map :: (a -> b) -> [a] -> [b]
putStrLn :: Show a => a -> IO ()
map putStrLn :: Show a => [a] -> [IO ()]
You've got a list of
IO () actions.
main :: IO ()
You need to join them into a single
IO () action.
What you want to do is to perform each of those
IO () actions in sequence/sequence_:
sequence :: Monad m => [m a] -> m [a]
sequence_ :: Monad m => [m a] -> m ()
For convenience, mapM/mapM_ will map a function over a list and sequence the resulting monadic results.
mapM :: Monad m => (a -> m b) -> [a] -> m [b]
mapM_ :: Monad m => (a -> m b) -> [a] -> m ()
So your fixed code would look like this:
main = mapM_ putStrLn $ map fizzBuzz [1..100]
Although I'd probably write it like this:
main = mapM_ (putStrLn . fizzBuzz) [1..100]
Or even this:
main = putStr $ unlines $ map fizzBuzz [1..100]
Let's write our own
sequence. What do we want it to do?
sequence  = return 
sequence (m:ms) = do
x <- m
xs <- sequence ms
return $ x:xs
- If there's nothing left in the list, return (inject into the monad) an empty list of results.
- Otherwise, within the monad,
- Bind (for the
IO monad, this means execute) the first result.
sequence the rest of the list; bind that list of results.
- Return a cons of the first result and the list of other results.
GHC's library uses something more like
foldr (liftM2 (:)) (return ) but that's harder to explain to a newcomer; for now, just take my word that they're equivalent.
sequence_ is easier, since it doesn't bother keeping track of the results. GHC's library implements it as
sequence_ ms = foldr (>>) (return ()) ms. Let's just expand the definition of
sequence [a, b, c, d]
= foldr (>>) (return ()) [a, b, c, d]
= a >> (b >> (c >> (d >> return ())))
In other words, "do
a, discard the result; do
b; discard the result, … finally, return
mapM f xs = sequence $ map f xs
mapM_ f xs = sequence_ $ map f xs
On the other hand, you don't even need to know monads at all with the alternate
unlines do? Well,
lines "a\nb\nc\nd\n" = ["a", "b", "c", "d"], so of course
unlines ["a", "b", "c", "d"] = "a\nb\nc\nd\n".
unlines $ map fizzBuzz [1..100] =
unlines ["1", "2", "Fizz", ..] =
"1\n2\nFizz\n..." and off it goes to
putStr. Thanks to the magic of Haskell's laziness, the full string never needs to be constructed in memory, so this will happily go to
[1..1000000] or higher :)