Copyright | (c) 2021 Xy Ren |
---|---|
License | BSD3 |
Maintainer | xy.r@outlook.com |
Stability | unstable |
Portability | non-portable (GHC only) |
Safe Haskell | None |
Language | Haskell2010 |
This module contains the IOE
effect together with a few primitives for using it, as well as interpretation
combinators for IO
-related effects. It is not usually needed because safe functionalities are re-exported in the
Cleff module.
This is an internal module and its API may change even between minor versions. Therefore you should be extra careful if you're to depend on this module.
Synopsis
- data IOE :: Effect
- primLiftIO :: IO a -> Eff es a
- primUnliftIO :: ((Eff es ~> IO) -> IO a) -> Eff es a
- thisIsPureTrustMe :: Eff (IOE ': es) ~> Eff es
- runIOE :: Eff '[IOE] ~> IO
- runPure :: Eff '[] a -> a
- type HandlerIO e es = forall esSend. Handling esSend e es => e (Eff esSend) ~> IO
- interpretIO :: IOE :> es => HandlerIO e es -> Eff (e ': es) ~> Eff es
- withToIO :: (Handling esSend e es, IOE :> es) => ((Eff esSend ~> IO) -> IO a) -> Eff es a
- fromIO :: (Handling esSend e es, IOE :> es) => IO ~> Eff esSend
The IOE
Effect
The effect capable of lifting and unlifting the IO
monad, allowing you to use MonadIO
, MonadUnliftIO
,
PrimMonad
, MonadCatch
, MonadThrow
and MonadMask
functionalities. This is the "final" effect that most
effects eventually are interpreted into. For example, you can do:
log ::IOE
:> es =>Eff
es () log =liftIO
(putStrLn
"Test logging")
It is not recommended to use this effect directly in application code, as it is too liberal and allows arbitrary IO, therefore making it harder to do proper effect management. Ideally, this is only used in interpreting more fine-grained effects.
Technical details
Note that this is not a real effect and cannot be interpreted in any way besides thisIsPureTrustMe
and
runIOE
. This is mainly for performance concern, but also that there doesn't really exist reasonable
interpretations other than the current one, given the underlying implementation of the Eff
monad.
IOE
can be a real effect though, and you can enable the dynamic-ioe
build flag to have that. However it is only
for reference purposes and should not be used in production code.
Primitive IO
functions
primLiftIO :: IO a -> Eff es a Source #
primUnliftIO :: ((Eff es ~> IO) -> IO a) -> Eff es a Source #
Give a runner function a way to run Eff
actions as an IO
computation. This function is highly unsafe and
should not be used directly; use withRunInIO
instead, or if you're interpreting higher-order effects, use
withToIO
.
Unwrapping Eff
thisIsPureTrustMe :: Eff (IOE ': es) ~> Eff es Source #
Unsafely eliminate an IOE
effect from the top of the effect stack. This is mainly for implementing effects that
uses IO
but does not do anything really impure (i.e. can be safely used unsafeDupablePerformIO
on), such as a
State effect.
runPure :: Eff '[] a -> a Source #
Unwrap a pure Eff
computation into a pure value, given that all effects are interpreted.
Effect interpretation
type HandlerIO e es = forall esSend. Handling esSend e es => e (Eff esSend) ~> IO Source #
The type of an IO
effect handler, which is a function that transforms an effect e
into IO
computations.
This is used for interpretIO
.
Combinators for interpreting higher-order effects
withToIO :: (Handling esSend e es, IOE :> es) => ((Eff esSend ~> IO) -> IO a) -> Eff es a Source #
Temporarily gain the ability to unlift an
computation into Eff
esSendIO
. This is analogous to
withRunInIO
, and is useful in dealing with higher-order effects that involves IO
. For example, the Resource
effect that supports brecketing:
data Resource m a where Bracket :: m a -> (a -> m ()) -> (a -> m b) -> Resource m b
can be interpreted into bracket
actions in IO
, by converting all effect computations into
IO
compucations via withToIO
:
runResource ::IOE
:>
es =>Eff
(Resource ': es) a ->Eff
es a runResource =interpret
\case Bracket alloc dealloc use ->withToIO
$ \toIO ->bracket
(toIO alloc) (toIO . dealloc) (toIO . use)
fromIO :: (Handling esSend e es, IOE :> es) => IO ~> Eff esSend Source #
Lift an IO
computation into
. This is analogous to Eff
esSendliftIO
, and is only useful in dealing with
effect operations with the monad type in the negative position, for example mask
ing:
data Mask ::Effect
where Mask :: ((m~>
m) -> m a) -> Mask m a ^ this "m" is in negative position
See how the restore :: IO a -> IO a
from mask
is "wrapped" into
:Eff
esSend a -> Eff
esSend a
runMask ::IOE
:>
es =>Eff
(Mask ': es) a ->Eff
es a runMask =interpret
\case Mask f ->withToIO
$ \toIO ->mask
$ \restore -> f (fromIO
. restore . toIO)
Here, toIO
from withToIO
takes an
to Eff
esSendIO
, where it can be passed into the restore
function,
and the returned IO
computation is recovered into Eff
with fromIO
.
Orphan instances
IOE :> es => MonadBase IO (Eff es) Source # | Compatibility instance; use |
IOE :> es => MonadBaseControl IO (Eff es) Source # | Compatibility instance; use |
IOE :> es => MonadIO (Eff es) Source # | |
IOE :> es => MonadThrow (Eff es) Source # | |
IOE :> es => MonadCatch (Eff es) Source # | |
IOE :> es => MonadMask (Eff es) Source # | |
IOE :> es => PrimMonad (Eff es) Source # | |
IOE :> es => MonadUnliftIO (Eff es) Source # | |