Continuation passing style (CPS) stream implementation. The symbol `K`

below
denotes a function as well as a Kontinuation.

class (forall m a. MonadAsync m => Semigroup (t m a), forall m a. MonadAsync m => Monoid (t m a), forall m. Monad m => Functor (t m), forall m. MonadAsync m => Applicative (t m)) => IsStream t where Source #

Class of types that can represent a stream of elements of some type `a`

in
some monad `m`

.

*Since: 0.2.0 (Streamly)*

*Since: 0.8.0*

toStream :: t m a -> Stream m a Source #

fromStream :: Stream m a -> t m a Source #

consM :: MonadAsync m => m a -> t m a -> t m a infixr 5 Source #

Constructs a stream by adding a monadic action at the head of an existing stream. For example:

> toList $ getLine `consM` getLine `consM` nil hello world ["hello","world"]

*Concurrent (do not use fromParallel to construct infinite streams)*

*Since: 0.2.0*

(|:) :: MonadAsync m => m a -> t m a -> t m a infixr 5 Source #

Operator equivalent of `consM`

. We can read it as "`parallel colon`

"
to remember that `|`

comes before `:`

.

> toList $ getLine |: getLine |: nil hello world ["hello","world"]

let delay = threadDelay 1000000 >> print 1 drain $ fromSerial $ delay |: delay |: delay |: nil drain $ fromParallel $ delay |: delay |: delay |: nil

*Concurrent (do not use fromParallel to construct infinite streams)*

*Since: 0.2.0*

IsStream Stream Source # | |

Defined in Streamly.Internal.Data.Stream.StreamK.Type | |

IsStream ParallelT Source # | |

Defined in Streamly.Internal.Data.Stream.Parallel | |

IsStream WAsyncT Source # | |

Defined in Streamly.Internal.Data.Stream.Async | |

IsStream AsyncT Source # | |

Defined in Streamly.Internal.Data.Stream.Async | |

IsStream AheadT Source # | |

Defined in Streamly.Internal.Data.Stream.Ahead | |

IsStream ZipAsyncM Source # | |

Defined in Streamly.Internal.Data.Stream.Zip | |

IsStream ZipSerialM Source # | |

Defined in Streamly.Internal.Data.Stream.Zip toStream :: forall (m :: Type -> Type) a. ZipSerialM m a -> Stream m a Source # fromStream :: forall (m :: Type -> Type) a. Stream m a -> ZipSerialM m a Source # consM :: MonadAsync m => m a -> ZipSerialM m a -> ZipSerialM m a Source # (|:) :: MonadAsync m => m a -> ZipSerialM m a -> ZipSerialM m a Source # | |

IsStream WSerialT Source # | |

Defined in Streamly.Internal.Data.Stream.Serial | |

IsStream SerialT Source # | |

Defined in Streamly.Internal.Data.Stream.Serial |

adapt :: (IsStream t1, IsStream t2) => t1 m a -> t2 m a Source #

Adapt any specific stream type to any other specific stream type.

*Since: 0.1.0 (Streamly)*

*Since: 0.8.0*

The type `Stream m a`

represents a monadic stream of values of type `a`

constructed using actions in monad `m`

. It uses stop, singleton and yield
continuations equivalent to the following direct style type:

data Stream m a = Stop | Singleton a | Yield a (Stream m a)

To facilitate parallel composition we maintain a local state in an `SVar`

that is shared across and is used for synchronization of the streams being
composed.

The singleton case can be expressed in terms of stop and yield but we have
it as a separate case to optimize composition operations for streams with
single element. We build singleton streams in the implementation of `pure`

for Applicative and Monad, and in `lift`

for MonadTrans.

MonadTrans Stream Source # | |

Defined in Streamly.Internal.Data.Stream.StreamK.Type | |

IsStream Stream Source # | |

Defined in Streamly.Internal.Data.Stream.StreamK.Type | |

Monad m => Monad (Stream m) Source # | |

Monad m => Functor (Stream m) Source # | |

Monad m => Applicative (Stream m) Source # | |

Semigroup (Stream m a) Source # | |

Monoid (Stream m a) Source # | |

mkStream :: IsStream t => (forall r. State Stream m a -> (a -> t m a -> m r) -> (a -> m r) -> m r -> m r) -> t m a Source #

Build a stream from an `SVar`

, a stop continuation, a singleton stream
continuation and a yield continuation.

fromYieldK :: IsStream t => YieldK m a -> t m a Source #

Make a singleton stream from a callback function. The callback function calls the one-shot yield continuation to yield an element.

