{-# LANGUAGE BangPatterns #-} {-# LANGUAGE CPP #-} {-# LANGUAGE ExistentialQuantification #-} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE RecordWildCards #-} {-# LANGUAGE ScopedTypeVariables #-} -- | -- Module : Streamly.Internal.Data.Pipe -- Copyright : (c) 2019 Composewell Technologies -- License : BSD3 -- Maintainer : streamly@composewell.com -- Stability : experimental -- Portability : GHC -- -- There are three fundamental types in streamly. They are streams -- ("Streamly.Prelude"), pipes ("Streamly.Internal.Data.Pipe") and folds ("Streamly.Data.Fold"). -- Streams are sources or producers of values, multiple sources can be merged -- into a single source but a source cannot be split into multiple stream -- sources. Folds are sinks or consumers, a stream can be split and -- distributed to multiple folds but the results cannot be merged back into a -- stream source again. Pipes are transformations, a stream source can be split -- and distributed to multiple pipes each pipe can apply its own transform on -- the stream and the results can be merged back into a single pipe. Pipes can -- be attached to a source to produce a source or they can be attached to a -- fold to produce a fold, or multiple pipes can be merged or zipped into a -- single pipe. -- -- > import qualified Streamly.Internal.Data.Pipe as P module Streamly.Internal.Data.Pipe ( -- * Pipe Type Pipe -- * Pipes -- ** Mapping , map , mapM {- -- ** Filtering , lfilter , lfilterM -- , ldeleteBy -- , luniq {- -- ** Mapping Filters , lmapMaybe , lmapMaybeM -- ** Scanning Filters , lfindIndices , lelemIndices -- ** Insertion -- | Insertion adds more elements to the stream. , linsertBy , lintersperseM -- ** Reordering , lreverse -} -- * Parsing -- ** Trimming , ltake -- , lrunFor -- time , ltakeWhile {- , ltakeWhileM , ldrop , ldropWhile , ldropWhileM -} -- ** Splitting -- | Streams can be split 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. -- *** By Chunks , chunksOf , sessionsOf -- *** By Elements , splitBy , splitSuffixBy , splitSuffixBy' -- , splitPrefixBy , wordsBy -- *** By Sequences , splitOn , splitSuffixOn -- , splitPrefixOn -- , wordsOn -- Keeping the delimiters , splitOn' , splitSuffixOn' -- , splitPrefixOn' -- Splitting by multiple sequences -- , splitOnAny -- , splitSuffixOnAny -- , splitPrefixOnAny -- ** Grouping , groups , groupsBy , groupsRollingBy -} -- * Composing Pipes , tee , zipWith , compose {- -- * Distributing -- | -- The 'Applicative' instance of a distributing 'Fold' distributes one copy -- of the stream to each fold and combines the results using a function. -- -- @ -- -- |-------Fold m a b--------| -- ---stream m a---| |---m (b,c,...) -- |-------Fold m a c--------| -- | | -- ... -- @ -- -- To compute the average of numbers in a stream without going through the -- stream twice: -- -- >>> let avg = (/) <$> FL.sum <*> fmap fromIntegral FL.length -- >>> FL.foldl' avg (S.enumerateFromTo 1.0 100.0) -- 50.5 -- -- The 'Semigroup' and 'Monoid' instances of a distributing fold distribute -- the input to both the folds and combines the outputs using Monoid or -- Semigroup instances of the output types: -- -- >>> import Data.Monoid (Sum) -- >>> FL.foldl' (FL.head <> FL.last) (fmap Sum $ S.enumerateFromTo 1.0 100.0) -- Just (Sum {getSum = 101.0}) -- -- The 'Num', 'Floating', and 'Fractional' instances work in the same way. , tee , distribute -- * Partitioning -- | -- Direct items in the input stream to different folds using a function to -- select the fold. This is useful to demultiplex the input stream. -- , partitionByM -- , partitionBy , partition -- * Demultiplexing , demux -- , demuxWith , demux_ -- , demuxWith_ -- * Classifying , classify -- , classifyWith -- * Unzipping , unzip -- These can be expressed using lmap/lmapM and unzip -- , unzipWith -- , unzipWithM -- * Nested Folds -- , concatMap -- , chunksOf , duplicate -- experimental -- * 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 -} ) where -- import Control.Concurrent (threadDelay, forkIO, killThread) -- import Control.Concurrent.MVar (MVar, newMVar, takeMVar, putMVar) -- import Control.Exception (SomeException(..), catch, mask) -- import Control.Monad (void) -- import Control.Monad.Catch (throwM) -- import Control.Monad.IO.Class (MonadIO(..)) -- import Control.Monad.Trans (lift) -- import Control.Monad.Trans.Control (control) -- import Data.Functor.Identity (Identity) -- import Data.Heap (Entry(..)) -- import Data.Map.Strict (Map) -- import Data.Maybe (fromJust, isJust, isNothing) -- import Foreign.Storable (Storable(..)) import Prelude hiding (id, filter, drop, dropWhile, take, takeWhile, zipWith, foldr, foldl, map, mapM_, sequence, all, any, sum, product, elem, notElem, maximum, minimum, head, last, tail, length, null, reverse, iterate, init, and, or, lookup, foldr1, (!!), scanl, scanl1, replicate, concatMap, mconcat, foldMap, unzip, span, splitAt, break, mapM) -- import qualified Data.Heap as H -- import qualified Data.Map.Strict as Map -- import qualified Prelude -- import Streamly (MonadAsync, parallel) -- import Streamly.Data.Fold.Types (Fold(..)) import Streamly.Internal.Data.Pipe.Types (Pipe(..), PipeState(..), Step(..), zipWith, tee, map, compose) -- import Streamly.Internal.Memory.Array.Types (Array) -- import Streamly.Memory.Ring (Ring) -- import Streamly.Internal.Data.Stream.Serial (SerialT) -- import Streamly.Internal.Data.Stream.StreamK (IsStream()) -- import Streamly.Internal.Data.Time.Units -- (AbsTime, MilliSecond64(..), addToAbsTime, diffAbsTime, toRelTime, -- toAbsTime) -- import Streamly.Internal.Data.Strict -- import qualified Streamly.Internal.Memory.Array.Types as A -- import qualified Streamly.Prelude as S -- import qualified Streamly.Internal.Data.Stream.StreamD as D -- import qualified Streamly.Internal.Data.Stream.StreamK as K -- import qualified Streamly.Internal.Data.Stream.Prelude as P ------------------------------------------------------------------------------ -- Pipes ------------------------------------------------------------------------------ -- | Lift a monadic function to a 'Pipe'. -- -- @since 0.7.0 {-# INLINE mapM #-} mapM :: Monad m => (a -> m b) -> Pipe m a b mapM :: (a -> m b) -> Pipe m a b mapM a -> m b f = (() -> a -> m (Step (PipeState () Any) b)) -> (Any -> m (Step (PipeState () Any) b)) -> () -> Pipe m a b forall (m :: * -> *) a b s1 s2. (s1 -> a -> m (Step (PipeState s1 s2) b)) -> (s2 -> m (Step (PipeState s1 s2) b)) -> s1 -> Pipe m a b Pipe () -> a -> m (Step (PipeState () Any) b) forall p s2. p -> a -> m (Step (PipeState () s2) b) consume Any -> m (Step (PipeState () Any) b) forall a. HasCallStack => a undefined () where consume :: p -> a -> m (Step (PipeState () s2) b) consume p _ a a = do b r <- a -> m b f a a Step (PipeState () s2) b -> m (Step (PipeState () s2) b) forall (m :: * -> *) a. Monad m => a -> m a return (Step (PipeState () s2) b -> m (Step (PipeState () s2) b)) -> Step (PipeState () s2) b -> m (Step (PipeState () s2) b) forall a b. (a -> b) -> a -> b $ b -> PipeState () s2 -> Step (PipeState () s2) b forall s a. a -> s -> Step s a Yield b r (() -> PipeState () s2 forall s1 s2. s1 -> PipeState s1 s2 Consume ()) {- ------------------------------------------------------------------------------ -- Filtering ------------------------------------------------------------------------------ -- | Include only those elements that pass a predicate. -- -- >>> FL.foldl (lfilter (> 5) FL.sum) [1..10] -- 40 -- -- @since 0.7.0 {-# INLINABLE lfilter #-} lfilter :: Monad m => (a -> Bool) -> Fold m a r -> Fold m a r lfilter f (Fold step begin done) = Fold step' begin done where step' x a = if f a then step x a else return x -- | Like 'lfilter' but with a monadic predicate. -- -- @since 0.7.0 {-# INLINABLE lfilterM #-} lfilterM :: Monad m => (a -> m Bool) -> Fold m a r -> Fold m a r lfilterM f (Fold step begin done) = Fold step' begin done where step' x a = do use <- f a if use then step x a else return x -- | Take first 'n' elements from the stream and discard the rest. -- -- @since 0.7.0 {-# INLINABLE ltake #-} ltake :: Monad m => Int -> Fold m a b -> Fold m a b ltake n (Fold step initial done) = Fold step' initial' done' where initial' = fmap (Tuple' 0) initial step' (Tuple' i r) a = do if i < n then do res <- step r a return $ Tuple' (i + 1) res else return $ Tuple' i r done' (Tuple' _ r) = done r -- | Takes elements from the input as long as the predicate succeeds. -- -- @since 0.7.0 {-# INLINABLE ltakeWhile #-} ltakeWhile :: Monad m => (a -> Bool) -> Fold m a b -> Fold m a b ltakeWhile predicate (Fold step initial done) = Fold step' initial' done' where initial' = fmap Left' initial step' (Left' r) a = do if predicate a then fmap Left' $ step r a else return (Right' r) step' r _ = return r done' (Left' r) = done r done' (Right' r) = done r ------------------------------------------------------------------------------ -- Grouping/Splitting ------------------------------------------------------------------------------ ------------------------------------------------------------------------------ -- Grouping without looking at elements ------------------------------------------------------------------------------ -- ------------------------------------------------------------------------------ -- Binary APIs ------------------------------------------------------------------------------ -- -- | @splitAt n f1 f2@ composes folds @f1@ and @f2@ such that first @n@ -- elements of its input are sent to fold @f1@ and the rest of the stream is -- sent to fold @f2@. -- -- > let splitAt_ n xs = FL.foldl' (FL.splitAt n FL.toList FL.toList) $ S.fromList xs -- -- >>> splitAt_ 6 "Hello World!" -- > ("Hello ","World!") -- -- >>> splitAt_ (-1) [1,2,3] -- > ([],[1,2,3]) -- -- >>> splitAt_ 0 [1,2,3] -- > ([],[1,2,3]) -- -- >>> splitAt_ 1 [1,2,3] -- > ([1],[2,3]) -- -- >>> splitAt_ 3 [1,2,3] -- > ([1,2,3],[]) -- -- >>> splitAt_ 4 [1,2,3] -- > ([1,2,3],[]) -- -- This can be considered as a two-fold version of 'ltake' where we take both -- the segments instead of discarding the leftover. -- -- @since 0.7.0 {-# INLINE splitAt #-} splitAt :: Monad m => Int -> Fold m a b -> Fold m a c -> Fold m a (b, c) splitAt n (Fold stepL initialL extractL) (Fold stepR initialR extractR) = Fold step init extract where init = Tuple3' <$> return n <*> initialL <*> initialR step (Tuple3' i xL xR) input = if i > 0 then stepL xL input >>= (\a -> return (Tuple3' (i - 1) a xR)) else stepR xR input >>= (\b -> return (Tuple3' i xL b)) extract (Tuple3' _ a b) = (,) <$> extractL a <*> extractR b ------------------------------------------------------------------------------ -- N-ary APIs ------------------------------------------------------------------------------ ------------------------------------------------------------------------------ -- Generalized grouping ------------------------------------------------------------------------------ -- This combinator is the most general grouping combinator and can be used to -- implement all other grouping combinators. -- -- XXX check if this can implement the splitOn combinator i.e. we can slide in -- new elements, slide out old elements and incrementally compute the hash. -- Also, can we implement the windowed classification combinators using this? -- -- In fact this is a parse. Instead of using a special return value in the fold -- we are using a mapping function. -- -- Note that 'scanl'' (usually followed by a map to extract the desired value -- from the accumulator) can be used to realize many implementations e.g. a -- sliding window implementation. A scan followed by a mapMaybe is also a good -- pattern to express many problems where we want to emit a filtered output and -- not emit an output on every input. -- -- Passing on of the initial accumulator value to the next fold is equivalent -- to returning the leftover concept. {- -- | @groupScan splitter fold stream@ folds the input stream using @fold@. -- @splitter@ is applied on the accumulator of the fold every time an item is -- consumed by the fold. The fold continues until @splitter@ returns a 'Just' -- value. A 'Just' result from the @splitter@ specifies a result to be emitted -- in the output stream and the initial value of the accumulator for the next -- group's fold. This allows us to control whether to start fresh for the next -- fold or to continue from the previous fold's output. -- {-# INLINE groupScan #-} groupScan :: (IsStream t, Monad m) => (x -> m (Maybe (b, x))) -> Fold m a x -> t m a -> t m b groupScan split fold m = undefined -} -- | Group the input stream into groups of @n@ elements each and then fold each -- group using the provided fold function. -- -- >> S.toList $ FL.chunksOf 2 FL.sum (S.enumerateFromTo 1 10) -- > [3,7,11,15,19] -- -- This can be considered as an n-fold version of 'ltake' where we apply -- 'ltake' repeatedly on