## About `return`

:

```
Prelude> :t return
return :: (Monad m) => a -> m a
```

So `return`

takes an argument of type `a`

, and returns something of type `m a`

. In this case `m`

is `LeafConType`

, so `LeafConType a`

is returned.

Now suppose that we pass `True`

. Then `a = Bool`

, so the return type must be `LeafConType Bool`

. However, you define:

```
return = LeafCon
```

So, `return True`

becomes `LeafCon True`

. But that is not allowed, because the type definition of `LeafConType`

states that

```
data LeafConType a = LeafCon (a, Int, Int)
```

So for `LeafConType Bool`

the argument to `LeafCon`

must have type `(Bool, Int, Int)`

, not just `Bool`

. And that is what the compile error means: `a`

cannot be the same as `(a, Int, Int)`

. You state:

I want to do calculations while `i`

is lower than `n`

.

This means that you will need some default values for `i`

and `n`

, for otherwise it will be impossible to define `return`

. If both of them are zero by default, then you could define:

```
return a = LeafCon (a, 0, 0)
```

## About `(>>=)`

:

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

Now look at your implementation (slightly different notation, same idea):

```
lc@(LeafCon (t, i, n)) >>= f | i >= n = lc
| otherwise = f t
```

What we see here, is that `lc`

is returned when `i >= n`

. But `lc`

is of type `LeafConType a`

, while `f`

is a function which may return a value of type `LeafConType b`

, for *any* `b`

. As a result it could be that `b`

is not equal to `a`

and hence these types don't match. In conclusion, you seriously have to ask yourself one question:

*Can this type of computation be expressed as a monad anyway?*