streamly-0.8.3: Dataflow programming and declarative concurrency
Copyright(c) 2019 Composewell Technologies
LicenseBSD-3-Clause
Maintainerstreamly@composewell.com
Stabilityexperimental
PortabilityGHC
Safe HaskellSafe-Inferred
LanguageHaskell2010

Streamly.Internal.Data.Stream.IsStream.Exception

Description

 
Synopsis

Documentation

before :: (IsStream t, Monad m) => m b -> t m a -> t m a Source #

Run the action m b before the stream yields its first element.

Same as the following but more efficient due to fusion:

>>> before action xs = Stream.nilM action <> xs
>>> before action xs = Stream.concatMap (const xs) (Stream.fromEffect action)

Since: 0.7.0

after_ :: (IsStream t, Monad m) => m b -> t m a -> t m a Source #

Like after, with following differences:

  • action m b won't run if the stream is garbage collected after partial evaluation.
  • Monad m does not require any other constraints.
  • has slightly better performance than after.

Same as the following, but with stream fusion:

after_ action xs = xs <> 'nilM' action

Pre-release

after :: (IsStream t, MonadRunInIO m) => m b -> t m a -> t m a Source #

Run the action m b whenever the stream t m a stops normally, or if it is garbage collected after a partial lazy evaluation.

The semantics of the action m b are similar to the semantics of cleanup action in bracket.

See also after_

Since: 0.7.0

bracket_ :: (IsStream t, MonadCatch m) => m b -> (b -> m c) -> (b -> t m a) -> t m a Source #

Like bracket but with following differences:

  • alloc action m b runs with async exceptions enabled
  • cleanup action b -> m c won't run if the stream is garbage collected after partial evaluation.
  • does not require a MonadAsync constraint.
  • has slightly better performance than bracket.

Inhibits stream fusion

Pre-release

bracket :: (IsStream t, MonadAsync m, MonadCatch m) => m b -> (b -> m c) -> (b -> t m a) -> t m a Source #

Run the alloc action m b with async exceptions disabled but keeping blocking operations interruptible (see mask). Use the output b as input to b -> t m a to generate an output stream.

b is usually a resource under the state of monad m, e.g. a file handle, that requires a cleanup after use. The cleanup action b -> m c, runs whenever the stream ends normally, due to a sync or async exception or if it gets garbage collected after a partial lazy evaluation.

bracket only guarantees that the cleanup action runs, and it runs with async exceptions enabled. The action must ensure that it can successfully cleanup the resource in the face of sync or async exceptions.

When the stream ends normally or on a sync exception, cleanup action runs immediately in the current thread context, whereas in other cases it runs in the GC context, therefore, cleanup may be delayed until the GC gets to run.

See also: bracket_

Inhibits stream fusion

Since: 0.7.0

bracket' :: (IsStream t, MonadAsync m, MonadCatch m) => m b -> (b -> m c) -> (b -> m d) -> (b -> m e) -> (b -> t m a) -> t m a Source #

Like bracket but can use separate cleanup actions depending on the mode of termination. bracket' before onStop onGC onException action runs action using the result of before. If the stream stops, onStop action is executed, if the stream is abandoned onGC is executed, if the stream encounters an exception onException is executed.

Pre-release

onException :: (IsStream t, MonadCatch m) => m b -> t m a -> t m a Source #

Run the action m b if the stream aborts due to an exception. The exception is not caught, simply rethrown.

Inhibits stream fusion

Since: 0.7.0

finally_ :: (IsStream t, MonadCatch m) => m b -> t m a -> t m a Source #

Like finally with following differences:

  • action m b won't run if the stream is garbage collected after partial evaluation.
  • does not require a MonadAsync constraint.
  • has slightly better performance than finally.

Inhibits stream fusion

Pre-release

finally :: (IsStream t, MonadAsync m, MonadCatch m) => m b -> t m a -> t m a Source #

Run the action m b whenever the stream t m a stops normally, aborts due to an exception or if it is garbage collected after a partial lazy evaluation.

The semantics of running the action m b are similar to the cleanup action semantics described in bracket.

finally release = bracket (return ()) (const release)

See also finally_

Inhibits stream fusion

Since: 0.7.0

ghandle :: (IsStream t, MonadCatch m, Exception e) => (e -> t m a -> t m a) -> t m a -> t m a Source #

Like handle but the exception handler is also provided with the stream that generated the exception as input. The exception handler can thus re-evaluate the stream to retry the action that failed. The exception handler can again call ghandle on it to retry the action multiple times.

This is highly experimental. In a stream of actions we can map the stream with a retry combinator to retry each action on failure.

Inhibits stream fusion

Pre-release

handle :: (IsStream t, MonadCatch m, Exception e) => (e -> t m a) -> t m a -> t m a Source #

When evaluating a stream if an exception occurs, stream evaluation aborts and the specified exception handler is run with the exception as argument.

Inhibits stream fusion

Since: 0.7.0

retry Source #

Arguments

:: (IsStream t, MonadCatch m, Exception e, Ord e) 
=> Map e Int

map from exception to retry count

-> (e -> t m a)

default handler for those exceptions that are not in the map

-> t m a 
-> t m a 

retry takes 3 arguments

  1. A map m whose keys are exceptions and values are the number of times to retry the action given that the exception occurs.
  2. A handler han that decides how to handle an exception when the exception cannot be retried.
  3. The stream itself that we want to run this mechanism on.

When evaluating a stream if an exception occurs,

  1. The stream evaluation aborts
  2. The exception is looked up in m

a. If the exception exists and the mapped value is > 0 then,

i. The value is decreased by 1.

ii. The stream is resumed from where the exception was called, retrying the action.

b. If the exception exists and the mapped value is == 0 then the stream evaluation stops.

c. If the exception does not exist then we handle the exception using han.

Internal