the leftover stream until the stream exhausts. -- -- @since 0.7.0 {-# INLINE chunksOf #-} chunksOf :: (IsStream t, Monad m) => Int -> Fold m a b -> t m a -> t m b chunksOf n f m = D.fromStreamD $ D.groupsOf n f (D.toStreamD m) -- | Transform a fold from a pure input to a 'Maybe' input, consuming only -- 'Just' values. {-# INLINE lcatMaybes #-} lcatMaybes :: Monad m => Fold m a b -> Fold m (Maybe a) b lcatMaybes = lfilter isJust . lmap fromJust -- XXX we can implement this by repeatedly applying the 'lrunFor' fold. -- XXX add this example after fixing the serial stream rate control -- >>> S.toList $ S.take 5 $ sessionsOf 1 FL.sum $ constRate 2 $ S.enumerateFrom 1 -- > [3,7,11,15,19] -- -- | Group the input stream into windows of @n@ second each and then fold each -- group using the provided fold function. -- -- @since 0.7.0 {-# INLINE sessionsOf #-} sessionsOf :: (IsStream t, MonadAsync m) => Double -> Fold m a b -> t m a -> t m b sessionsOf n f xs = splitSuffixBy' isNothing (lcatMaybes f) (S.intersperseByTime n (return Nothing) (S.map Just xs)) ------------------------------------------------------------------------------ -- Element Aware APIs ------------------------------------------------------------------------------ -- ------------------------------------------------------------------------------ -- Binary APIs ------------------------------------------------------------------------------ -- | Break the input stream into two groups, the first group takes the input as -- long as the predicate applied to the first element of the stream and next -- input element holds 'True', the second group takes the rest of the input. -- _spanBy :: Monad m => (a -> a -> Bool) -> Fold m a b -> Fold m a c -> Fold m a (b, c) _spanBy cmp (Fold stepL initialL extractL) (Fold stepR initialR extractR) = Fold step init extract where init = Tuple3' <$> initialL <*> initialR <*> return (Tuple' Nothing True) step (Tuple3' a b (Tuple' (Just frst) isFirstG)) input = if cmp frst input && isFirstG then stepL a input >>= (\a' -> return (Tuple3' a' b (Tuple' (Just frst) isFirstG))) else stepR b input >>= (\a' -> return (Tuple3' a a' (Tuple' Nothing False))) step (Tuple3' a b (Tuple' Nothing isFirstG)) input = if isFirstG then stepL a input >>= (\a' -> return (Tuple3' a' b (Tuple' (Just input) isFirstG))) else stepR b input >>= (\a' -> return (Tuple3' a a' (Tuple' Nothing False))) extract (Tuple3' a b _) = (,) <$> extractL a <*> extractR b -- | Span as long as the predicate is 'True'. @span p f1 f2@ composes folds -- @f1@ and @f2@ such that the composed fold continues sending the input to -- @f1@ as long as the predicate @p@ is 'True'. The rest of the input is sent -- to @f2@. -- -- > let span_ p xs = FL.foldl' (FL.span p FL.toList FL.toList) $ S.fromList xs -- -- >>> span_ (< 1) [1,2,3] -- > ([],[1,2,3]) -- -- >>> span_ (< 2) [1,2,3] -- > ([1],[2,3]) -- -- >>> span_ (< 4) [1,2,3] -- > ([1,2,3],[]) -- -- This can be considered as a two-fold version of 'ltakeWhile' where we take -- both the segments instead of discarding the leftover. -- -- @since 0.7.0 {-# INLINE span #-} span :: Monad m => (a -> Bool) -> Fold m a b -> Fold m a c -> Fold m a (b, c) span p (Fold stepL initialL extractL) (Fold stepR initialR extractR) = Fold step init extract where init = Tuple3' <$> initialL <*> initialR <*> return True step (Tuple3' a b isFirstG) input = if isFirstG && p input then stepL a input >>= (\a' -> return (Tuple3' a' b True)) else stepR b input >>= (\a' -> return (Tuple3' a a' False)) extract (Tuple3' a b _) = (,) <$> extractL a <*> extractR b -- | -- > break p = span (not . p) -- -- Break as soon as the predicate becomes 'True'. @break p f1 f2@ composes -- folds @f1@ and @f2@ such that @f1@ stops receiving input as soon as the -- predicate @p@ becomes 'True'. The rest of the input is sent to @f2@. -- -- This is the binary version of 'splitBy'. -- -- > let break_ p xs = FL.foldl' (FL.break p FL.toList FL.toList) $ S.fromList xs -- -- >>> break_ (< 1) [3,2,1] -- > ([3,2,1],[]) -- -- >>> break_ (< 2) [3,2,1] -- > ([3,2],[1]) -- -- >>> break_ (< 4) [3,2,1] -- > ([],[3,2,1]) -- -- @since 0.7.0 {-# INLINE break #-} break :: Monad m => (a -> Bool) -> Fold m a b -> Fold m a c -> Fold m a (b, c) break p = span (not . p) -- | Like 'spanBy' but applies the predicate in a rolling fashion i.e. -- predicate is applied to the previous and the next input elements. {-# INLINE _spanRollingBy #-} _spanRollingBy :: Monad m => (a -> a -> Bool) -> Fold m a b -> Fold m a c -> Fold m a (b, c) _spanRollingBy cmp (Fold stepL initialL extractL) (Fold stepR initialR extractR) = Fold step init extract where init = Tuple3' <$> initialL <*> initialR <*> return Nothing step (Tuple3' a b (Just frst)) input = if cmp input frst then stepL a input >>= (\a' -> return (Tuple3' a' b (Just input))) else stepR b input >>= (\b' -> return (Tuple3' a b' (Just input))) step (Tuple3' a b Nothing) input = stepL a input >>= (\a' -> return (Tuple3' a' b (Just input))) extract (Tuple3' a b _) = (,) <$> extractL a <*> extractR b ------------------------------------------------------------------------------ -- N-ary APIs ------------------------------------------------------------------------------ -- -- | @groupsBy cmp f $ S.fromList [a,b,c,...]@ assigns the element @a@ to the -- first group, if @a \`cmp` b@ is 'True' then @b@ is also assigned to the same -- group. If @a \`cmp` c@ is 'True' then @c@ is also assigned to the same -- group and so on. When the comparison fails a new group is started. Each -- group is folded using the fold @f@. -- -- >>> S.toList $ FL.groupsBy (>) FL.toList $ S.fromList [1,3,7,0,2,5] -- > [[1,3,7],[0,2,5]] -- -- @since 0.7.0 {-# INLINE groupsBy #-} groupsBy :: (IsStream t, Monad m) => (a -> a -> Bool) -> Fold m a b -> t m a -> t m b groupsBy cmp f m = D.fromStreamD $ D.groupsBy cmp f (D.toStreamD m) -- | Unlike @groupsBy@ this function performs a rolling comparison of two -- successive elements in the input stream. @groupsRollingBy cmp f $ S.fromList -- [a,b,c,...]