{-# LANGUAGE CPP #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE FlexibleContexts #-} #if __GLASGOW_HASKELL__ >= 800 {-# OPTIONS_GHC -Wno-orphans #-} #endif #include "Streams/inline.hs" -- | -- Module : Streamly.Prelude -- Copyright : (c) 2017 Harendra Kumar -- -- License : BSD3 -- Maintainer : streamly@composewell.com -- Stability : experimental -- Portability : GHC -- -- This module is designed to be imported qualified: -- -- @ -- import qualified Streamly.Prelude as S -- @ -- -- Functions with the suffix @M@ are general functions that work on monadic -- arguments. The corresponding functions without the suffix @M@ work on pure -- arguments and can in general be derived from their monadic versions but are -- provided for convenience and for consistency with other pure APIs in the -- @base@ package. -- -- In many cases, short definitions of the combinators are provided in the -- documentation for illustration. The actual implementation may differ for -- performance reasons. -- -- Functions having a 'MonadAsync' constraint work concurrently when used with -- appropriate stream type combinator. Please be careful to not use 'parallely' -- with infinite streams. -- -- Deconstruction and folds accept a 'SerialT' type instead of a polymorphic -- type to ensure that streams always have a concrete monomorphic type by -- default, reducing type errors. In case you want to use any other type of -- stream you can use one of the type combinators provided in the "Streamly" -- module to convert the stream type. module Streamly.Prelude ( -- * Construction -- ** Primitives -- | Primitives to construct a stream from pure values or monadic actions. -- All other stream construction and generation combinators described later -- can be expressed in terms of these primitives. However, the special -- versions provided in this module can be much more efficient in most -- cases. Users can create custom combinators using these primitives. nil , cons , (.:) , consM , (|:) -- ** From Values -- | Generate a monadic stream from a seed value or values. , yield , yieldM , repeat , repeatM , replicate , replicateM -- Note: Using enumeration functions e.g. 'Prelude.enumFromThen' turns out -- to be slightly faster than the idioms like @[from, then..]@. -- -- ** Enumeration -- | We can use the 'Enum' type class to enumerate a type producing a list -- and then convert it to a stream: -- -- @ -- 'fromList' $ 'Prelude.enumFromThen' from then -- @ -- -- However, this is not particularly efficient. -- The 'Enumerable' type class provides corresponding functions that -- generate a stream instead of a list, efficiently. , Enumerable (..) , enumerate , enumerateTo -- ** From Generators -- | Generate a monadic stream from a seed value and a generator function. , unfoldr , unfoldrM , unfold , iterate , iterateM , fromIndices , fromIndicesM -- ** From Containers -- | Convert an input structure, container or source into a stream. All of -- these can be expressed in terms of primitives. , fromList , fromListM , fromFoldable , fromFoldableM -- * Elimination -- ** Deconstruction -- | It is easy to express all the folds in terms of the 'uncons' primitive, -- however the specific implementations provided later are generally more -- efficient. -- , uncons , tail , init -- ** Folding -- | In imperative terms a fold can be considered as a loop over the stream -- that reduces the stream to a single value. -- Left and right folds use a fold function @f@ and an identity element @z@ -- (@zero@) to recursively deconstruct a structure and then combine and reduce -- the values or transform and reconstruct a new container. -- -- In general, a right fold is suitable for transforming and reconstructing a -- right associated structure (e.g. cons lists and streamly streams) and a left -- fold is suitable for reducing a right associated structure. The behavior of -- right and left folds are described in detail in the individual fold's -- documentation. To illustrate the two folds for cons lists: -- -- > foldr :: (a -> b -> b) -> b -> [a] -> b -- > foldr f z [] = z -- > foldr f z (x:xs) = x `f` foldr f z xs -- > -- > foldl :: (b -> a -> b) -> b -> [a] -> b -- > foldl f z [] = z -- > foldl f z (x:xs) = foldl f (z `f` x) xs -- -- @foldr@ is conceptually equivalent to: -- -- > foldr f z [] = z -- > foldr f z [x] = f x z -- > foldr f z xs = foldr f (foldr f z (tail xs)) [head xs] -- -- @foldl@ is conceptually equivalent to: -- -- > foldl f z [] = z -- > foldl f z [x] = f z x -- > foldl f z xs = foldl f (foldl f z (init xs)) [last xs] -- -- Left and right folds are duals of each other. -- -- @ -- foldr f z xs = foldl (flip f) z (reverse xs) -- foldl f z xs = foldr (flip f) z (reverse xs) -- @ -- -- More generally: -- -- @ -- foldr f z xs = foldl g id xs z where g k x = k . f x -- foldl f z xs = foldr g id xs z where g x k = k . flip f x -- @ -- -- As a general rule, foldr cannot have state and foldl cannot have control. -- NOTE: Folds are inherently serial as each step needs to use the result of -- the previous step. However, it is possible to fold parts of the stream in -- parallel and then combine the results using a monoid. -- ** Right Folds -- $rightfolds , foldrM -- , foldrS -- , foldrT , foldr -- ** Left Folds -- $leftfolds , foldl' , foldl1' , foldlM' -- ** Composable Left Folds -- $runningfolds , fold -- ** Full Folds -- | Folds that are guaranteed to evaluate the whole stream. -- -- ** To Summary (Full Folds) -- -- | Folds that summarize the stream to a single value. , drain , last , length , sum , product --, mconcat -- -- ** To Summary (Maybe) (Full Folds) -- -- | Folds that summarize a non-empty stream to a 'Just' value and return -- 'Nothing' for an empty stream. , maximumBy , maximum , minimumBy , minimum , the -- , toListRev -- experimental -- ** Lazy Folds -- -- | Folds that generate a lazy structure. Note that the generated -- structure may not be lazy if the underlying monad is strict. -- -- ** To Containers (Full Folds) -- -- | Convert or divert a stream into an output structure, container or -- sink. , toList -- ** Partial Folds -- | Folds that may terminate before evaluating the whole stream. These -- folds strictly evaluate the stream until the result is determined. -- -- ** To Elements (Partial Folds) , drainN , drainWhile -- -- | Folds that extract selected elements of a stream or their properties. , (!!) , head , findM , find , lookup , findIndex , elemIndex -- -- ** To Boolean (Partial Folds) -- -- | Folds that summarize the stream to a boolean value. , null , elem , notElem , all , any , and , or -- ** Multi-Stream folds , eqBy , cmpBy , isPrefixOf -- , isSuffixOf -- , isInfixOf , isSubsequenceOf -- trimming sequences , stripPrefix -- , stripSuffix -- , stripInfix -- * Transformation --, transform -- ** Mapping -- | In imperative terms a map operation can be considered as a loop over -- the stream that transforms the stream into another stream by performing -- an operation on each element of the stream. -- -- 'map' is the least powerful transformation operation with strictest -- guarantees. A map, (1) is a stateless loop which means that no state is -- allowed to be carried from one iteration to another, therefore, -- operations on different elements are guaranteed to not affect each -- other, (2) is a strictly one-to-one transformation of stream elements -- which means it guarantees that no elements can be added or removed from -- the stream, it can merely transform them. , map , sequence , mapM -- ** Special Maps , mapM_ , trace , tap -- ** Scanning -- -- | A scan is more powerful than map. While a 'map' is a stateless loop, a -- @scan@ is a stateful loop which means that a state can be shared across -- all the loop iterations, therefore, future iterations can be impacted by -- the state changes made by the past iterations. A scan yields the state -- of the loop after each iteration. Like a map, a @postscan@ or @prescan@ -- does not add or remove elements in the stream, it just transforms them. -- However, a @scan@ adds one extra element to the stream. -- -- A left associative scan, also known as a prefix sum, can be thought of -- as