# Streamly [![Hackage](https://img.shields.io/hackage/v/streamly.svg?style=flat)](https://hackage.haskell.org/package/streamly) [![Gitter chat](https://badges.gitter.im/composewell/gitter.svg)](https://gitter.im/composewell/streamly) [![Build Status](https://travis-ci.org/composewell/streamly.svg?branch=master)](https://travis-ci.org/composewell/streamly) [![Windows Build status](https://ci.appveyor.com/api/projects/status/ajxg0c79raou9ned?svg=true)](https://ci.appveyor.com/project/harendra-kumar/streamly) [![Coverage Status](https://coveralls.io/repos/composewell/streamly/badge.svg?branch=master&service=github)](https://coveralls.io/github/composewell/streamly?branch=master) ## Stream`ing` `Concurrent`ly Streamly, short for streaming concurrently, is a simple yet powerful streaming library with concurrent merging and concurrent nested looping support. A stream is just like a list except that it is a list of monadic actions rather than pure values. Streamly streams can be generated, consumed, combined, or transformed serially or concurrently. We can loop over a stream serially or concurrently. We can also have serial or concurrent nesting of loops. For those familiar with the list transformer concept streamly is a concurrent list transformer. Streamly uses standard composition abstractions. Concurrent composition is just the same as serial composition except that we use a simple combinator to request a concurrent composition instead of serial. The programmer does not have to be aware of threads, locking or synchronization to write scalable concurrent programs. Streamly provides functionality that is equivalent to streaming libraries like [pipes](https://hackage.haskell.org/package/pipes) and [conduit](https://hackage.haskell.org/package/conduit) but with a list like API. The streaming API of streamly is close to the monadic streams API of the [vector](https://hackage.haskell.org/package/vector) package and similar in concept to the [streaming](https://hackage.haskell.org/package/streaming) package. In addition to streaming, streamly subsumes the functionality of list transformer libraries like `pipes` or [list-t](https://hackage.haskell.org/package/list-t) and also the logic programming library [logict](https://hackage.haskell.org/package/logict). On the concurrency side, it subsumes the functionality of the [async](https://hackage.haskell.org/package/async) package. Because it streams and supports concurrency we can write FRP applications similar in concept to [Yampa](https://hackage.haskell.org/package/Yampa) or [reflex](https://hackage.haskell.org/package/reflex). Why use streamly? * Simple list like streaming API, if you know how to use lists then you know how to use streamly. * Powerful yet simple and scalable concurrency. There is no other package that provides such high level and flexible concurrency support. * Unifies the functionality of many other disparate packages in a single concise and simple API. * Best in class performance. See [streaming-benchmarks](https://github.com/composewell/streaming-benchmarks) for a comparison of popular streaming libraries on micro-benchmarks. For more information: * [Streamly.Tutorial](https://hackage.haskell.org/package/streamly-0.1.2/docs/Streamly-Tutorial.html) module in the haddock documentation for a detailed introduction * [examples](https://github.com/composewell/streamly/tree/master/examples) directory in the package for some simple practical examples ## Streaming Pipelines Unlike `pipes` or `conduit` and like `vector` and `streaming` `streamly` composes stream data instead of stream processors (functions). A stream is just like a list and is explicitly passed around to functions that process the stream. Therefore, no special operator is needed to join stages in a streaming pipeline, just a forward (`$`) or reverse (`&`) function application operator is enough. Combinators are provided in `Streamly.Prelude` to transform or fold streams. ```haskell import Streamly import qualified Streamly.Prelude as S import Data.Function ((&)) main = runStream $ S.repeatM getLine & fmap read & S.filter even & S.takeWhile (<= 9) & fmap (\x -> x * x) & S.mapM print ``` ## Serial and Concurrent Merging Semigroup and Monoid instances can be used to fold streams serially or concurrently. In the following example we are composing ten actions in the stream each with a delay of 1 to 10 seconds. Since all the actions are concurrent we see one output printed every second: ``` haskell import Streamly import qualified Streamly.Prelude as S import Control.Concurrent (threadDelay) main = S.toList $ parallely $ foldMap delay [1..10] where delay n = S.once $ threadDelay (n * 1000000) >> print n ``` Streams can be combined together in