@ assigns the element @a@ to the first group, if @a \`cmp` b@ is -- 'True' then @b@ is also assigned to the same group. If @b \`cmp` c@ is -- 'True' then @c@ is also assigned to the same group and so on. When the -- comparison fails a new group is started. Each group is folded using the fold -- @f@. -- -- >>> S.toList $ FL.groupsRollingBy (\a b -> a + 1 == b) FL.toList $ S.fromList [1,2,3,7,8,9] -- > [[1,2,3],[7,8,9]] -- -- @since 0.7.0 {-# INLINE groupsRollingBy #-} groupsRollingBy :: (IsStream t, Monad m) => (a -> a -> Bool) -> Fold m a b -> t m a -> t m b groupsRollingBy cmp f m = D.fromStreamD $ D.groupsRollingBy cmp f (D.toStreamD m) -- | -- > groups = groupsBy (==) -- > groups = groupsRollingBy (==) -- -- Groups a contiguous span of equal elements together in one group. -- -- >>> S.toList $ FL.groups FL.toList $ S.fromList [1,1,2,2] -- > [[1,1],[2,2]] -- -- @since 0.7.0 groups :: (IsStream t, Monad m, Eq a) => Fold m a b -> t m a -> t m b groups = groupsBy (==) ------------------------------------------------------------------------------ -- Binary splitting on a separator ------------------------------------------------------------------------------ {- -- | Find the first occurrence of the specified sequence in the input stream -- and break the input stream into two parts, the first part consisting of the -- stream before the sequence and the second part consisting of the sequence -- and the rest of the stream. -- -- > let breakOn_ pat xs = FL.foldl' (FL.breakOn pat FL.toList FL.toList) $ S.fromList xs -- -- >>> breakOn_ "dear" "Hello dear world!" -- > ("Hello ","dear world!") -- {-# INLINE breakOn #-} breakOn :: Monad m => Array a -> Fold m a b -> Fold m a c -> Fold m a (b,c) breakOn pat f m = undefined -} ------------------------------------------------------------------------------ -- N-ary split on a predicate ------------------------------------------------------------------------------ -- TODO: Use a Splitter configuration similar to the "split" package to make it -- possible to express all splitting combinations. In general, we can have -- infix/suffix/prefix/condensing of separators, dropping both leading/trailing -- separators. We can have a single split operation taking the splitter config -- as argument. -- | Split a stream on separator elements determined by a predicate, dropping -- the separator. Separators are not considered part of stream segments on -- either side of it instead they are treated as infixed between two stream -- segments. For example, with @.@ as separator, @"a.b.c"@ would be parsed as -- @["a","b","c"]@. When @.@ is in leading or trailing position it is still -- considered as infixed, treating the first or the last segment as empty. For -- example, @".a."@ would be parsed as @["","a",""]@. This operation is -- opposite of 'intercalate'. -- -- Let's use the following definition for illustration: -- -- > splitBy_ p xs = S.toList $ FL.splitBy p (FL.toList) (S.fromList xs) -- -- >>> splitBy_ (== '.') "" -- [""] -- -- >>> splitBy_ (== '.') "." -- ["",""] -- -- >>> splitBy_ (== '.') ".a" -- > ["","a"] -- -- >>> splitBy_ (== '.') "a." -- > ["a",""] -- -- >>> splitBy_ (== '.') "a.b" -- > ["a","b"] -- -- >>> splitBy_ (== '.') "a..b" -- > ["a","","b"] -- -- This can be considered as an n-fold version of 'break' where we apply -- 'break' successively on the input stream, dropping the first element -- of the second segment after each break. -- -- @since 0.7.0 {-# INLINE splitBy #-} splitBy :: (IsStream t, Monad m) => (a -> Bool) -> Fold m a b -> t m a -> t m b splitBy predicate f m = D.fromStreamD $ D.splitBy predicate f (D.toStreamD m) -- | Like 'splitBy' but the separator is treated as part of the previous -- stream segment (suffix). Therefore, when the separator is in trailing -- position, no empty segment is considered to follow it. For example, @"a.b."@ -- would be parsed as @["a","b"]@ instead of @["a","b",""]@ as in the case of -- 'splitBy'. -- -- > splitSuffixBy_ p xs = S.toList $ FL.splitSuffixBy p (FL.toList) (S.fromList xs) -- -- >>> splitSuffixBy_ (== '.') "" -- [] -- -- >>> splitSuffixBy_ (== '.') "." -- [""] -- -- >>> splitSuffixBy_ (== '.') "a" -- ["a"] -- -- >>> splitSuffixBy_ (== '.') ".a" -- > ["","a"] -- -- >>> splitSuffixBy_ (== '.') "a." -- > ["a"] -- -- >>> splitSuffixBy_ (== '.') "a.b" -- > ["a","b"] -- -- >>> splitSuffixBy_ (== '.') "a.b." -- > ["a","b"] -- -- >>> splitSuffixBy_ (== '.') "a..b.." -- > ["a","","b",""] -- -- > lines = splitSuffixBy (== '\n') -- -- This can be considered as an n-fold version of 'breakPost' where we apply -- 'breakPost' successively on the input stream, dropping the first element -- of the second segment after each break. -- -- @since 0.7.0 {-# INLINE splitSuffixBy #-} splitSuffixBy :: (IsStream t, Monad m) => (a -> Bool) -> Fold m a b -> t m a -> t m b splitSuffixBy predicate f m = D.fromStreamD $ D.splitSuffixBy predicate f (D.toStreamD m) -- | Like 'splitBy' but ignores repeated separators or separators in leading -- or trailing position. Therefore, @"..a..b.."@ would be parsed as -- @["a","b"]@. In other words, it treats the input like words separated by -- whitespace elements determined by the predicate. -- -- > wordsBy' p xs = S.toList $ FL.wordsBy p (FL.toList) (S.fromList xs) -- -- >>> wordsBy' (== ',') "" -- > [] -- -- >>> wordsBy' (== ',') "," -- > [] -- -- >>> wordsBy' (== ',') ",a,,b," -- > ["a","b"] -- -- > words = wordsBy isSpace -- -- @since 0.7.0 {-# INLINE wordsBy #-} wordsBy :: (IsStream t, Monad m) => (a -> Bool) -> Fold m a b -> t m a -> t m b wordsBy predicate f m = D.fromStreamD $ D.wordsBy predicate f (D.toStreamD m) -- XXX we should express this using the Splitter config. -- -- We can get splitSuffixBy' by appending the suffix to the output segments -- produced by splitSuffixBy. However, it may add an additional suffix if the last -- fragment did not have a suffix in the first place. -- | Like 'splitSuffixBy' but keeps the suffix in the splits. -- -- > splitSuffixBy'_ p xs = S.toList $ FL.splitSuffixBy' p (FL.toList) (S.fromList xs) -- -- >>> splitSuffixBy'_ (== '.') "" -- [] -- -- >>> splitSuffixBy'_ (== '.') "." -- ["."] -- -- >>> splitSuffixBy'_ (== '.') "a" -- ["a"] -- -- >>> splitSuffixBy'_ (== '.') ".a" -- > [".","a"] -- -- >>> splitSuffixBy'_ (== '.') "a." -- > ["a."] -- -- >>> splitSuffixBy'_ (== '.') "a.b" -- > ["a.","b"] -- -- >>> splitSuffixBy'_ (== '.') "a.b." -- > ["a.","b."] -- -- >>> splitSuffixBy'_ (== '.') "a..b.." -- > ["a.",".","b.","."] -- -- This can be considered as an n-fold version of 'breakPost' where we apply -- 'breakPost' successively on the input stream. -- -- @since 0.7.0 {-# INLINE splitSuffixBy' #-} splitSuffixBy' :: (IsStream t, Monad m) => (a -> Bool) -> Fold m a b -> t m a -> t m b splitSuffixBy' predicate f m = D.fromStreamD $ D.splitSuffixBy' predicate f (D.toStreamD