dave4420 hits it, but I think the following remarks might still be useful.

There are rules that you can use to validly "rewrite" a type into another type that's compatible with the original. These rules involve replacing all occurrences of a type variable with some other type:

- If you have
`id :: a -> a`

, you can replace `a`

with `c`

and get `id :: c -> c`

. This latter type can also be rewritten to the original `id :: a -> a`

, which means that these two types are equivalent. As a general rule, if you replace all instances of type variable with another type variable that occurs nowhere in the original, you get an equivalent type.
- You can replace all occurrences of a type variable with a concrete type. I.e., if you have
`id :: a -> a`

, you can rewrite that to `id :: Int -> Int`

. The latter however can't be rewritten back to the original, so in this case you're **specializing** the type.
- More generally than the second rule, you can replace all occurrences of a type variable any type, concrete or variable. So for example, if you have
`f :: a -> m b`

, you can replace all occurrences of `a`

with `m b`

and get `f :: m b -> m b`

. Since this one can't be undone either, it's also a specialization.

That last example shows how `id`

can be used as the second argument of `>>=`

. So the answer to your question is that we can rewrite and derive types as follows:

```
1. (>>=) :: m a -> (a -> m b) -> m b (premise)
2. id :: a -> a (premise)
3. (>>=) :: m (m b) -> (m b -> m b) -> m b (replace a with m b in #1)
4. id :: m b -> m b (replace a with m b in #2)
.
.
.
n. (>>= id) :: m (m b) -> m b (indirectly from #3 and #4)
```

`a`

is`m b`

, as`id`

forces it to be ? This should answer your question. – Alexandre C. Apr 20 '12 at 21:01