streamly-0.7.3.1: Beautiful Streaming, Concurrent and Reactive Composition
Copyright(c) 2019 Composewell Technologies
LicenseBSD3
Maintainerstreamly@composewell.com
Stabilityexperimental
PortabilityGHC
Safe HaskellSafe-Inferred
LanguageHaskell2010

Streamly.Internal.Data.Stream.StreamDK.Type

Description

A CPS style stream using a constructor based representation instead of a function based representation.

Streamly internally uses two fundamental stream representations, (1) streams with an open or arbitrary control flow (we call it StreamK), (2) streams with a structured or closed loop control flow (we call it StreamD). The higher level stream types can use any of these representations under the hood and can interconvert between the two.

StreamD:

StreamD is a non-recursive data type in which the state of the stream and the step function are separate. When the step function is called, a stream element and the new stream state is yielded. The generated element and the state are passed to the next consumer in the loop. The state is threaded around in the loop until control returns back to the original step function to run the next step. This creates a structured closed loop representation (like "for" loops in C) with state of each step being hidden/abstracted or existential within that step. This creates a loop representation identical to the "for" or "while" loop constructs in imperative languages, the states of the steps combined together constitute the state of the loop iteration.

Internally most combinators use a closed loop representation because it provides very high efficiency due to stream fusion. The performance of this representation is competitive to the C language implementations.

Pros and Cons of StreamD:

1) stream-fusion: This representation can be optimized very efficiently by the compiler because the state is explicitly separated from step functions, represented using pure data constructors and visible to the compiler, the stream steps can be fused using case-of-case transformations and the state can be specialized using spec-constructor optimization, yielding a C like tight loop/state machine with no constructors, the state is used unboxed and therefore no unnecessary allocation.

2) Because of a closed representation consing too many elements in this type of stream does not scale, it will have quadratic performance slowdown. Each cons creates a layer that needs to return the control back to the caller. Another implementation of cons is possible but that will have to box/unbox the state and will not fuse. So effectively cons breaks fusion.

3) unconsing an item from the stream breaks fusion, we have to "pause" the loop, rebox and save the state.

3) Exception handling is easy to implement in this model because control flow is structured in the loop and cannot be arbitrary. Therefore, implementing "bracket" is natural.

4) Round-robin scheduling for co-operative multitasking is easy to implement.

5) It fuses well with the direct style Fold implementation.

StreamK/StreamDK:

StreamDK i.e. the stream defined in this module, like StreamK, is a recursive data type which has no explicit state defined using constructors, each step yields an element and a computation representing the rest of the stream. Stream state is part of the function representing the rest of the stream. This creates an open computation representation, or essentially a continuation passing style computation. After the stream step is executed, the caller is free to consume the produced element and then send the control wherever it wants, there is no restriction on the control to return back somewhere, the control is free to go anywhere. The caller may decide not to consume the rest of the stream. This representation is more like a "goto" based implementation in imperative languages.

Pros and Cons of StreamK:

1) The way StreamD can be optimized using stream-fusion, this type can be optimized using foldrbuild fusion. However, foldrbuild has not yet been fully implemented for StreamK/StreamDK.

2) Using cons is natural in this representation, unlike in StreamD it does not have a quadratic slowdown. Currently, we in fact wrap StreamD in StreamK to support a better cons operation.

3) Similarly, uncons is natural in this representation.

4) Exception handling is not easy to implement because of the "goto" nature of CPS.

5) Composable folds are not implemented/proven, however, intuition says that a push style CPS representation should be able to be used along with StreamK to efficiently implement composable folds.

Documentation

data Step m a Source #

Constructors

Yield a (Stream m a) 
Stop 

data Stream m a Source #

Constructors

Stream (m (Step m a))