m) ------------------------------------------------------------------------------ -- Split on a delimiter sequence ------------------------------------------------------------------------------ -- Int list examples for splitOn: -- -- >>> splitList [] [1,2,3,3,4] -- > [[1],[2],[3],[3],[4]] -- -- >>> splitList [5] [1,2,3,3,4] -- > [[1,2,3,3,4]] -- -- >>> splitList [1] [1,2,3,3,4] -- > [[],[2,3,3,4]] -- -- >>> splitList [4] [1,2,3,3,4] -- > [[1,2,3,3],[]] -- -- >>> splitList [2] [1,2,3,3,4] -- > [[1],[3,3,4]] -- -- >>> splitList [3] [1,2,3,3,4] -- > [[1,2],[],[4]] -- -- >>> splitList [3,3] [1,2,3,3,4] -- > [[1,2],[4]] -- -- >>> splitList [1,2,3,3,4] [1,2,3,3,4] -- > [[],[]] -- | Split the stream on both sides of a separator sequence, dropping the -- separator. -- -- For illustration, let's define a function that operates on pure lists: -- -- @ -- splitOn_ pat xs = S.toList $ FL.splitOn (A.fromList pat) (FL.toList) (S.fromList xs) -- @ -- -- >>> splitOn_ "" "hello" -- > ["h","e","l","l","o"] -- -- >>> splitOn_ "hello" "" -- > [""] -- -- >>> splitOn_ "hello" "hello" -- > ["",""] -- -- >>> splitOn_ "x" "hello" -- > ["hello"] -- -- >>> splitOn_ "h" "hello" -- > ["","ello"] -- -- >>> splitOn_ "o" "hello" -- > ["hell",""] -- -- >>> splitOn_ "e" "hello" -- > ["h","llo"] -- -- >>> splitOn_ "l" "hello" -- > ["he","","o"] -- -- >>> splitOn_ "ll" "hello" -- > ["he","o"] -- -- 'splitOn' is an inverse of 'intercalate'. The following law always holds: -- -- > intercalate . splitOn == id -- -- The following law holds when the separator is non-empty and contains none of -- the elements present in the input lists: -- -- > splitOn . intercalate == id -- -- The following law always holds: -- -- > concat . splitOn . intercalate == concat -- -- @since 0.7.0 {-# INLINE splitOn #-} splitOn :: (IsStream t, MonadIO m, Storable a, Enum a, Eq a) => Array a -> Fold m a b -> t m a -> t m b splitOn patt f m = D.fromStreamD $ D.splitOn patt f (D.toStreamD m) {- -- This can be implemented easily using Rabin Karp -- | Split on any one of the given patterns. {-# INLINE splitOnAny #-} splitOnAny :: (IsStream t, Monad m, Storable a, Integral a) => [Array a] -> Fold m a b -> t m a -> t m b splitOnAny subseq f m = undefined -- D.fromStreamD $ D.splitOnAny f subseq (D.toStreamD m) -} -- | Like 'splitSuffixBy' but the separator is a sequence of elements, instead -- of a predicate for a single element. -- -- > splitSuffixOn_ pat xs = S.toList $ FL.splitSuffixOn (A.fromList pat) (FL.toList) (S.fromList xs) -- -- >>> splitSuffixOn_ "." "" -- [""] -- -- >>> splitSuffixOn_ "." "." -- [""] -- -- >>> splitSuffixOn_ "." "a" -- ["a"] -- -- >>> splitSuffixOn_ "." ".a" -- > ["","a"] -- -- >>> splitSuffixOn_ "." "a." -- > ["a"] -- -- >>> splitSuffixOn_ "." "a.b" -- > ["a","b"] -- -- >>> splitSuffixOn_ "." "a.b." -- > ["a","b"] -- -- >>> splitSuffixOn_ "." "a..b.." -- > ["a","","b",""] -- -- > lines = splitSuffixOn "\n" -- -- @since 0.7.0 {-# INLINE splitSuffixOn #-} splitSuffixOn :: (IsStream t, MonadIO m, Storable a, Enum a, Eq a) => Array a -> Fold m a b -> t m a -> t m b splitSuffixOn patt f m = D.fromStreamD $ D.splitSuffixOn False patt f (D.toStreamD m) {- -- | Like 'splitOn' but drops any empty splits. -- {-# INLINE wordsOn #-} wordsOn :: (IsStream t, Monad m, Storable a, Eq a) => Array a -> Fold m a b -> t m a -> t m b wordsOn subseq f m = undefined -- D.fromStreamD $ D.wordsOn f subseq (D.toStreamD m) -} -- XXX use a non-monadic intersperse to remove the MonadAsync constraint. -- -- | Like 'splitOn' but splits the separator as well, as an infix token. -- -- > splitOn'_ pat xs = S.toList $ FL.splitOn' (A.fromList pat) (FL.toList) (S.fromList xs) -- -- >>> splitOn'_ "" "hello" -- > ["h","","e","","l","","l","","o"] -- -- >>> splitOn'_ "hello" "" -- > [""] -- -- >>> splitOn'_ "hello" "hello" -- > ["","hello",""] -- -- >>> splitOn'_ "x" "hello" -- > ["hello"] -- -- >>> splitOn'_ "h" "hello" -- > ["","h","ello"] -- -- >>> splitOn'_ "o" "hello" -- > ["hell","o",""] -- -- >>> splitOn'_ "e" "hello" -- > ["h","e","llo"] -- -- >>> splitOn'_ "l" "hello" -- > ["he","l","","l","o"] -- -- >>> splitOn'_ "ll" "hello" -- > ["he","ll","o"] -- -- @since 0.7.0 {-# INLINE splitOn' #-} splitOn' :: (IsStream t, MonadAsync m, Storable a, Enum a, Eq a) => Array a -> Fold m a b -> t m a -> t m b splitOn' patt f m = S.intersperseM (foldl' f (A.read patt)) $ splitOn patt f m -- | Like 'splitSuffixOn' but keeps the suffix intact in the splits. -- -- > splitSuffixOn'_ pat xs = S.toList $ FL.splitSuffixOn' (A.fromList pat) (FL.toList) (S.fromList xs) -- -- >>> splitSuffixOn'_ "." "" -- [""] -- -- >>> splitSuffixOn'_ "." "." -- ["."] -- -- >>> splitSuffixOn'_ "." "a" -- ["a"] -- -- >>> splitSuffixOn'_ "." ".a" -- > [".","a"] -- -- >>> splitSuffixOn'_ "." "a." -- > ["a."] -- -- >>> splitSuffixOn'_ "." "a.b" -- > ["a.","b"] -- -- >>> splitSuffixOn'_ "." "a.b." -- > ["a.","b."] -- -- >>> splitSuffixOn'_ "." "a..b.." -- > ["a.",".","b.","."] -- -- @since 0.7.0 {-# INLINE splitSuffixOn' #-} splitSuffixOn' :: (IsStream t, MonadIO m, Storable a, Enum a, Eq a) => Array a -> Fold m a b -> t m a -> t m b splitSuffixOn' patt f m = D.fromStreamD $ D.splitSuffixOn True patt f (D.toStreamD m) {- -- This can be implemented easily using Rabin Karp -- | Split post any one of the given patterns. {-# INLINE splitSuffixOnAny #-} splitSuffixOnAny :: (IsStream t, Monad m, Storable a, Integral a) => [Array a] -> Fold m a b -> t m a -> t m b splitSuffixOnAny subseq f m = undefined -- D.fromStreamD $ D.splitPostAny f subseq (D.toStreamD m) -} ------------------------------------------------------------------------------ -- Reorder in sequence ------------------------------------------------------------------------------ {- -- Buffer until the next element in sequence arrives. The function argument -- determines the difference in sequence numbers. This could be useful in -- implementing sequenced streams, for example, TCP reassembly. {-# INLINE reassembleBy #-} reassembleBy :: (IsStream t, Monad m) => Fold m a b -> (a -> a -> Int) -> t m a -> t m b reassembleBy = undefined -} ------------------------------------------------------------------------------ -- Distributing ------------------------------------------------------------------------------ -- -- | Distribute one copy of the stream to each fold and zip the results. -- -- @ -- |-------Fold m a b--------| -- ---stream m a---| |---m (b,c) -- |-------Fold