I'm new to functional programming (coming from javascript), and I'm having a hard time telling the difference between the two, which is also messing with my understand of functors vs. monads.

Functor:

```
class Functor f where
fmap :: (a -> b) -> f a -> f b
```

Monad (simplified):

```
class Monad m where
(>>=) :: m a -> (a -> m b) -> m b
```

`fmap`

takes a function and a functor, and returns a functor.`>>=`

takes a function and a monad, and returns a monad.

The difference between the two is in the function parameter:

`fmap`

-`(a -> b)`

`>>=`

-`(a -> m b)`

`>>=`

takes a function parameter that returns a monad. I know that this is significant, but I'm having difficulty seeing how this one slight thing makes monads much more powerful than functors. Can someone explain?

`(>>=)`

,`(=<<)`

. With`(g <$>) :: f a -> f b`

, the function`g :: a -> b`

has no influence on the`f`

"wrapping" -- doesn't change it. With`(k =<<) :: m a -> m b`

, the function`k :: a -> m b`

itselfcreatesthe new`m`

"wrapping", so it can change.`>>=`

can do that`fmap`

can't do. In my head they're equivalent because I haven't seen an example, which shows that fmap is inadequate.`map`

. you can't. but with`concatMap`

, you can:`map (\x->x+1) [1,2,3]`

vs`concatMap (\x-> [x,x+1|even x]) [1,2,3])`

.`filter`

operation was just a sugary variant of`map`

, but just now I've realized that's not even possible.almost-filter with`map (\x -> [x|even x]) [1,2,3]`

but it produces`[[],[2],[]]`

and another level of interpretation done by`concat`

is then needed to make it really a`filter`

.