t m to have a monad instance for this to work.
co :: Monad m => m a -> m a -> m a
co = undefined
co' :: (MonadTrans t, Monad m, Monad (t m)) => t m a -> m a -> t m a
co' one two = lift . flip co two . return =<< one
Alternative view on the problem
Seeing the definition of
transformers package should help you find the answer as you want something similar
lift . return = return
lift (m >>= f) = lift m >>= (lift . f)
As you have
flip co one :: Monad m => m a -> m a and you want to lift it to get a function of type
(MonadTrans t, Monad m, Monad (t m)) => t m a -> t m a. So following on the footsteps of lift
lift' :: (MonadTrans t, Monad m, Monad (t m)) => (m a -> m a) -> t m a -> t m a
lift' f tma = tma >>= (lift . f . return)
co' is trivial
co' one two = lift' (flip co two) one
The above solutions just satisfy the type, but do they satisfy the semantics too?
To see the problem lets take a
co function which always returns the second action without even looking at the first. Now the above
co' will never be able to do that as it always runs the first action before deciding anything. So the side effect of first action will still occur in the
co' even though they dont occur in
Does the general solution exist?
I suppose not. Because what you want to actually implement that function generically, is a function like
t m a -> (m a -> m b) -> t m b, where you need to get action
m a out of
t m a without actually running the side effects of
IO monad and
t is State transformer with some state and your
one action actually launches a missile and depending on the success or failure of that modifies the
State. Now what you want is to actually modify the state without launching the missiles. In general that is not possible.
If you know some information about
co like which action is run first, then you can implement
co' using the above method.