a stream transformation consisting of left folds of all prefixes of a -- stream. Another way of thinking about it is that it streams all the -- intermediate values of the accumulator while applying a left fold on the -- input stream. A right associative scan, on the other hand, can be -- thought of as a stream consisting of right folds of all the suffixes of -- a stream. -- -- The following equations hold for lists: -- -- > scanl f z xs == map (foldl f z) $ inits xs -- > scanr f z xs == map (foldr f z) $ tails xs -- -- @ -- > scanl (+) 0 [1,2,3,4] -- 0 = 0 -- 0 + 1 = 1 -- 0 + 1 + 2 = 3 -- 0 + 1 + 2 + 3 = 6 -- 0 + 1 + 2 + 3 + 4 = 10 -- -- > scanr (+) 0 [1,2,3,4] -- 1 + 2 + 3 + 4 + 0 = 10 -- 2 + 3 + 4 + 0 = 9 -- 3 + 4 + 0 = 7 -- 4 + 0 = 4 -- 0 = 0 -- @ -- -- Left and right scans are duals: -- -- > scanr f z xs == reverse $ scanl (flip f) z (reverse xs) -- > scanl f z xs == reverse $ scanr (flip f) z (reverse xs) -- -- A scan is a stateful map i.e. a combination of map and fold: -- -- > map f xs = tail $ scanl (\_ x -> f x) z xs -- > map f xs = reverse $ head $ scanr (\_ x -> f x) z xs -- -- > foldl f z xs = last $ scanl f z xs -- > foldr f z xs = head $ scanr f z xs -- ** Left scans , scanl' , scanlM' , postscanl' , postscanlM' -- , prescanl' -- , prescanlM' , scanl1' , scanl1M' -- ** Scan Using Fold , scan , postscan -- , lscanl' -- , lscanlM' -- , lscanl1' -- , lscanl1M' -- -- , lpostscanl' -- , lpostscanlM' -- , lprescanl' -- , lprescanlM' -- ** Filtering -- | Remove some elements from the stream based on a predicate. In -- imperative terms a filter over a stream corresponds to a loop with a -- @continue@ clause for the cases when the predicate fails. , filter , filterM -- ** Mapping Filters -- | Mapping along with filtering , mapMaybe , mapMaybeM -- ** Deleting Elements -- | Deleting elements is a special case of de-interleaving streams. , deleteBy , uniq -- , uniqBy -- by predicate e.g. to remove duplicate "/" in a path -- , uniqOn -- to remove duplicate sequences -- , pruneBy -- dropAround + uniqBy - like words -- ** Inserting Elements -- | Inserting elements is a special case of interleaving/merging streams. , insertBy , intersperseM , intersperse -- , insertAfterEach -- , intersperseBySpan -- , intersperseByIndices -- using an index function/stream -- , intersperseByTime -- , intersperseByEvent -- -- * Inserting Streams in Streams -- , interposeBy -- , intercalate -- ** Indexing -- | Indexing can be considered as a special type of zipping where we zip a -- stream with an index stream. , indexed , indexedR -- , timestamped -- , timestampedR -- timer -- ** Reordering Elements , reverse -- , reverse' -- ** Trimming -- | Take or remove elements from one or both ends of a stream. , take -- , takeEnd , takeWhile , takeWhileM -- , takeWhileEnd , drop -- , dropEnd , dropWhile , dropWhileM -- , dropWhileEnd -- , dropAround -- -- ** Breaking -- By chunks -- , splitAt -- spanN -- , splitIn -- sessionN -- By elements -- , span -- spanWhile -- , break -- breakBefore -- , breakAfter -- , breakOn -- , breakAround -- , spanBy -- , spanByRolling -- By sequences -- breakOnSeq/breakOnArray -- on a fixed sequence -- breakOnStream -- on a stream -- ** Slicing -- | Streams can be sliced into segments in space or in time. We use the -- term @chunk@ to refer to a spatial length of the stream (spatial window) -- and the term @session@ to refer to a length in time (time window). -- In imperative terms, grouped folding can be considered as a nested loop -- where we loop over the stream to group elements and then loop over -- individual groups to fold them to a single value that is yielded in the -- output stream. -- , groupScan , chunksOf , intervalsOf -- ** Searching -- | Finding the presence or location of an element, a sequence of elements -- or another stream within a stream. -- -- ** Searching Elements , findIndices , elemIndices -- -- *** Searching Sequences -- , seqIndices -- search a sequence in the stream -- -- *** Searching Multiple Sequences -- , seqIndices -- search a sequence in the stream -- -- ** Searching