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This is a question that has come up several times for me in the design code, especially libraries. There seems to be some interest in it so I thought it might make a good community wiki.

The fail method in Monad is considered by some to be a wart; a somewhat arbitrary addition to the class that does not come from the original category theory. But of course in the current state of things, many Monad types have logical and useful fail instances.

The MonadPlus class is a sub-class of Monad that provides an mzero method which logically encapsulates the idea of failure in a monad.

So a library designer who wants to write some monadic code that does some sort of failure handling can choose to make his code use the fail method in Monad or restrict his code to the MonadPlus class, just so that he can feel good about using mzero, even though he doesn't care about the monoidal combining mplus operation at all.

Some discussions on this subject are in this wiki page about proposals to reform the MonadPlus class.

So I guess I have one specific question:

What monad instances, if any, have a natural fail method, but cannot be instances of MonadPlus because they have no logical implementation for mplus?

But I'm mostly interested in a discussion about this subject. Thanks!

EDIT: One final thought occured to me. I recently learned (even though it's right there in the docs for fail) that monadic "do" notation is desugared in such a way that pattern match failures, as in (x:xs) <- return [] call the monad's fail.

It seems like the language designers must have been strongly influenced by the prospect of some automatic failure handling built in to haskell's syntax in their inclusion of fail in Monad.

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It’s an ill-posed question, but probably one that in the answering will help clarify things. The most important step is to decide what algebraic laws MonadPlus should follow, but it's also worth thinking about what programmers might expect fail and mzero to do. –  Edward Z. Yang Feb 17 '11 at 1:21
I think I'm really just inviting a discussion about the inclusion of fail in Monad, and perhaps an expansion on the vein of discussion in the MonadPlus wiki discussion page above. Maybe my answer can be edited to better serve that goal. –  jberryman Feb 17 '11 at 3:51
Oh, most people don't like fail and think it should not live in Monad :-) –  Edward Z. Yang Feb 17 '11 at 11:25
Changed tag [class] to [typeclass], as class is used almost exclusively for OO programming. Haskellers usually use the [typeclass] tag. –  FUZxxl Feb 17 '11 at 15:04
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2 Answers

Think of Either. It's monadic instance looks like this:

{-# LANGUAGE FlexibleInstances #-}
instance Monad (Either String) where
  (Left x) >>= _   = Left x
  (Right a)  >>= f = f a
  return           = Right
  fail             = Left

(We need FlexibleInstances in order to allow an instance like Either String)
So it's basically like Maybe with an optional error message if something happens. You can't recreate this with mzero, as you can't add an error message to the failure. It's somewhat different from fail.

Each instance of mplus should satisfy these two laws:

mzero `mplus` a -> a
a `mplus` mzero -> a

Simple, isn't it? But these laws make mplus special. With them, it's possible to write a reasonable MonadPlus instance for it:

instance MonadPlus Either a where
  mzero = Left undefined
  mplus (Left _) b = b
  mplus a _        = a

What is this? It represents a choice. If the first computation is successful, it will be returned. Else, mplus returns the second computation. Note how it differs from (>>), which doesn't satisfies the laws:

Left a   >>    Right b -> Left a
Left a `mplus` Right b -> Right b

(>>) will stop on the first computation, while mplus tries the second one instead. [] also behaves like this:

[] >> [1..4] -> []
[] `mplus` [1..4] -> [1,2,3,4]

This is just to discuss the aspects of MonadPlus and specially the aspect of mplus in contrast to (>>).

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Oh, duh. Trying not to short-cirtuit in (Left a) >>= f = ... necessitates inventing an argument. Even when that gets ignored by (>>), it makes the Monad instance right-out evil. So while it may be possible to derive mplus, it cannot be (reliably) done in a way not introducing non-totality, that is, it cannot be done sensibly. That said, I think you meant to return x instead of a in your second code line. –  barsoap Feb 17 '11 at 14:53
I think you mean x@(Left _) >>= _ = x, not x@(Left a) >>= _ = a (since a is a String not an Either String t for some type t) –  rampion Feb 17 '11 at 14:55
Yes. Fixed that typo. Already prepared for this using @, but then entered the wrong character. –  FUZxxl Feb 17 '11 at 15:01
Try to type-check your Monad instance. It has a syntax bug and a type error. –  Peaker Feb 18 '11 at 23:16
@Peaker: Fixed it. Thank you for the tip. –  FUZxxl Feb 20 '11 at 15:22
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In this answer, I want to discuss the topic, why fail isa member of Monad. I don't want to add this to my other answer, since it covers another topic.

