Applicatives compose, monads don't.
What does the above statement mean? And when is one preferable to other?
If we compare the types
we get a clue to what separates the two concepts. That
which uses the result of some effect to decide between two computations (e.g. launching missiles and signing an armistice), whereas
which uses the value of
The monadic version relies essentially on the extra power of
we get this far, but now our layers are all jumbled up. We have an
to permute the
The weaker ‘double-apply’ is much easier to define
because there is no interference between the layers.
Correspondingly, it's good to recognize when you really need the extra power of
Note, by the way, that although composing monads is difficult, it might be more than you need. The type
Monads do compose, but the result might not be a monad.
In contrast, the composition of two applicatives is necessarily an applicative.
I suspect the intention of the original statement was that "Applicativeness composes, while monadness doesn't." Rephrased, "
If you have applicatives
On the other hand, if you have monads
One example can be the type
And that generalizes to any applicative:
But there is no sensible definition of
Composing monads, http://web.cecs.pdx.edu/~mpj/pubs/RR-1004.pdf
The distributive law solution l : MN -> NM is enough
to guarantee monadicity of NM. To see this you need a unit and a mult. i'll focus on the mult (the unit is unit_N unitM)
This does not guarantee that MN is a monad.
The crucial observation however, comes into play when you have distributive law solutions
thus, LM, LN and MN are monads. The question arises as to whether LMN is a monad (either by
(MN)L -> L(MN) or by N(LM) -> (LM)N
We have enough structure to make these maps. However, as Eugenia Cheng observes, we need a hexagonal condition (that amounts to a presentation of the Yang-Baxter equation) to guarantee monadicity of either construction. In fact, with the hexagonal condition, the two different monads coincide.