There are a few big problems here.

First, a `Monad`

instance must have kind `* -> *`

. That means they need at least one *type variable*, where your `Something`

doesn't have any. For comparison:

```
-- kind * -> *
Maybe
IO
Either String
-- kind *
Maybe Int
IO ()
Either String Double
```

See how each of `Maybe`

, `IO`

, and `Either String`

need a type parameter before you can use them? With `Something`

, there's no place for the type parameter to fill in. So you need to change your definition to:

```
data Something a = Something a
```

The second big problem is that the `>>=`

in your Monad instance is wrong. You generally can't use do-notation because that just calls the `Monad`

functions `return`

and `>>=`

. So you have to write it out without any monad functions, either do-notation or calling `>>=`

or `return`

.

```
instance Monad Something where
return a = Something a --Wraps a in 'Something'
(Something m) >>= f = f m --unwraps m and applies it to f
```

The definition of `>>=`

is simpler than you expected. Unwrapping `m`

is easy because you just need to pattern-match on the `Something`

constructor. Also `f :: a -> m b`

, so you don't need to worry about wrapping it up again, because `f`

does that for you.

While there's no way to unwrap a monad *in general*, very many *specific* monads can be unwrapped.

Be aware that there's nothing syntactically wrong with using do-notation or `>>=`

in the monad instance declaration. The problem is that `>>=`

is defined recursively so the program goes into an endless loop when you try to use it.

(N.B. `Something`

as defined here is the Identity monad)

For your third question, yes the `return`

function defined in the Monad instance is the one that will be called. Type classes are dispatched by type, and as you've specified the type must be `Something b`

the compiler will automatically use the Monad instance for `Something`

. (I think you meant the last line to be `doMagicTo var`

).