`(m >>= f) >>= g` = `m >>= (\x -> f x >>= g)`

what's different from `f` and `\x->f x` ??

I think they're the same type `a -> m b`. but it seems that the second `>>=` at right side of equation treats the type of `\x->f x` as `m b`. what's going wrong?

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The expressions `f` and `\x -> f x` do, for most purposes, mean the same thing. However, the scope of a lambda expression extends as far to the right as possible, i.e. `m >>= (\x -> (f x >>= g))`.

If the types are `m :: m a`, `f :: a -> m b`, and `g :: b -> m c`, then on the left we have `(m >>= f) :: m b`, and on the right we have `(\x -> f x >>= g) :: a -> m c`.

So, the difference between the two expressions is just which order the `(>>=)` operations are performed, much like the expressions `1 + (2 + 3)` and `(1 + 2) + 3` differ only in the order in which the additions are performed.

Just a comment: `\x -> f x >>= g` is the same as `f >=> g`. (Kleisli fish) –  FUZxxl Dec 1 '11 at 20:54
In fact, the Typeclassopedia argues that this law is more elegantly stated in terms of `(>=>)`, recalling that that's basically composition. I as a learner agree. –  delnan Dec 1 '11 at 21:00
@delnan: I'd sooner write them all that way; they're monoid laws with `(<=<)` as the operator and `return` as the identity, after all, so might as well make that obvious. –  C. A. McCann Dec 1 '11 at 21:06