Considering the expression:

```
[0,1..] >>= \i -> [i * 2]
```

In the definition of `>>=`

for List, the lambda function `\i -> [i * 2]`

is mapped over the list argument via fmap, resulting in a list of lists, `[[0], [2]..]`

. So `>>=`

needs to flatten the result using a join function in order to return the list: `[0, 2..]`

According to this source: "...the definition of bind in terms of fmap and join works for every monad m: `ma >>= k = join $ fmap k ma`

"

So why is it necessary to place the burden of returning a monad on the function supplied to >>=? Why not simply define bind like so?

```
ma >>= k = fmap k ma
```

This way you don't have to deal with flattening the result.

`ma >>= k = join $ fmap k ma`

is more powerful. Your variant is just alias to`fmap`

,`ma >>= k = fmap k ma ~ (>>=) = flip fmap`

. – freestyle Nov 15 '17 at 21:09`fmap`

and`<$>`

. Of course in your specific example, those would have sufficed. – Bergi Nov 15 '17 at 21:40`>>=`

wasn't defined out of thin error; a function of type`a -> m b`

for a monad`m`

is a Kleisli arrow, and its use is firmly grounded in category theory. Monads are useful in programmingbecausethey "trap" values, making it easy to lift a value into the monad but hard to get out. – chepner Nov 15 '17 at 22:38`[0,1..] >>= \i -> [i * 2]`

doesn't return`[[0], [2]..]`

it returns`[0,2,4,6,8,..]`

just like`fmap (*2)`

would do however with the bind operator you have the option to use`return`

to make it return a monad properly so`[0,1..] >>= \i -> return [i * 2]`

would result`[[0],[2],[4],[6],[8],..]`

. Yet with`fmap`

its not the case`take 5 $ (\i -> [i * 2]) <$> [0..]`

would return`[[0],[2],[4],[6],[8],..]`

– Redu Nov 15 '17 at 22:59