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The >> operator for Monads in haskell is often defined as

(>>) :: m a -> m b -> m b
a >> b = a >>= \_ -> b

It can be used to print things like

main = putStr "foo" >> putStrLn "bar"

Why does the compiler not optimize away the value of putStr "foo" and just evaluate putStrLn "bar"? It doesn't need it so why compute it?

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What makes you think that it doesn't need it? –  sepp2k Dec 15 '12 at 12:53
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What (>>) does depends on your monad. In the IO monad it's defined to combine the effects from both operands. Exactly how this is done depends on the monad definition. –  augustss Dec 15 '12 at 12:55
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[(),()] >> [1,2,3] ~> [1,2,3,1,2,3]. Even for something simple and pure like lists, the first argument is needed, the result depends on it. –  Daniel Fischer Dec 15 '12 at 12:58
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For lists (and Maybe and some others), yes it only needs the structure, not the contained values. For something like State s, I don't see how one could meaningfully speak of the "structure" like one can for lists; there, the state is (potentially) needed. In ma >> mb, the value of type a that ma returns is usually not evaluated (it may be, e.g. in State s, the state may depend on the value put (if even n then [] else [n]) >> return n, so when mb needs to evaluate the state, the value returned by ma is also evaluated). What parts of ma are evaluated depends on the monad. –  Daniel Fischer Dec 15 '12 at 14:24
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@DanielFischer: I like to use the deliberately generic term "shape" for the portions of a Functor-y type that are neither constant nor parametric--the side effects of IO, choice of constructor in Maybe or [], the state value in State, &c. This "shape" is exactly what (>>) retains and exactly what fmap leaves unchanged, so it's a useful concept for clarifying how things behave. –  C. A. McCann Dec 15 '12 at 16:20
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3 Answers

up vote 8 down vote accepted

As Chris said, it depends on the monad. Identity or Reader won't evaluate the part in front of >>, because they don't need it to compute the result. Other monads, like Writer, Maybe, Either, State or IO will.

Let's take Maybe as an example. >>= is defined as

Nothing  >>= _  = Nothing
(Just x) >>= f  = f x

So if we expand >> we get

Nothing  >> _  = Nothing
(Just x) >> y  = y

So Maybe must evaluate what's in front of >> to see if the result will be Nothing or y.

IO is purposely defined in a way so that the action is evaluated whether its result is needed or not (otherwise it would be just impossible to use).

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Huh? Of course it needs the value of putStr "foo". It's evaluated in >>= - only the result of the action is thrown away, not the action itself if you want to think of monads as actions.

For example in a parser, that would mean throwing away the just parsed sequence - but it was still parsed, so the cursor is still being moved forward.

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Compare with this expression, where haskell is smart enough to not try to find the last integer: const "foobar" . last $ [1..] –  Erik Henriksson Dec 15 '12 at 12:58
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@ErikHenriksson Yes, because the definition of const does not use its second argument. The same is not true for >>=. –  sepp2k Dec 15 '12 at 13:02
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@ErikHenriksson You're mixing up the monadic action putStr "foo" and the value produced by the monadic action putStr "foo". For instance, return [1..] >> putStrLn "Hello World" works just fine because the value [1..] is never evaluated, but return [1..] is. –  Cubic Dec 15 '12 at 13:06
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It depends on the monad. In IO is is evaluated. In Identity the first is not evaluated:

> import Control.Monad.Identity
> import Control.Monad.Trace
> let x = trace "x" $ return () :: Identity ()
> let y = trace "y" $ return () :: Identity ()
> runIdentity $ x >> y
y
()
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