-- |
-- Module      : Streamly.StreamDK.Type
-- Copyright   : (c) 2019 Composewell Technologies
-- License     : BSD3
-- Maintainer  : streamly@composewell.com
-- Stability   : experimental
-- Portability : GHC
--
-- 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 foldr/build fusion. However, foldr/build 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.

module Streamly.Internal.Data.Stream.StreamDK.Type
    ( Step(..)
    , Stream (..)
    )
where

-- XXX Use Cons and Nil instead of Yield and Stop?
data Step m a = Yield a (Stream m a) | Stop

newtype Stream m a = Stream (m (Step m a))