explicit-exception-0.1.9: Exceptions which are explicit in the type signature.

Safe HaskellSafe
LanguageHaskell98

Control.Monad.Exception.Asynchronous.Lazy

Synopsis

Documentation

data Exceptional e a Source #

Contains a value and a reason why the computation of the value of type a was terminated. Imagine a as a list type, and an according operation like the readFile operation. If the exception part is Nothing then the value could be constructed regularly. If the exception part is Just then the value could not be constructed completely. However you can read the result of type a lazily, even if an exception occurs while it is evaluated. If you evaluate the exception part, then the result value is certainly computed completely.

However, we cannot provide general Monad functionality due to the very different ways of combining the results of type a. It is recommended to process the result value in an application specific way, and after consumption of the result, throw a synchronous exception using toSynchronous.

Maybe in the future we provide a monad instance which considers subsequent actions as simultaneous processes on a lazy data structure.

This variant has lazy combinators like fmap. This implies that some laws are not fulfilled, but in practice it saves you some calls to force.

Constructors

Exceptional 

Fields

Instances

Functor (Exceptional e) Source #

fmap (f.g) = fmap f . fmap g

The law fmap id = id requires that we match the constructor strictly.

Strict matching fmap id undefined = undefined = id undefined

Lazy matching fmap id undefined = Exceptional undefined undefined /= undefined = id undefined

Methods

fmap :: (a -> b) -> Exceptional e a -> Exceptional e b #

(<$) :: a -> Exceptional e b -> Exceptional e a #

(Show a, Show e) => Show (Exceptional e a) Source # 

Methods

showsPrec :: Int -> Exceptional e a -> ShowS #

show :: Exceptional e a -> String #

showList :: [Exceptional e a] -> ShowS #

Monoid a => Monoid (Exceptional e a) Source #

mappend must be strict in order to fulfill the Monoid laws mappend mempty a = a and mappend a mempty = a for a=undefined.

Methods

mempty :: Exceptional e a #

mappend :: Exceptional e a -> Exceptional e a -> Exceptional e a #

mconcat :: [Exceptional e a] -> Exceptional e a #

(NFData e, NFData a) => NFData (Exceptional e a) Source # 

Methods

rnf :: Exceptional e a -> () #

pure :: a -> Exceptional e a Source #

Create an exceptional value without exception.

broken :: e -> a -> Exceptional e a Source #

Create an exceptional value with exception.

throw :: e -> Exceptional e () Source #

I think in most cases we want throwMonoid, thus we can replace throw by throwMonoid.

eatNothing :: Exceptional (Maybe e) a -> Exceptional e a Source #

You might use an exception of type Maybe e in manyMonoidT in order to stop the loop. After finishing the loop you will want to turn the Nothing exception into a success. This is achieved by this function.

zipWith :: (a -> b -> c) -> Exceptional e [a] -> Exceptional e [b] -> Exceptional e [c] Source #

This is an example for application specific handling of result values. Assume you obtain two lazy lists say from readFile and you want to zip their contents. If one of the stream readers emits an exception, we quit with that exception. If both streams have throw an exception at the same file position, the exception of the first stream is propagated.

append :: Monoid a => Exceptional e a -> Exceptional e a -> Exceptional e a infixr 1 Source #

This is an example for application specific handling of result values. Assume you obtain two lazy lists say from readFile and you want to append their contents. If the first stream ends with an exception, this exception is kept and the second stream is not touched. If the first stream can be read successfully, the second one is appended until stops.

append is less strict than the Monoid method mappend instance.

continue :: Monoid a => Maybe e -> Exceptional e a -> Exceptional e a infixr 1 Source #

maybeAbort :: Exceptional e a -> Maybe e -> Exceptional e a infixr 1 Source #

force :: Exceptional e a -> Exceptional e a Source #

construct Exceptional constructor lazily

mapException :: (e0 -> e1) -> Exceptional e0 a -> Exceptional e1 a Source #

mapExceptional :: (e0 -> e1) -> (a -> b) -> Exceptional e0 a -> Exceptional e1 b Source #

simultaneousBind :: Exceptional e a -> (a -> Exceptional e b) -> Exceptional e b infixr 1 Source #

Deprecated: Check whether this function is really what you need. It generates an unreasonable exception when the second exception is caused by the first one.

I consider both actions to process the data simultaneously through lazy evaluation. If the second one fails too, it must have encountered an exception in the data that was successfully emitted by the first action, and thus the exception of the second action is probably earlier.

We cannot check in general whether the two exception occur at the same time, e.g. the second one might occur since the first occured and left an invalid structure. In this case we should emit the first exception, not the second one. Because of this I expect that this function is not particularly useful. Otherwise it could be used as bind operation for a monad instance.

simultaneousBindM :: Monad m => m (Exceptional e a) -> (a -> m (Exceptional e b)) -> m (Exceptional e b) infixr 1 Source #

Deprecated: Check whether this function is really what you need. It generates an unreasonable exception when the second exception is caused by the first one.

sequenceF :: Functor f => Exceptional e (f a) -> f (Exceptional e a) Source #

Is there a better name?

traverse :: Applicative f => (a -> f b) -> Exceptional e a -> f (Exceptional e b) Source #

Foldable instance would allow to strip off the exception too easily.