m a c--------| -- @ -- >>> FL.foldl' (FL.tee FL.sum FL.length) (S.enumerateFromTo 1.0 100.0) -- (5050.0,100) -- -- @since 0.7.0 {-# INLINE tee #-} tee :: Monad m => Fold m a b -> Fold m a c -> Fold m a (b,c) tee f1 f2 = (,) <$> f1 <*> f2 {-# INLINE foldNil #-} foldNil :: Monad m => Fold m a [b] foldNil = Fold step begin done where begin = return [] step _ _ = return [] done = return {-# INLINE foldCons #-} foldCons :: Monad m => Fold m a b -> Fold m a [b] -> Fold m a [b] foldCons (Fold stepL beginL doneL) (Fold stepR beginR doneR) = Fold step begin done where begin = Tuple' <$> beginL <*> beginR step (Tuple' xL xR) a = Tuple' <$> stepL xL a <*> stepR xR a done (Tuple' xL xR) = (:) <$> (doneL xL) <*> (doneR xR) -- XXX use "List" instead of "[]"?, use Array for output to scale it to a large -- number of consumers? -- -- | Distribute one copy of the stream to each fold and collect the results in -- a container. -- -- @ -- -- |-------Fold m a b--------| -- ---stream m a---| |---m [b] -- |-------Fold m a b--------| -- | | -- ... -- @ -- -- >>> FL.foldl' (FL.distribute [FL.sum, FL.length]) (S.enumerateFromTo 1 5) -- [15,5] -- -- This is the consumer side dual of the producer side 'sequence' operation. -- -- @since 0.7.0 {-# INLINE distribute #-} distribute :: Monad m => [Fold m a b] -> Fold m a [b] distribute [] = foldNil distribute (x:xs) = foldCons x (distribute xs) ------------------------------------------------------------------------------ -- Partitioning ------------------------------------------------------------------------------ -- -- | Partition the input over two folds using an 'Either' partitioning -- predicate. -- -- @ -- -- |-------Fold b x--------| -- -----stream m a --> (Either b c)----| |----(x,y) -- |-------Fold c y--------| -- @ -- -- Send input to either fold randomly: -- -- >>> import System.Random (randomIO) -- >>> randomly a = randomIO >>= \x -> return $ if x then Left a else Right a -- >>> FL.foldl' (FL.partitionByM randomly FL.length FL.length) (S.enumerateFromTo 1 100) -- (59,41) -- -- Send input to the two folds in a proportion of 2:1: -- -- @ -- import Data.IORef (newIORef, readIORef, writeIORef) -- proportionately m n = do -- ref <- newIORef $ cycle $ concat [replicate m Left, replicate n Right] -- return $ \\a -> do -- r <- readIORef ref -- writeIORef ref $ tail r -- return $ head r a -- -- main = do -- f <- proportionately 2 1 -- r <- FL.foldl' (FL.partitionByM f FL.length FL.length) (S.enumerateFromTo (1 :: Int) 100) -- print r -- @ -- @ -- (67,33) -- @ -- -- This is the consumer side dual of the producer side 'mergeBy' operation. -- -- @since 0.7.0 {-# INLINE partitionByM #-} partitionByM :: Monad m => (a -> m (Either b c)) -> Fold m b x -> Fold m c y -> Fold m a (x, y) partitionByM f (Fold stepL beginL doneL) (Fold stepR beginR doneR) = Fold step begin done where begin = Tuple' <$> beginL <*> beginR step (Tuple' xL xR) a = do r <- f a case r of Left b -> Tuple' <$> stepL xL b <*> return xR Right c -> Tuple' <$> return xL <*> stepR xR c done (Tuple' xL xR) = (,) <$> doneL xL <*> doneR xR -- Note: we could use (a -> Bool) instead of (a -> Either b c), but the latter -- makes the signature clearer as to which case belongs to which fold. -- XXX need to check the performance in both cases. -- | Same as 'partitionByM' but with a pure partition function. -- -- Count even and odd numbers in a stream: -- -- @ -- >>> let f = FL.partitionBy (\\n -> if even n then Left n else Right n) -- (fmap (("Even " ++) . show) FL.length) -- (fmap (("Odd " ++) . show) FL.length) -- in FL.foldl' f (S.enumerateFromTo 1 100) -- ("Even 50","Odd 50") -- @ -- -- @since 0.7.0 {-# INLINE partitionBy #-} partitionBy :: Monad m => (a -> Either b c) -> Fold m b x -> Fold m c y -> Fold m a (x, y) partitionBy f = partitionByM (return . f) -- | Compose two folds such that the combined fold accepts a stream of 'Either' -- and routes the 'Left' values to the first fold and 'Right' values to the -- second fold. -- -- > partition = partitionBy id -- -- @since 0.7.0 {-# INLINE partition #-} partition :: Monad m => Fold m b x -> Fold m c y -> Fold m (Either b c) (x, y) partition = partitionBy id {- -- | Send one item to each fold in a round-robin fashion. This is the consumer -- side dual of producer side 'mergeN' operation. -- -- partitionN :: Monad m => [Fold m a b] -> Fold m a [b] -- partitionN fs = Fold step begin done -} -- Demultiplex an input element into a number of typed variants. We want to -- statically restrict the target values within a set of predefined types, an -- enumeration of a GADT. We also want to make sure that the Map contains only -- those types and the full set of those types. Instead of Map it should -- probably be a lookup-table using an array and not in GC memory. -- -- This is the consumer side dual of the producer side 'mux' operation (XXX to -- be implemented). -- | Split the input stream based on a key field and fold each split using a -- specific fold collecting the results in a map from the keys to the results. -- Useful for cases like protocol handlers to handle different type of packets -- using different handlers. -- -- @ -- -- |-------Fold m a b -- -----stream m a-----Map-----| -- |-------Fold m a b -- | -- ... -- @ -- -- @since 0.7.0 {-# INLINE demuxWith #-} demuxWith :: (Monad m, Ord k) => (a -> k) -> Map k (Fold m a b) -> Fold m a (Map k b) demuxWith f kv = Fold step initial extract where initial = return kv step mp a = -- XXX should we raise an exception in Nothing case? -- Ideally we should enforce that it is a total map over k so that look -- up never fails -- XXX we could use a monadic update function for a single lookup and -- update in the map. let k = f a in case Map.lookup k mp of Nothing -> return mp Just (Fold step' acc extract') -> do !r <- acc >>= \x -> step' x a return $ Map.insert k (Fold step' (return r) extract') mp extract = Prelude.mapM (\(Fold _ acc e) -> acc >>= e) -- | Fold a stream of key value pairs using a map of specific folds for each -- key into a map from keys to the results of fold outputs of the corresponding -- values. -- -- @ -- > let table = Data.Map.fromList [(\"SUM", FL.sum), (\"PRODUCT", FL.product)] -- input = S.fromList [(\"SUM",1),(\"PRODUCT",2),(\"SUM",3),(\"PRODUCT",4)] -- in FL.foldl' (FL.demux table) input -- One 1 -- Two 2 -- @ -- -- @since 0.7.0 {-# INLINE demux #-} demux :: (Monad m, Ord k) => Map k (Fold m a b) -> Fold m (k, a) (Map