The problem is you are confusing wrapped monadic values with pure values.

The first thing to know is that do notation is syntactic sugar for regular function calls (`>>=`

and `>>`

). So, it would help to see what your code desugars too.

Lets try something simpler

```
f a b =
do one <- a + b
return one
```

This has the same problem as your code, but is simpler. To understand why it doesn't work we ask: what does this actually mean? Well, we can rewrite the `<-`

symbol using `>>=`

```
f a b = (a + b) >>= \x -> return x
```

(this is not the simplest representation, but makes the point clear)

If you test the following in GHCi

```
>> :t (>>=)
Monad m => m a -> (a -> m b) -> m b
```

that is, the function `>>=`

takes: an argument of type `m`

of `a`

and a function from `a`

to `m`

of `b`

and returns a `m`

of `b`

.

What about in this code?

```
(a + b)
```

Is going to be a number.
How about the other half

```
\x -> return x
```

Takes an object of type `a`

and returns an object of type `m a`

for any `a`

So, you need to have a number, that is also some sort of monad of something. Can you think of anything like that? It is not clear what this would be, which is a reason to be suspicious that this should type check.

One good way to come to terms with monads is to look at some specific examples.

The `Maybe`

monad expresses computations that might fail

```
instance Monad Maybe where
return = Just
(>>=) (Just a) f = f a
(>>=) Nothing _ = Nothing
```

This lets you say things with a patter like

```
f args = do x <- functionThatMightFail args
y <- anotherfunctionThatMightFail x
return y
```

or the same code more simply

```
f args = do x <- functionThatMightFail args
anotherfunctionThatMightFail x
```

or perhaps

```
f args = functionThatMightFail args >>= anotherfunctionThatMightFail
```

On the other hand the `List`

monad captures the idea of performing the same function on every element of a list, and then concatenating the results together. Simple examples abound:

```
f = do x <- [1,2,3,4]
[1..x]
```

If you understand these ones, play with the `State`

monad. It helps you get the more general idea that "monads are models of computation." I would then checkout Parsec, and of course, IO