Although the mathematical definition of a monad doesn't contains fail, the creators of Haskell 98 put it into the Monad typeclass. Why?

In order to ease the usage of monads and to make it easier to abstract the usage of monads, they introduced the do notation, a very useful piece of sugar. For example, this code:

do putStr "What's your full name? "
   [name,surname] <- getLine >>= return . words
   putStr "How old are you? "
   age <- getLine >>= return . read
   if age >= 18
      then putStrLn $ "Hello Mr / Ms " ++ surname
      else putStrLn $ "Hello " ++ name

translates to:

putStr "What's your full name? " >>
getLine >>= return . words >>= \[name,surname] ->
putSr "How old are you? " >>
getLine >>= return . read >>= \age ->
if age >= 18
   then putStrLn $ "Hello Mr / Ms " ++ surname
   else putStrLn $ "Hello " ++ name

What's the problem here? Imagine you have a name with a space in between, like Jon M. Doe. In this case, the whole construct will be _|_. Sure, you can work around this by adding some ad-hoc function with let, but this is pure boilerplate. At the time Haskell 98 was created, there wasn't an exception system like today, where you could simply catch the failed pattern matching. Also, incomplete patterns are considered bad coding style.

What's the solution? The creators of Haskell 98 added a special function fail, called in the case of a mismatch. The desugaring looks somewhat like this:

putStr "What's your full name? " >> let
  helper1 [name,surname] =
    putSr "How old are you? " >> let
      helper2 age =
        if age >= 18
           then putStrLn $ "Hello Mr / Ms " ++ surname
           else putStrLn $ "Hello " ++ name
      helper2 _ = fail "..."
    in getLine >>= return . read >>= helper2
  helper1 _ = fail "..."
in getLine >>= return . words >>= helper1

(I'm not sure whether there is really a helper2, but I think so)

If you look twice at this, you'll find out how smart it is. First, there's never an incomplete pattern match, and second you can make fail configurizable. To achieve this, they just put fail into the monads definition. For example, for Maybe, fail is simply Nothing and for the instance of Either String, it's Left. This way, it's easy to write monad-independent monadic code. For instance, for a long time lookup was defined as (Eq a,Monad b) => a -> [(a, b)] -> m b, and lookup returned fail if there wasn't a match.

Now, there's still the big question in the Haskell community: isn't it a bad idea to add something completely independent to the Monad typeclass like fail? I can't answer this question, but IMHO this decision was right, as other places aren't that comfortable for fail.

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I still don't buy that fail must be in Monad, instead of its own class, to enable that. I absolutely wouldn't mind getting compiler errors along the lines of No instance for (Failure Foo) arising from an incomplete pattern match in do notation at <whereever>. It might not fit particularly well into existing compiler pipelines, though. –  barsoap Feb 17 '11 at 15:55
If it would be in another class, the behavior would depend on whether there is an instance of this class. Or you would be forced to declare an instance to use the sugar. This could change the meaning of your code, if some jerk would define an instance of that class in some other module. Also notice, that instances are like a virus, once defined they're valid everywhere. Also, for performance issues all instances of classes are static and known before execution. There isn't a runtime check "am I instance of Foo" while running. This kind of static typing is a basic attribute of Haskell. –  FUZxxl Feb 17 '11 at 16:07
what would change is not the dynamic behaviour: Incomplete pattern matches would be a compile-time error when the instance is missing, no run-time checks involved, so the only thing that jerk can do is make non-compiling code compile (Or the other way round if he introduces a duplicate instance, but that's the case for Monad, too). If you want a yet higher degree of security, there's always -fwarn-incomplete-patterns. –  barsoap Feb 17 '11 at 16:21
@barsoap: I don't wan't to start a flame. Personally, I like it as it is. I think it's mostly a matter of taste and whether you like mathematical correctness or pragmatism. –  FUZxxl Feb 17 '11 at 16:36
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