# It's not a monad, but what is it?

According to the Haskell wikibook, a `Monad` called `m` is a `Functor` with two additional operations:

``````unit :: a -> m a
join :: m (m a) -> m a
``````

That's nice, but I have something slightly different. Glossing over the gory details, I have a type that has good `unit` and `join` functions, but its `fmap` is not well behaved (`fmap g . fmap f` is not necessarily `fmap (g.f)`). Because of this, it cannot be made an instance of `Monad`. Nonetheless, I'd like to give it as much generic functionality as possible.

So my question is, what category theoretic structures are similar to monads in that they have a `unit` and `join`?

I realize that on some level, the above question is ill-defined. For monads the `unit` and `join` definitions only make sense in terms of the `fmap` definition. Without `fmap`, you can't define any of the monad laws, so any definitions of `unit`/`join` would be equally "valid." So I'm looking for functions other than `fmap` that it might make sense to define some "not-monad" laws on these `unit` and `join` functions.

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Can you describe more about the structure you have, and what in particular causes it to fail the fusion law for `fmap`? –  luqui Jun 10 '13 at 23:35
I suppose you specifically "tweaked" `fmap` in a way so that `join` fulfills the 2nd monad law? Normally, you almost always get `fmap g . fmap f ≡ fmap \$ f.g` just automatically. –  leftaroundabout Jun 10 '13 at 23:47
@luqui I'm more interested in general than just this specific case, but it's a normal distribution. If you think about `fmap` as applying a function to every point in a distribution, then `fmap` only obeys the `Functor` laws for addition and multiplication. `unit` is training on a single data point, and `join` is merging a "normal distribution of normal distributions" into a single normal distribution. Obviously, this requires some constraints on the parameters, so it can't be done at all using the `Base` type classes and I'be been using `ConstraintKinds` to play around with it. –  Mike Izbicki Jun 11 '13 at 0:36
As is well-known by now, "monads are just monoids in the category of endofunctors". So you're looking for a `monoid`, just in a different category. I'm not sure what category would correspond to normal distributions, but I'm a bit suspicious. My intuition (which is frequently wrong FWIW) is that the only structure imposed by a normal distribution is isomorphic to a List. –  John L Jun 11 '13 at 4:40
Your normal-distribution application sounds quite similar to what I tried as an uncertainty-propagation type. I think I checked it does obey the functor law, if you obtain the result width with differentiation laws! Certainly when the distribution widths remain small enough that you can neglect higher-order Taylor summands; otherwise the whole approach doesn't seem very useful anyway. –  leftaroundabout Jun 11 '13 at 13:56

Well here's one law you should have with just `unit` and `join`. Given `x :: m a`,

``````join (unit x) = x
``````

``````return x >>= f = f x
``````

Given that `m >>= f = join (fmap f m)`

``````join (fmap f (return x)) = f x
``````

Select `f = id`

``````join (fmap id (return x)) = id x
``````

Use the functor law that `fmap id = id`

``````join (id (return x)) = id x
``````

Use the obvious `id a = a`

``````join (return x) = x
``````
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