I've looked over https://www.fpcomplete.com/blog/2017/06/tale-of-two-brackets, though skimming some parts, and I still don't quite understand the core issue "
StateT is bad,
IO is OK", other than vaguely getting the sense that Haskell allows one to write bad
StateT monads (or in the ultimate example in the article,
MonadBaseControl instead of
StateT, I think).
In the haddocks, the following law must be satisfied:
askUnliftIO >>= (\u -> liftIO (unliftIO u m)) = m
So this appears to be saying that state is not mutated in the monad
m when using
askUnliftIO. But to my mind, in
IO, the entire world can be the state. I could be reading and writing to a text file on disk, for instance.
To quote another article by Michael,
False purity We say WriterT and StateT are pure, and technically they are. But let's be honest: if you have an application which is entirely living within a StateT, you're not getting the benefits of restrained mutation that you want from pure code. May as well call a spade a spade, and accept that you have a mutable variable.
This makes me think this is indeed the case: with IO we are being honest, with
StateT, we are not being honest about mutability ... but that seems another issue than what the law above is trying to show; after all,
MonadUnliftIO is assuming
IO. I'm having trouble understanding conceptually how
IO is more restrictive than something else.
After sleeping (some), I am still confused but am gradually getting less so as the day wears on. I worked out the law proof for
IO. I realized the presence of
id in the README. In particular,
instance MonadUnliftIO IO where askUnliftIO = return (UnliftIO id)
askUnliftIO would appear to return an
IO (IO a) on an
Prelude> fooIO = print 5 Prelude> :t fooIO fooIO :: IO () Prelude> let barIO :: IO(IO ()); barIO = return fooIO Prelude> :t barIO barIO :: IO (IO ())
Back to the law, it really appears to be saying that state is not mutated in the monad
m when doing a round trip on the transformed monad (
askUnliftIO), where the round trip is
Resuming the example above,
barIO :: IO (), so if we do
barIO >>= (u -> liftIO (unliftIO u m)), then
u :: IO () and
unliftIO u == IO (), then
liftIO (IO ()) == IO (). **So since everything has basically been applications of
id under the hood, we can see that no state was changed, even though we are using
IO. Crucially, I think, what is important is that the value in
a is never run, nor is any other state modified, as a result of using
askUnliftIO. If it did, then like in the case of
randomIO :: IO a, we would not be able to get the same value had we not run
askUnliftIO on it. (Verification attempt 1 below)
But, it still seems like we could do the same for other Monads, even if they do maintain state. But I also see how, for some monads, we may not be able to do so. Thinking of a contrived example: each time we access the value of type
a contained in the stateful monad, some internal state is changed.
Verification attempt 1
> fooIO >> askUnliftIO 5 > fooIOunlift = fooIO >> askUnliftIO > :t fooIOunlift fooIOunlift :: IO (UnliftIO IO) > fooIOunlift 5
Good so far, but confused about why the following occurs:
> fooIOunlift >>= (\u -> unliftIO u) <interactive>:50:24: error: * Couldn't match expected type `IO b' with actual type `IO a0 -> IO a0' * Probable cause: `unliftIO' is applied to too few arguments In the expression: unliftIO u In the second argument of `(>>=)', namely `(\ u -> unliftIO u)' In the expression: fooIOunlift >>= (\ u -> unliftIO u) * Relevant bindings include it :: IO b (bound at <interactive>:50:1)