k b) demux fs = demuxWith fst (Map.map (lmap snd) fs) -- | Split the input stream based on a key field and fold each split using a -- specific fold without collecting the results. Useful for cases like protocol -- handlers to handle different type of packets. -- -- @ -- -- |-------Fold m a () -- -----stream m a-----Map-----| -- |-------Fold m a () -- | -- ... -- @ -- -- -- @since 0.7.0 -- demuxWith_ can be slightly faster than demuxWith because we do not need to -- update the Map in this case. This may be significant only if the map is -- large. {-# INLINE demuxWith_ #-} demuxWith_ :: (Monad m, Ord k) => (a -> k) -> Map k (Fold m a b) -> Fold m a () demuxWith_ f kv = Fold step initial extract where initial = do Prelude.mapM (\(Fold s i e) -> i >>= \r -> return (Fold s (return r) e)) kv step mp a = -- XXX should we raise an exception in Nothing case? -- Ideally we should enforce that it is a total map over k so that look -- up never fails case Map.lookup (f a) mp of Nothing -> return mp Just (Fold step' acc _) -> do _ <- acc >>= \x -> step' x a return mp extract mp = Prelude.mapM (\(Fold _ acc e) -> acc >>= e) mp >> return () -- | Given a stream of key value pairs and a map from keys to folds, fold the -- values for each key using the corresponding folds, discarding the outputs. -- -- @ -- > let prn = FL.drainBy print -- > let table = Data.Map.fromList [(\"ONE", prn), (\"TWO", prn)] -- input = S.fromList [(\"ONE",1),(\"TWO",2)] -- in FL.foldl' (FL.demux_ table) input -- One 1 -- Two 2 -- @ -- -- @since 0.7.0 {-# INLINE demux_ #-} demux_ :: (Monad m, Ord k) => Map k (Fold m a ()) -> Fold m (k, a) () demux_ fs = demuxWith_ fst (Map.map (lmap snd) fs) -- XXX instead of a Map we could yield the results as a pure stream as they -- complete. We could then concatMap the fold results to implement the -- windowing combinators. -- -- | Split the input stream based on a key field and fold each split using the -- given fold. Useful for map/reduce, bucketizing the input in different bins -- or for generating histograms. -- -- @ -- > let input = S.fromList [(\"ONE",1),(\"ONE",1.1),(\"TWO",2), (\"TWO",2.2)] -- in FL.foldl' (FL.classify FL.toListRev) input -- fromList [(\"ONE",[1.1,1.0]),(\"TWO",[2.2,2.0])] -- @ -- -- @since 0.7.0 {-# INLINE classifyWith #-} classifyWith :: (Monad m, Ord k) => (a -> k) -> Fold m a b -> Fold m a (Map k b) classifyWith f (Fold step initial extract) = Fold step' initial' extract' where initial' = return Map.empty step' kv a = let k = f a in case Map.lookup k kv of Nothing -> do x <- initial r <- step x a return $ Map.insert k r kv Just x -> do r <- step x a return $ Map.insert k r kv extract' = Prelude.mapM extract -- | Given an input stream of key value pairs and a fold for values, fold all -- the values belonging to each key. Useful for map/reduce, bucketizing the -- input in different bins or for generating histograms. -- -- @ -- > let input = S.fromList [(\"ONE",1),(\"ONE",1.1),(\"TWO",2), (\"TWO",2.2)] -- in FL.foldl' (FL.classify FL.toListRev) input -- fromList [(\"ONE",[1.1,1.0]),(\"TWO",[2.2,2.0])] -- @ -- -- Same as: -- -- > classify fld = classifyWith fst (lmap snd fld) -- -- @since 0.7.0 {-# INLINE classify #-} classify :: (Monad m, Ord k) => Fold m a b -> Fold m (k, a) (Map k b) classify fld = classifyWith fst (lmap snd fld) ------------------------------------------------------------------------------ -- Unzipping ------------------------------------------------------------------------------ -- -- | Like 'unzipWith' but with a monadic splitter function. -- -- @since 0.7.0 {-# INLINE unzipWithM #-} unzipWithM :: Monad m => (a -> m (b,c)) -> Fold m b x -> Fold m c y -> Fold m a (x,y) unzipWithM f (Fold stepL beginL doneL) (Fold stepR beginR doneR) = Fold step begin done where step (Tuple' xL xR) a = do (b,c) <- f a Tuple' <$> stepL xL b <*> stepR xR c begin = Tuple' <$> beginL <*> beginR done (Tuple' xL xR) = (,) <$> doneL xL <*> doneR xR -- | Split elements in the input stream into two parts using a pure splitter -- function, direct each part to a different fold and zip the results. -- -- @since 0.7.0 {-# INLINE unzipWith #-} unzipWith :: Monad m => (a -> (b,c)) -> Fold m b x -> Fold m c y -> Fold m a (x,y) unzipWith f = unzipWithM (return . f) -- | Send the elements of tuples in a stream of tuples through two different -- folds. -- -- @ -- -- |-------Fold a x--------| -- -----Stream m x----(a,b)--| |----m (x,y) -- |-------Fold b y--------| -- -- @ -- -- This is the consumer side dual of the producer side 'zip' operation. -- -- @since 0.7.0 {-# INLINE unzip #-} unzip :: Monad m => Fold m a x -> Fold m b y -> Fold m (a,b) (x,y) unzip = unzipWith id ------------------------------------------------------------------------------ -- Nesting ------------------------------------------------------------------------------ -- -- | Modify the fold such that when the fold is done, instead of returning the -- accumulator, it returns a fold. The returned fold starts from where we left -- i.e. it uses the last accumulator value as the initial value of the -- accumulator. Thus we can resume the fold later and feed it more input. -- -- >> do -- > more <- FL.foldl (FL.duplicate FL.sum) (S.enumerateFromTo 1 10) -- > evenMore <- FL.foldl (FL.duplicate more) (S.enumerateFromTo 11 20) -- > FL.foldl evenMore (S.enumerateFromTo 21 30) -- > 465 -- -- @since 0.7.0 {-# INLINABLE duplicate #-} duplicate :: Applicative m => Fold m a b -> Fold m a (Fold m a b) duplicate (Fold step begin done) = Fold step begin (\x -> pure (Fold step (pure x) done)) {- -- All the stream flattening transformations can also be applied to a fold -- input stream. -- | This can be used to apply all the stream generation operations on folds. lconcatMap ::(IsStream t, Monad m) => (a -> t m b) -> Fold m b c -> Fold m a c lconcatMap s f1 f2 = undefined -} -- All the grouping transformation that we apply to a stream can also be -- applied to a fold input stream. {- -- | Group the input stream into groups of elements between @low@ and @high@. -- Collection starts in chunks of @low@ and then keeps doubling until we reach -- @high@. Each chunk is folded using the provided fold function. -- -- This could be useful, for example, when we are folding a stream of unknown -- size to a stream of arrays and we want to minimize the number of -- allocations. -- -- @ -- -- XXX we should be able to implement it with parsers/terminating folds. -- {-# INLINE lchunksInRange #-} lchunksInRange :: Monad m => Int -> Int -> Fold m a b -> Fold m b c -> Fold m a c lchunksInRange low high (Fold step1 initial1 extract1) (Fold step2 initial2 extract2) = undefined -} -- | Group the input stream into groups of @n@ elements each and then fold each -- group using the provided fold function. -- -- @ -- -- -----Fold m a b----|-Fold n a c-|-Fold n a c-|-...