Streams -- -- | Finding a stream within another stream. -- ** Splitting -- | In general we can express splitting in terms of parser combinators. -- These are some common use functions for convenience and efficiency. -- While parsers can fail these functions are designed to transform a -- stream without failure with a predefined behavior for all cases. -- -- In general, there are three possible ways of combining stream segments -- with a separator. The separator could be prefixed to each segment, -- suffixed to each segment, or it could be infixed between segments. -- 'intersperse' and 'intercalate' operations are examples of infixed -- combining whereas 'unlines' is an example of suffixed combining. When we -- split a stream with separators we can split in three different ways, -- each being an opposite of the three ways of combining. -- -- Splitting may keep the separator or drop it. Depending on how we split, -- the separator may be kept attached to the stream segments in prefix or -- suffix position or as a separate element in infix position. Combinators -- like 'splitOn' that use @On@ in their names drop the separator and -- combinators that use 'With' in their names keep the separator. When a -- segment is missing it is considered as empty, therefore, we never -- encounter an error in parsing. -- -- ** Splitting By Elements , splitOn , splitOnSuffix -- , splitOnPrefix -- , splitBy , splitWithSuffix -- , splitByPrefix , wordsBy -- strip, compact and split -- -- *** Splitting By Sequences -- , splitOnSeq -- , splitOnSuffixSeq -- , splitOnPrefixSeq -- Keeping the delimiters -- , splitBySeq -- , splitBySeqSuffix -- , splitBySeqPrefix -- , wordsBySeq -- Splitting By Multiple Sequences -- , splitOnAnySeq -- , splitOnAnySuffixSeq -- , splitOnAnyPrefixSeq -- -- ** Splitting By Streams -- -- | Splitting a stream using another stream as separator. -- ** Grouping -- | Splitting a stream by combining multiple contiguous elements into -- groups using some criterion. , groups , groupsBy , groupsByRolling {- -- * Windowed Classification -- | Split the stream into windows or chunks in space or time. Each window -- can be associated with a key, all events associated with a particular -- key in the window can be folded to a single result. The stream is split -- into windows of specified size, the window can be terminated early if -- the closing flag is specified in the input stream. -- -- The term "chunk" is used for a space window and the term "session" is -- used for a time window. -- ** Tumbling Windows -- | A new window starts after the previous window is finished. -- , classifyChunksOf -- , classifySessionsOf -- ** Keep Alive Windows -- | The window size is extended if an event arrives within the specified -- window size. This can represent sessions with idle or inactive timeout. -- , classifyKeepAliveChunks -- , classifyKeepAliveSessions {- -- ** Sliding Windows -- | A new window starts after the specified slide from the previous -- window. Therefore windows can overlap. , classifySlidingChunks , classifySlidingSessions -} -- ** Sliding Window Buffers -- , slidingChunkBuffer -- , slidingSessionBuffer -} -- * Combining Streams -- | New streams can be constructed by appending, merging or zipping -- existing streams. -- ** Appending -- | Streams form a 'Semigroup' and a 'Monoid' under the append -- operation. Appending can be considered as a generalization of the `cons` -- operation to consing a stream to a stream. -- -- @ -- -- -------Stream m a------|-------Stream m a------|=>----Stream m a--- -- -- @ -- -- @ -- >> S.toList $ S.fromList [1,2] \<> S.fromList [3,4] -- [1,2,3,4] -- >> S.toList $ fold $ [S.fromList [1,2], S.fromList [3,4]] -- [1,2,3,4] -- @ -- ** Merging -- | Streams form a commutative semigroup under the merge -- operation. Merging can be considered as a generalization of inserting an -- element in a stream to interleaving a stream with another stream. -- -- @ -- -- -------Stream m a------| -- |=>----Stream m a--- -- -------Stream m a------| -- @ -- -- , merge , mergeBy , mergeByM , mergeAsyncBy , mergeAsyncByM -- ** Zipping -- | -- @ -- -- -------Stream m a------| -- |=>----Stream m c--- -- -------Stream m b------| -- @ -- , zipWith , zipWithM , zipAsyncWith , zipAsyncWithM {- -- ** Folding Containers of Streams -- | These are variants of standard 'Foldable' fold functions that use a -- polymorphic stream sum operation (e.g. 