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Is there some reason why the Prelude doesn't define the list monad like this? (Note the non-standard implementation of >>.)

instance  Monad []  where
    m >>= k          = concat (map k m)
    m >> k           = k                 -- a.k.a. flip const
    return x         = [x]
    fail s           = []

I tried checking this against the monad laws, but they don't mention >>. The Monad class definition is this:

m >> k = m >>= \_ -> k

which in the [] instance would translate to this:

concat (map (\_ -> k) m)

which is of course not equivalent to flip const—they produce an obviously different results for, say, [1..5] >> return 1. But it's not clear to me whether this default definition is a law that instances of Monad must respect, or just a default implementation that satisfies some other law that the flip const implementation would also satisfy.

Intuitively, given the intent of the list monad ("nondeterministic computations"), it seems like the alternative definition of >> would be just as good, if not better thanks to pruning branches that are guaranteed to be equal down to just one. Or another way of saying this is that if we were dealing with sets instead of lists, the two candidate definitions would be equivalent. But am I missing some subtlety here that makes the flip const definition wrong for lists?

EDIT: ehird's answer catches a very obvious flaw with the above, which is that it gets the wrong intended result for [] >> k, which should be [], not k. Still, I think the question can be amended to this definition:

[] >> k = []
_ >> k = k
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3 Answers 3

up vote 12 down vote accepted

a >> b must always be equivalent to a >>= const b; it's only in the Monad class so that you can define a more efficient (but semantically equivalent) version. That's why it's not part of the monad laws: it's not really part of the definition of a monad, only the typeclass (like fail).

Unfortunately, I can't find anywhere in the documentation for the base package where this is stated explicitly, but I think older versions may have defined (>>) outside of the Monad typeclass.

For what it's worth, your definition of (>>) breaks the list monad's use for nondeterministic computations. Since [] is used to represent failure, [] >> m must always be []; you can't continue on after you've exhausted all possible branches! It would also mean that these two programs:

do { m; ... }
do { _ <- m; ... }

could differ in behaviour, since the former desugars with (>>) and the latter with (>>=). (See the Haskell 2010 Report.)

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Yeah, the fact that I couldn't find any documentation on what laws >> should follow troubled me a bit. And yeah, duh, the [] >> m case kills the proposed implementation—but still, what about m >> k = if m == [] then [] else k? (I edited the question to reflect this.) –  Luis Casillas May 8 '12 at 0:22
The essential problem is that [()] and [(), ()] do not represent the same thing. The list monad is just one of many monads that model nondeterministic computation. If Set was a monad in Haskell, then you would be able to define (>>) like that for it. But lists are ordered and allow duplicates, so it isn't going to work; even if (>>) wasn't simply shorthand for (>>=) and discarding the argument, it would break the semantics in surprising ways. –  ehird May 8 '12 at 0:26

Because ma >> mb just is shorthand for ma >>= \_ -> mb. If >> were defined as flip const just in the case of lists, then ma >> mb wouldn't run the computation in ma at all if ma is a list, which would be very confusing.

As for why it isn't defined as flip const in general, well, the present semantics of >> makes it able to sequence effects where you don't care about their results, which is often useful.

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Your definition of >> breaks the Monad associativity law:

newtype B a = B { unB :: [a] }

instance Monad B where
  m >>= f = B . concatMap (unB.f) $ unB m
  (>>) = flip const
  return a = B [a]

case1 = B [1,2,3] >>= (\_ -> B [4,5,6] >> return 1)
case2 = (B [1,2,3] >>= \_ -> B [4,5,6]) >> return 1

main = do
  print $ unB case1
  print $ unB case2

The two cases above differ in their associativity, but yield different results.

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Hmm, I guess the monad laws are based only on >>=, and say nothing about >>, and that's your whole point... –  pat May 8 '12 at 4:39

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