it can't possibly affect `join . join`. (This would be easier to show with a picture instead of words.)

Your `PoE` is a list-like type that doesn't have fixed length (the length is either zero or two). It turns out that taking its diagonal doesn't give us a monad, as the potential issue discussed above actually gets in the way (as illustrated in chi's answer).

• This is precisely the reason `ZipList` is not a monad: the zippy behaviour amounts to taking the diagonal.

• Infinite lists are isomorphic to functions from the naturals, and fixed length lists are isomorphic to functions from the naturals up to an appropriate value. This means you can get a `Monad` instance for them out of the instance for functions -- and the instance you get, again, amounts to taking the diagonal.

(Posting this as a separate answer, as it has little overlap with my other one.)

The actual reason why I believe this to be a monad is that it is isomorphic to `Maybe (Pair a)` with `Pair a = P a a`. They are both monads, both traversables so their composition should form a monad, too. Oh, I just found out not always.

The conditions for the composition of monads `m`-over-`n` with `n` traversable are:

``````-- Using TypeApplications notation to make the layers easier to track.
sequenceA @n @m . pure @n = fmap @m (pure @n)
sequenceA @n @m . fmap @n (join @m)
= join @m . fmap @m (sequenceA @n @m) . sequenceA @n @m
sequenceA @n @m . join @n
= fmap @m (join @n) . sequenceA @n @m . fmap @n (sequenceA @n @m)
``````

(There is also `sequenceA @n @m . fmap @n (pure @m) = pure @m`, but that always holds.)

In our case, we have `m ~ Maybe` and `n ~ Pair`. The relevant method definitions for `Pair` would be:

``````fmap f (P x y) = P (f x) (f y)
pure x = P x x
P f g <*> P x y = P (f x) (g y)
join (P (P a00 a01) (P a10 a11)) = P a00 a11 -- Let's pretend join is a method.
sequenceA (P x y) = P <\$> x <*> y
``````

Let's check the third property:

``````sequenceA @n @m . join @n
= fmap @m (join @n) . sequenceA @n @m . fmap @n (sequenceA @n @m)

-- LHS
sequenceA . join \$ P (P a00 a01) (P a10 a11)
sequenceA \$ P a00 a11
P <\$> a00 <*> a11 -- Maybe (Pair a)

-- RHS
fmap join . sequenceA . fmap sequenceA \$ P (P a00 a01) (P a10 a11)
fmap join . sequenceA \$ P (P <\$> a00 <*> a01) (P <\$> a10 <*> a11)
fmap join \$ P <\$> (P <\$> a00 <*> a01) <*> (P <\$> a10 <*> a11)
fmap join \$ (\x y z w -> P (P x y) (P z w)) <\$> a00 <*> a01 <*> a10 <*> a11
(\x _ _ w -> P x w) <\$> a00 <*> a01 <*> a10 <*> a11 -- Maybe (Pair a)
``````

These are clearly not the same: while any `a` values will be drawn exclusively from `a00` and `a11`, the effects of `a01` and `a10` are ignored in the left-hand side, but not in the right-hand side (in other words, if `a01` or `a10` are `Nothing`, the RHS will be `Nothing`, but the LHS won't necessarily be so). The LHS corresponds exactly to the vanishing `Empty` in chi's answer, and the RHS corresponds to the inner diagonal trimming described in my other answer.

P.S.: I forgot to show that the would-be instance we are talking about here is the same one being discussed in the question:

``````join' ::  m (n (m (n a))) -> m (n a)
join' = fmap @m (join @n) . join @m . fmap @m (sequenceA @n @m)
``````

With `m ~ Maybe` and `n ~ Pair`, we have:

``````join' :: Maybe (Pair (Maybe (Pair a))) -> Maybe (Pair a)
join' = fmap @Maybe (join @Pair) . join @Maybe . fmap @Maybe (sequenceA @Pair @Maybe)
``````

`join @Maybe . fmap @Maybe (sequenceA @Pair @Maybe)` means the `join'` will result in `Nothing` unless there are no `Nothing`s anywhere:

``````join' = \case
Just (P (Just (P a00 a01)) (Just (P a10 a11))) -> _
_ -> Nothing
``````

Working out the non-`Nothing` case is straightforward:

``````fmap join . join . fmap sequenceA \$ Just (P (Just (P a00 a01)) (Just (P a10 a11)))
fmap join . join \$ Just (Just (P (P a00 a01) (P a10 a11)))
fmap join \$ Just (P (P a00 a01) (P a10 a11))
Just (P a00 a11)
``````

Therefore...

``````join' = \case
Just (P (Just (P a00 _)) (Just (P _ a11))) -> Just (P a00 a11)
_ -> Nothing
``````

... which is essentially the same as:

``````join = \case
Pair (Pair a00 _) (Pair _ a11) -> Pair (a00 a11)
_ -> Empty
``````