'async' or 'wSerial') to fold a -- finite container of streams. Note that these are just special cases of -- the more general 'concatMapWith' operation. -- , foldMapWith , forEachWith , foldWith -} -- ** Folding Streams of Streams -- | Stream operations like map and filter represent loop processing in -- imperative programming terms. Similarly, the imperative concept of -- nested loops are represented by streams of streams. The 'concatMap' -- operation represents nested looping. -- A 'concatMap' operation loops over the input stream and then for each -- element of the input stream generates another stream and then loops over -- that inner stream as well producing effects and generating a single -- output stream. -- The 'Monad' instances of different stream types provide a more -- convenient way of writing nested loops. Note that the monad bind -- operation is just @flip concatMap@. -- -- One dimension loops are just a special case of nested loops. For -- example, 'concatMap' can degenerate to a simple map operation: -- -- > map f m = S.concatMap (\x -> S.yield (f x)) m -- -- Similarly, 'concatMap' can perform filtering by mapping an element to a -- 'nil' stream: -- -- > filter p m = S.concatMap (\x -> if p x then S.yield x else S.nil) m -- -- XXX add stateful concatMapWith , concatMapWith --, bindWith , concatMap , concatMapM , concatUnfold -- * Exceptions , before , after , bracket , onException , finally , handle -- * Deprecated , once , each , scanx , foldx , foldxM , foldr1 , runStream , runN , runWhile , fromHandle , toHandle ) where import Prelude hiding (filter, drop, dropWhile, take, takeWhile, zipWith, foldr, foldl, map, mapM, mapM_, sequence, all, any, sum, product, elem, notElem, maximum, minimum, head, last, tail, length, null, reverse, iterate, init, and, or, lookup, foldr1, (!!), scanl, scanl1, repeat, replicate, concatMap, span) import Streamly.Internal.Prelude -- $rightfolds -- -- Let's take a closer look at the @foldr@ definition for lists, as given -- earlier: -- -- @ -- foldr f z (x:xs) = x \`f` foldr f z xs -- @ -- -- @foldr@ invokes the fold step function @f@ as @f x (foldr f z xs)@. At each -- invocation of @f@, @foldr@ gives us the next element in the input container -- @x@ and a recursive expression @foldr f z xs@ representing the yet unbuilt -- (lazy thunk) part of the output. -- -- When @f x xs@ is lazy in @xs@ it can consume the input one element at a time -- in FIFO order to build a lazy output expression. For example, -- -- > f x remaining = show x : remaining -- -- @take 2 $ foldr f [] (1:2:undefined)@ would consume the input lazily on -- demand, consuming only first two elements and resulting in ["1", "2"]. @f@ -- can terminate recursion by not evaluating the @remaining@ part: -- -- > f 2 remaining = show 2 : [] -- > f x remaining = show x : remaining -- -- @f@ would terminate recursion whenever it sees element @2@ in the input. -- Therefore, @take 2 $ foldr f [] (1:2:undefined)@ would work without any -- problem. -- -- On the other hand, if @f a b@ is strict in @b@ it would end up consuming the -- whole input right away and expanding the recursive expression @b@ (i.e. -- @foldr f z xs@) fully before it yields an output expression, resulting in -- the following /right associated expression/: -- -- @ -- foldr f z xs == x1 \`f` (x2 \`f` ...