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To clarify the question: it is about the merits of the monad type class (as opposed to just its instances without the unifying class).

After having read many references (see below), I came to the conclusion that, actually, the monad class is there to solve only one, but big and crucial, problem: the 'chaining' of functions on types with context. Hence, the famous sentence "monads are programmable semicolons". In fact, a monad can be viewed as an array of functions with helper operations.

I insist on the difference between the monad class, understood as a general interface for other types; and these other types instantiating the class (thus, "monadic types").

I understand that the monad class by itself, only solves the chaining of operators because mainly, it only mandates its type instances to have bind >>= and return, and tell us how they must behave. And as a bonus, the compiler greatyly helps the coding providing do notation for monadic types.

On the other hand, it is each individual type instantiating the monad class which solves each concrete problem, but not merely for being a instance of Monad. For instance Maybe solves "how a function returns a value or an error", State solves "how to have functions with global state", IO solves "how to interact with the outside world", and so on. All theses classes encapsulate a value within a context.

But soon or later, we will need to chain operations on such context-types. I.e., we will need to organize calls to functions on these types in a particular sequence (for an example of such a problem, please read the example about multivalued functions in You could have invented monads).

And you get solved the problem of chaining, if you have each type be an instance of the monad class. For the chaining to work you need >>= just with the exact signature it has, no other. (See this question).

Therefore, I guess that the next time you define a context data type T for solving something, if you need to sequence calls of functions (on values of T) consider making T an instance of Monad (if you need "chaining with choice" and if you can benefit from the do notation). And to make sure you are doing it right, check that T satisfies the monad laws

Then, I ask two questions to the Haskell experts:

  1. A concrete question: is there any other problem that the monad class solves by ifself (leaving apart monadic classes)? If any, then, how it compares in relevance to the problem of chaining operations?
  2. An optional general question: are my conclusions right, am I misunderstanding something?

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Just for clarification, are you wondering about the merits of the monad type class (as opposed to just its instances without the unifying class), or the monad concept (as defined by the monad operations and laws)? –  ollanta Jan 21 '14 at 15:06
    
@ollanta about the merits of the monad type class (as opposed to just its instances without the unifying class), –  cibercitizen1 Jan 21 '14 at 15:10
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Then I would say it doesn't solve any problem except boilerplate, like all type classes. I don't think anyone would say the monad type class solves X problems. Rather it reifies a useful concept in Haskell, so that we can talk about functions on monads (understanding their possibilities and limitations), instead of functions on types and more functions on those types implementing a specialized protocol. It's all about making abstraction beautiful. –  ollanta Jan 21 '14 at 15:26
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From the 2 answers given: "the monad class allows its instance types to reuse the code for chaining operations, and makes it possible that a chained operation depends on the result of the previous one". –  cibercitizen1 Jan 21 '14 at 22:00

2 Answers 2

up vote 21 down vote accepted

You're definitely on to something in the way that you're stating this—there are many things that Monad means and you've separated them out well.

That said, I would definitely say that chaining operations is not the primary thing solved by Monads. That can be solved using plain Functors (with some trouble) or easily with Applicatives. You need to use the full monad spec when "chaining with choice". In particular, the tension between Applicative and Monad comes from Applicative needing to know the entire structure of the side-effecting computation statically. Monad can change that structure at runtime and thus sacrifices some analyzability for power.


To make the point more clear, the only place you deal with a Monad but not any specific monad is if you're defining something with polymorphism constrained to be a Monad. This shows up repeatedly in the Control.Monad module, so we can examine some examples from there.

sequence     :: [m a] -> m [a]
forever      :: m a   -> m b
foldM        :: (a -> b -> m a) -> a -> [b] -> m a

Immediately, we can throw out sequence as being particular to Monad since there's a corresponding function in Data.Traversable, sequenceA which has a type slightly more general than Applicative f => [f a] -> f [a]. This ought to be a clear indicator that Monad isn't the only way to sequence things.

Similarly, we can define foreverA as follows

foreverA :: Applicative f => f a -> f b
foreverA f = flip const <$> f <*> foreverA f

So more ways to sequence non-Monad types. But we run into trouble with foldM

foldM             :: (Monad m) => (a -> b -> m a) -> a -> [b] -> m a
foldM _ a []      =  return a
foldM f a (x:xs)  =  f a x >>= \fax -> foldM f fax xs

If we try to translate this definition to Applicative style we might write

foldA             :: (Applicative f) => (a -> b -> f a) -> a -> [b] -> f a
foldA _ a []      =  pure a
foldA f a (x:xs)  = foldA f <$> f a x <*> xs

But Haskell will rightfully complain that this doesn't typecheck--each recursive call to foldA tries to put another "layer" of f on the result. With Monad we could join those layers down, but Applicative is too weak.


So how does this translate to Applicatives restricting us from runtime choices? Well, that's exactly what we express with foldM, a monadic computation (a -> b -> m a) which depends upon its a argument, a result from a prior monadic computation. That kind of thing simply doesn't have any meaning in the more purely sequential world of Applicative.

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In summary you need a monad when "the next action depends on the value returned by the previous action". You can get away with an applicative when "the next value depends on the previous value, but the action run to generate that value does not". –  Tom Ellis Jan 21 '14 at 16:54
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... and a functor is just when you don't need to create any new side effects at all. –  jozefg Jan 21 '14 at 16:55
    
@jozefg Well, you still can use Fix to create a whole nested set of effects that you interpret elsewhere. data SayHi a = SayHi a | Done, io :: Fix SayHi -> IO (); io (Fix Done) = return (); io (Fix SayHi next) = putStrLn "hi" >> io next. –  J. Abrahamson Jan 21 '14 at 17:38
    
@J.Abrahamson But the Functor type class -- and in particular its only method fmap -- doesn't let you introduce new "side effects" into an existing Fix SayHi value. That's the point I think jozefg was trying to make. Of course specific functors can have functions that introduce new side effects, but that's beside the point. –  Daniel Wagner Jan 21 '14 at 21:00
    
That's true. I think I'm stuck on thinking about that due to trying to be explicit about what exactly causes sequencing of effects. Nesting of Functors is one blind way to achieve that without any more structure. –  J. Abrahamson Jan 21 '14 at 21:15

To solve the problem of chaining operations on an individual monadic type, it's not at all necessary to make it an instance of Monad and be sure the monad laws are satisfied. You could just implement a chaining operation directly on your type.

It would probably be very similar to the monadic bind, but not necessarily exactly the same (recall that bind for lists is concatMap, a function that exists anyway, but with the arguments in a different order). And you wouldn't have to worry about the monad laws, because you would have a slightly different interface for each type, so they wouldn't have any common requirements.

To ask what problem the Monad type class itself solves, look at all the functions (in Control.Monad and else where) that work on values in any monadic type. The problem solved is code reuse! Monad is exactly the part of all the monadic types that is common to each and every one of them. That part is sufficient on its own to write useful computations. All of these functions could be implemented for any individual monadic type (often more directly), but they've already been implemented for all monadic types, even the ones that don't exist yet.

You don't write a Monad instance so that you can chain operations on your type (often you already have a way of chaining, in fact). You write a Monad instance for all the code that automatically comes along with the Monad instance. Monad isn't about solving any problem for any single type, it's about a way of viewing many disparate types as instances of a single unifying concept.

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Thanks. I think that your point that the Monad class is for "reusing the code that allows chaining operations" is not explicitly stated in my question (only implicit) and that it is worth to stress it. –  cibercitizen1 Jan 21 '14 at 21:55

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