I like the methods of Traversable, but Traversable instance requires Foldable instance.

mapM :: Monad m => (a -> m b) -> Exceptional e a -> m (Exceptional e b) Source #

sequence :: Monad m => Exceptional e (m a) -> m (Exceptional e a) Source #

swapToSynchronousAsynchronous :: Exceptional e0 (Exceptional e1 a) -> Exceptional e1 (Exceptional e0 a) Source #

Consider a file format consisting of a header and a data body. The header can only be used if is read completely. Its parsing might stop with an synchronous exception. The data body can also be used if it is truncated by an exceptional event. This is expressed by an asynchronous exception. A loader for this file format can thus fail by a synchronous and an asynchronous exception. Surprisingly, both orders of nesting these two kinds of exceptional actions are equally expressive. This function converts to the form where the synchronous exception is the outer one.

This is a specialisation of sequence and friends.

newtype ExceptionalT e m a Source #

In contrast to synchronous exceptions, the asynchronous monad transformer is not quite a monad. You must use the Monoid interface or bindT instead.

Constructors

ExceptionalT 

Fields

Instances

Functor m => Functor (ExceptionalT e m) Source # 

Methods

fmap :: (a -> b) -> ExceptionalT e m a -> ExceptionalT e m b #

(<$) :: a -> ExceptionalT e m b -> ExceptionalT e m a #

(Monad m, Monoid a) => Monoid (ExceptionalT e m a) Source # 

Methods

mempty :: ExceptionalT e m a #

mappend :: ExceptionalT e m a -> ExceptionalT e m a -> ExceptionalT e m a #

mconcat :: [ExceptionalT e m a] -> ExceptionalT e m a #

forceT :: Monad m => ExceptionalT e m a -> ExceptionalT e m a Source #

see force

mapExceptionT :: Monad m => (e0 -> e1) -> ExceptionalT e0 m a -> ExceptionalT e1 m a Source #

mapExceptionalT :: (m (Exceptional e0 a) -> n (Exceptional e1 b)) -> ExceptionalT e0 m a -> ExceptionalT e1 n b Source #

throwMonoidT :: (Monad m, Monoid a) => e -> ExceptionalT e m a Source #

bindT :: (Monad m, Monoid b) => ExceptionalT e m a -> (a -> ExceptionalT e m b) -> ExceptionalT e m b infixl 1 Source #

The monadic bind operation. It cannot be made an instance of the Monad class method (>>=) since it requires a default return value in case the first action fails. We get this default value by the Monoid method mempty.

manySynchronousT Source #

Arguments

:: Monad m 
=> (m (Exceptional e b) -> m (Exceptional e b))

defer function

-> (a -> b -> b)

cons function

-> b
empty
-> ExceptionalT e m a

atomic action to repeat

-> m (Exceptional e b) 

Deprecated: use manyMonoidT with appropriate Monad like LazyIO and result Monoid like Endo instead

Repeat an action with synchronous exceptions until an exception occurs. Combine all atomic results using the bind function. It may be cons = (:) and empty = [] for b being a list type. The defer function may be id or unsafeInterleaveIO for lazy read operations. The exception is returned as asynchronous exception.

manyMonoidT Source #

Arguments

:: (Monad m, Monoid a) 
=> ExceptionalT e m a

atomic action to repeat

-> ExceptionalT e m a 

We advise to use the Endo Monoid when you want to read a series of characters into a list. This means you use the difference lists technique in order to build the list, which is efficient.

import Data.Monoid (Endo, appEndo, )
import Control.Exception (try, )
import qualified Control.Monad.Exception.Synchronous as Sync
fmap (flip appEndo []) $ manyMonoidT (fromSynchronousMonoidT $ fmap (Endo . (:)) $ Sync.fromEitherT $ try getChar)

If you want Lazy IO you must additionally convert getChar to LazyIO monad.

processToSynchronousT_ Source #

Arguments

:: Monad m 
=> (b -> Maybe (a, b))

decons function

-> (a -> ExceptionalT e m ())

action that is run for each element fetched from x

-> Exceptional e b

value x of type b with asynchronous exception

-> ExceptionalT e m () 

Scan x using the decons function and run an action with synchronous exceptions for each element fetched from x. Each invocation of an element action may stop this function due to an exception. If all element actions can be performed successfully and if there is an asynchronous exception then at the end this exception is raised as synchronous exception. decons function might be Data.List.HT.viewL.

appendM :: (Monad m, Monoid a) => m (Exceptional e a) -> m (Exceptional e a) -> m (Exceptional e a) infixr 1 Source #

continueM :: (Monad m, Monoid a) => m (Maybe e) -> m (Exceptional e a) -> m (Exceptional e a) infixr 1 Source #