(xn \`f` z)) -- @ -- -- For example, -- -- > f x remaining = x + remaining -- -- With this definition, @foldr f 0 [1..1000]@, would recurse completely until -- it reaches the terminating case @... `f` (1000 `f` 0)@, and then -- start reducing the whole expression from right to left, therefore, consuming -- the input elements in LIFO order. Thus, such an evaluation would require -- memory proportional to the size of input. Try out @foldr (+) 0 (map (\\x -> -- trace (show x) x) [1..10])@. -- -- Notice the order of the arguments to the step function @f a b@. It follows -- the order of @a@ and @b@ in the right associative recursive expression -- generated by expanding @a \`f` b@. -- -- A right fold is a pull fold, the step function is the puller, it can pull -- more data from the input container by using its second argument in the -- output expression or terminate pulling by not using it. As a corollary: -- -- 1. a step function which is lazy in its second argument (usually functions -- or constructors that build a lazy structure e.g. @(:)@) can pull lazily on -- demand. -- 2. a step function strict in its second argument (usually reducers e.g. -- (+)) would end up pulling all of its input and buffer it in memory before -- potentially reducing it. -- -- A right fold is suitable for lazy reconstructions e.g. transformation, -- mapping, filtering of /right associated input structures/ (e.g. cons lists). -- Whereas a left fold is suitable for reductions (e.g. summing a stream of -- numbers) of right associated structures. Note that these roles will reverse -- for left associated structures (e.g. snoc lists). Most of our observations -- here assume right associated structures, lists being the canonical example. -- -- 1. A lazy FIFO style pull using a right fold allows pulling a potentially -- /infinite/ input stream lazily, perform transformations on it, and -- reconstruct a new structure without having to buffer the whole structure. In -- contrast, a left fold would buffer the entire structure before the -- reconstructed structure can be consumed. -- 2. Even if buffering the entire input structure is ok, we need to keep in -- mind that a right fold reconstructs structures in a FIFO style, whereas a -- left fold reconstructs in a LIFO style, thereby reversing the order of -- elements.. -- 3. A right fold has termination control and therefore can terminate early -- without going throught the entire input, a left fold cannot terminate -- without consuming all of its input. For example, a right fold -- implementation of 'or' can terminate as soon as it finds the first 'True' -- element, whereas a left fold would necessarily go through the entire input -- irrespective of that. -- 4. Reduction (e.g. using (+) on a stream of numbers) using a right fold -- occurs in a LIFO style, which means that the entire input gets buffered -- before reduction starts. Whereas with a strict left fold reductions occur -- incrementally in FIFO style. Therefore, a strict left fold is more suitable -- for reductions. -- -- $leftfolds -- -- Note that the observations below about the behavior of a left fold assume -- that we are working on a right associated structure like cons lists and -- streamly streams. If we are working on a left associated structure (e.g. -- snoc lists) the roles of right and left folds would reverse. -- -- Let's take a closer look at the @foldl@ definition for lists given above: -- -- @ -- foldl f z (x:xs) = foldl f (z \`f` x) xs -- @ -- -- @foldl@ calls itself recursively, in each call it invokes @f@ as @f z x@ -- providing it with the result accumulated till now @z@ (the state) and the -- next element from the input container. First call to @f@ is supplied with -- the initial value of the accumulator @z@ and each subsequent call uses the -- output of the previous call to @f z x@. -- -- >> foldl' (+) 0 [1,2,3] -- > 6 -- -- The recursive call at the head of the output expression is bound to be -- evaluated until recursion terminates, therefore, a left fold always -- /consumes the whole input container/. The following would result in an -- error, even though the fold is not using the values at all: -- -- >> foldl' (\_ _ -> 0) 0 (1:undefined) -- > *** Exception: Prelude.undefined -- -- As @foldl@ recurses, it builds the left associated expression shown below. -- Notice, the order of the arguments to the step function @f b a@. It follows -- the left associative recursive expression generated by expanding @b \`f` a@. -- -- @ -- foldl f z xs == (((z \`f` x1) \`f` x2) ...) \`f` xn -- @ -- -- -- The strict left fold @foldl'@ forces the reduction of its argument @z \`f` -- x@ before using it, therefore it never builds the whole expression in -- memory. Thus, @z \`f` x1@ would get reduced to @z1@ and then @z1 \`f` x2@ -- would get reduced to @z2@ and so on, incrementally reducing the expression -- from left to right as it recurses, consuming the input in FIFO order. Try -- out @foldl' (+) 0 (map (\\x -> trace (show x) x) [1..10])@ to see how it -- works. For example: -- -- @ -- > S.foldl' (+) 0 $ S.fromList [1,2,3,4] -- 10 -- @ -- -- @ -- 0 + 1 = 1 -- 1 + 2 = 3 -- 3 + 3 = 6 -- 6 + 4 = 10 -- @ -- -- However, @foldl'@ evaluates the accumulator only to WHNF. It may further -- help if the step function uses a strict data structure as accumulator to -- improve performance and to keep the expression fully reduced at all times -- during the fold. -- -- A left fold can also build a new structure instead of reducing one if a -- constructor is used as a fold step. However, it may not be very useful -- because it will consume the whole input and construct the new structure in -- memory before we can consume it. Thus the whole structure gets buffered in -- memory. When the list constructor is used it would build a new list in -- reverse (LIFO) order: -- -- @ -- > S.foldl' (flip (:)) [] $ S.fromList [1,2,3,4] -- [4,3,2,1] -- @ -- -- A left fold is a push fold. The producer pushes its contents to the step -- function of the fold. The step function therefore has no control to stop the -- input, it can only discard it if it does not need it. We can also consider a -- left fold as a state machine where the state is store in the accumulator, -- the state can be modified based on new inputs that are pushed to the fold. -- -- In general, a strict left fold is a reducing fold, whereas a right fold is a -- constructing fold. A strict left fold reduces in a FIFO order whereas it -- constructs in a LIFO order, and vice-versa for the right fold. See the -- documentation of 'foldrM' for a discussion on where a left or right fold is -- suitable. -- -- To perform a left fold lazily without having to consume all the input one -- can use @scanl@ to stream the intermediate results of the fold and consume -- the resulting stream lazily. -- -- $runningfolds -- -- "Streamly.Data.Fold" module defines composable left folds which can be combined -- together in many interesting ways. Those folds can be run using 'fold'. -- The following two ways of folding are equivalent in functionality and -- performance, -- -- >>> S.fold FL.sum (S.enumerateFromTo 1 100) -- 5050 -- >>> S.sum (S.enumerateFromTo 1 100) -- 5050 -- -- However, left folds cannot terminate early even if it does not need to -- consume more input to determine the result. Therefore, the performance is -- equivalent only for full folds like 'sum' and 'length'. For partial folds -- like 'head' or 'any' the the folds defined in this module may be much more -- efficient because they are implemented as right folds that terminate as soon -- as we get the result. Note that when a full fold is composed with a partial -- fold in parallel the performance is not impacted as we anyway have to -- consume the whole stream due to the full fold. -- -- >>> S.head (1 `S.cons` undefined) -- Just 1 -- >>> S.fold FL.head (1 `S.cons` undefined) -- *** Exception: Prelude.undefined -- -- However, we can wrap the fold in a scan to convert it into a lazy stream of -- fold steps. We can then terminate the stream whenever we want. For example, -- -- >>> S.toList $ S.take 1 $ S.scan FL.head (1 `S.cons` undefined) -- [Nothing] -- -- The following example extracts the input stream up to a point where the -- running average of elements is no more than 10: -- -- @ -- > S.toList -- $ S.map (fromJust . fst) -- $ S.takeWhile (\\(_,x) -> x <= 10) -- $ S.postscan ((,) \<$> FL.last \<*> avg) (S.enumerateFromTo 1.0 100.0) -- @ -- @ -- [1.0,2.0,3.0,4.0,5.0,6.0,7.0,8.0,9.0,10.0,11.0,12.0,13.0,14.0,15.0,16.0,17.0,18.0,19.0] -- @