consK :: IsStream t => YieldK m a -> t m a -> t m a Source #

Add a yield function at the head of the stream.

foldStream :: IsStream t => State Stream m a -> (a -> t m a -> m r) -> (a -> m r) -> m r -> t m a -> m r Source #

Fold a stream by providing a State, stop continuation, a singleton continuation and a yield continuation. The stream will not use the SVar passed via State.

foldStreamShared :: IsStream t => State Stream m a -> (a -> t m a -> m r) -> (a -> m r) -> m r -> t m a -> m r Source #

Fold a stream by providing an SVar, a stop continuation, a singleton continuation and a yield continuation. The stream would share the current SVar passed via the State.

foldl' :: (IsStream t, Monad m) => (b -> a -> b) -> b -> t m a -> m b Source #

Strict left associative fold.

foldlx' :: forall t m a b x. (IsStream t, Monad m) => (x -> a -> x) -> x -> (x -> b) -> t m a -> m b Source #

Strict left fold with an extraction function. Like the standard strict
left fold, but applies a user supplied extraction function (the third
argument) to the folded value at the end. This is designed to work with the
`foldl`

library. The suffix `x`

is a mnemonic for extraction.

Note that the accumulator is always evaluated including the initial value.

foldrM :: IsStream t => (a -> m b -> m b) -> m b -> t m a -> m b Source #

Lazy right fold with a monadic step function.

foldrS :: IsStream t => (a -> t m b -> t m b) -> t m b -> t m a -> t m b Source #

Lazy right associative fold to a stream.

foldrSShared :: IsStream t => (a -> t m b -> t m b) -> t m b -> t m a -> t m b Source #

Fold sharing the SVar state within the reconstructed stream

buildM :: (IsStream t, MonadAsync m) => (forall r. (a -> t m a -> m r) -> (a -> m r) -> m r -> m r) -> t m a Source #

buildSM :: (IsStream t, MonadAsync m) => ((m a -> t m a -> t m a) -> t m a -> t m a) -> t m a Source #

sharedM :: (IsStream t, MonadAsync m) => (forall r. (a -> t m a -> m r) -> (a -> m r) -> m r -> m r) -> t m a Source #

Like `buildM`

but shares the SVar state across computations.

augmentSM :: (IsStream t, MonadAsync m) => ((m a -> t m a -> t m a) -> t m a -> t m a) -> t m a -> t m a Source #

cons :: IsStream t => a -> t m a -> t m a infixr 5 Source #

Construct a stream by adding a pure value at the head of an existing
stream. For serial streams this is the same as `(return a) `consM` r`

but
more efficient. For concurrent streams this is not concurrent whereas
`consM`

is concurrent. For example:

> toList $ 1 `cons` 2 `cons` 3 `cons` nil [1,2,3]

*Since: 0.1.0*

consMBy :: (IsStream t, MonadAsync m) => (t m a -> t m a -> t m a) -> m a -> t m a -> t m a Source #

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

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

An empty stream producing a side effect.

> toList (nilM (print "nil")) "nil" []

*Pre-release*

conjoin :: (IsStream t, MonadAsync m) => t m a -> t m a -> t m a Source #

serial :: IsStream t => t m a -> t m a -> t m a infixr 6 Source #

Appends two streams sequentially, yielding all elements from the first stream, and then all elements from the second stream.

`>>>`

`import Streamly.Prelude (serial)`

`>>>`

`stream1 = Stream.fromList [1,2]`

`>>>`

`stream2 = Stream.fromList [3,4]`

`>>>`

[1,2,3,4]`Stream.toList $ stream1 `serial` stream2`

This operation can be used to fold an infinite lazy container of streams.

*Since: 0.2.0 (Streamly)*

*Since: 0.8.0*

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

mapMSerial :: MonadAsync m => (a -> m b) -> Stream m a -> Stream m b Source #

concatMapBy :: IsStream t => (t m b -> t m b -> t m b) -> (a -> t m b) -> t m a -> t m b Source #

concatPairsWith :: IsStream t => (t m b -> t m b -> t m b) -> (a -> t m b) -> t m a -> t m b Source #

See `concatPairsWith`

for
documentation.

apSerialDiscardFst :: IsStream t => t m a -> t m b -> t m b Source #

apSerialDiscardSnd :: IsStream t => t m a -> t m b -> t m a Source #

streamly-0.8.0**Streamly.Internal.Data.Stream.StreamK.Type**