many ways (see the tutorial for more ways): ``` haskell import Streamly import qualified Streamly.Prelude as S import Control.Concurrent delay n = S.once $ do threadDelay (n * 1000000) tid <- myThreadId putStrLn (show tid ++ ": Delay " ++ show n) ``` ### Serial ```haskell main = runStream $ delay 3 <> delay 2 <> delay 1 ``` ``` ThreadId 36: Delay 3 ThreadId 36: Delay 2 ThreadId 36: Delay 1 ``` ### Parallel ```haskell main = runStream . parallely $ delay 3 <> delay 2 <> delay 1 ``` ``` ThreadId 42: Delay 1 ThreadId 41: Delay 2 ThreadId 40: Delay 3 ``` ## Nested Loops (aka List Transformer) The monad instance composes like a list monad. ``` haskell import Streamly import qualified Streamly.Prelude as S loops = do x <- S.fromFoldable [1,2] y <- S.fromFoldable [3,4] S.once $ putStrLn $ show (x, y) main = runStream loops ``` ``` (1,3) (1,4) (2,3) (2,4) ``` ## Concurrent Nested Loops To run the above code with demand-driven concurrency i.e. each iteration in the loops can run concurrently depending on the consumer rate: ``` haskell main = runStream $ coparallely $ loops ``` To run it with round-robin parallelism: ``` haskell main = runStream $ parallely $ loops ``` To run it serially but interleaving the outer and inner loop iterations: ``` haskell main = runStream $ costreamly $ loops ``` ## Magical Concurrency Streams can perform semigroup (<>) and monadic bind (>>=) operations concurrently using combinators like `coparallelly`, `parallelly`. For example, to concurrently generate squares of a stream of numbers and then concurrently sum the square roots of all combinations of two streams: ``` haskell import Streamly import qualified Streamly.Prelude as S main = do s <- S.sum $ coparallely $ do -- Each square is performed concurrently, (<>) is concurrent x2 <- foldMap (\x -> return $ x * x) [1..100] y2 <- foldMap (\y -> return $ x * x) [1..100] -- Each addition is performed concurrently, monadic bind is concurrent return $ sqrt (x2 + y2) print s ``` Of course, the actions running in parallel could be arbitrary IO actions. For example, to concurrently list the contents of a directory tree recursively: ``` haskell import Path.IO (listDir, getCurrentDir) import Streamly main = runStream $ coparallely $ getCurrentDir >>= readdir where readdir d = do (dirs, files) <- S.once $ listDir d S.once $ mapM_ putStrLn $ map show files -- read the subdirs concurrently, (<>) is concurrent foldMap readdir dirs ``` In the above examples we do not think in terms of threads, locking or synchronization, rather we think in terms of what can run in parallel, the rest is taken care of automatically. When using `coparallely` the programmer does not have to worry about how many threads are to be created they are automatically adjusted based on the demand of the consumer. The concurrency facilities provided by streamly can be compared with [OpenMP](https://en.wikipedia.org/wiki/OpenMP) and [Cilk](https://en.wikipedia.org/wiki/Cilk) but with a more declarative expression. ## Reactive Programming (FRP) Streamly is a foundation for first class reactive programming as well by virtue of integrating concurrency and streaming. See [AcidRain.hs](https://github.com/composewell/streamly/tree/master/examples/AcidRain.hs) for a console based FRP game example and [CirclingSquare.hs](https://github.com/composewell/streamly/tree/master/examples/CirclingSquare.hs) for an SDL based animation example. ## Performance `Streamly` has best in class performance even though it generalizes streaming to concurrent composition that does not mean it sacrifices non-concurrent performance. See [streaming-benchmarks](https://github.com/composewell/streaming-benchmarks) for detailed performance comparison with regular streaming libraries and the explanation of the benchmarks. The following graphs show a summary, the first one measures how four pipeline stages in a series perform, the second one measures the performance of individual stream operations; in both cases the stream processes a million elements: ![Composing Pipeline Stages](charts/comparative/ComposingPipelineStages.svg) ![All Operations at a Glance](charts/comparative/AllOperationsataGlance.svg) ## Contributing The code is available under BSD-3 license [on github](https://github.com/composewell/streamly). Join the [gitter chat](https://gitter.im/composewell/streamly) channel for discussions. You can find some of the [todo items on the github wiki](https://github.com/composewell/streamly/wiki/Things-To-Do). Please ask on the gitter channel or [contact the maintainer directly](mailto:harendra.kumar@gmail.com) for more details on each item. All contributions are welcome! This library was originally inspired by the `transient` package authored by Alberto G. Corona.