-|----Fold m a c -- -- @ -- {-# INLINE lchunksOf #-} lchunksOf :: Monad m => Int -> Fold m a b -> Fold m b c -> Fold m a c lchunksOf n (Fold step1 initial1 extract1) (Fold step2 initial2 extract2) = Fold step' initial' extract' where initial' = (Tuple3' 0) <$> initial1 <*> initial2 step' (Tuple3' i r1 r2) a = do if i < n then do res <- step1 r1 a return $ Tuple3' (i + 1) res r2 else do res <- extract1 r1 acc2 <- step2 r2 res i1 <- initial1 acc1 <- step1 i1 a return $ Tuple3' 1 acc1 acc2 extract' (Tuple3' _ _ r) = extract2 r -- | Group the input stream into windows of n second each and then fold each -- group using the provided fold function. -- -- For example, we can copy and distribute a stream to multiple folds where -- each fold can group the input differently e.g. by one second, one minute and -- one hour windows respectively and fold each resulting stream of folds. -- -- @ -- -- -----Fold m a b----|-Fold n a c-|-Fold n a c-|-...-|----Fold m a c -- -- @ {-# INLINE lsessionsOf #-} lsessionsOf :: MonadAsync m => Double -> Fold m a b -> Fold m b c -> Fold m a c lsessionsOf n (Fold step1 initial1 extract1) (Fold step2 initial2 extract2) = Fold step' initial' extract' where -- XXX MVar may be expensive we need a cheaper synch mechanism here initial' = do i1 <- initial1 i2 <- initial2 mv1 <- liftIO $ newMVar i1 mv2 <- liftIO $ newMVar (Right i2) t <- control $ \run -> mask $ \restore -> do tid <- forkIO $ catch (restore $ void $ run (timerThread mv1 mv2)) (handleChildException mv2) run (return tid) return $ Tuple3' t mv1 mv2 step' acc@(Tuple3' _ mv1 _) a = do r1 <- liftIO $ takeMVar mv1 res <- step1 r1 a liftIO $ putMVar mv1 res return acc extract' (Tuple3' tid _ mv2) = do r2 <- liftIO $ takeMVar mv2 liftIO $ killThread tid case r2 of Left e -> throwM e Right x -> extract2 x timerThread mv1 mv2 = do liftIO $ threadDelay (round $ n * 1000000) r1 <- liftIO $ takeMVar mv1 i1 <- initial1 liftIO $ putMVar mv1 i1 res1 <- extract1 r1 r2 <- liftIO $ takeMVar mv2 res <- case r2 of Left _ -> return r2 Right x -> fmap Right $ step2 x res1 liftIO $ putMVar mv2 res timerThread mv1 mv2 handleChildException :: MVar (Either SomeException a) -> SomeException -> IO () handleChildException mv2 e = do r2 <- takeMVar mv2 let r = case r2 of Left _ -> r2 Right _ -> Left e putMVar mv2 r ------------------------------------------------------------------------------ -- Windowed classification ------------------------------------------------------------------------------ -- We divide the stream into windows or chunks in space or time and 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 can be split into -- windows by size or by using a split predicate on the elements in the stream. -- For example, when we receive a closing flag, we can close the window. -- -- A "chunk" is a space window and a "session" is a time window. Are there any -- other better short words to describe them. An alternative is to use -- "swindow" and "twindow". Another word for "session" could be "spell". -- -- TODO: To mark the position in space or time we can have Indexed or -- TimeStamped types. That can make it easy to deal with the position indices -- or timestamps. ------------------------------------------------------------------------------ -- Keyed Sliding Windows ------------------------------------------------------------------------------ {- {-# INLINABLE classifySlidingChunks #-} classifySlidingChunks :: (IsStream t, MonadAsync m, Ord k) => Int -- ^ window size -> Int -- ^ window slide -> Fold m a b -- ^ Fold to be applied to window events -> t m (k, a, Bool) -- ^ window key, data, close event -> t m (k, b) classifySlidingChunks wsize wslide (Fold step initial extract) str = undefined -- XXX Another variant could be to slide the window on an event, e.g. in TCP we -- slide the send window when an ack is received and we slide the receive -- window when a sequence is complete. Sliding is stateful in case of TCP, -- sliding releases the send buffer or makes data available to the user from -- the receive buffer. {-# INLINABLE classifySlidingSessions #-} classifySlidingSessions :: (IsStream t, MonadAsync m, Ord k) => Double -- ^ timer tick in seconds -> Double -- ^ time window size -> Double -- ^ window slide -> Fold m a b -- ^ Fold to be applied to window events -> t m (k, a, Bool, AbsTime) -- ^ window key, data, close flag, timestamp -> t m (k, b) classifySlidingSessions tick interval slide (Fold step initial extract) str = undefined -} ------------------------------------------------------------------------------ -- Sliding Window Buffers ------------------------------------------------------------------------------ -- These buffered versions could be faster than concurrent incremental folds of -- all overlapping windows as in many cases we may not need all the values to -- compute the fold, we can just compute the result using the old value and new -- value. However, we may need the buffer once in a while, for example for -- string search we usually compute the hash incrementally but when the hash -- matches the hash of the pattern we need to compare the whole string. -- -- XXX we should be able to implement sequence based splitting combinators -- using this combinator. {- -- | Buffer n elements of the input in a ring buffer. When t new elements are -- collected, slide the window to remove the same number of oldest elements, -- insert the new elements, and apply an incremental fold on the sliding -- window, supplying the outgoing elements, the new ring buffer as arguments. slidingChunkBuffer :: (IsStream t, Monad m, Ord a, Storable a) => Int -- window size -> Int -- window slide -> Fold m (Ring a, Array a) b -> t m a -> t m b slidingChunkBuffer = undefined -- Buffer n seconds worth of stream elements of the input in a radix tree. -- Every t seconds, remove the items that are older than n seconds, and apply -- an incremental fold on the sliding window, supplying the outgoing elements, -- and the new radix tree buffer as arguments. slidingSessionBuffer :: (IsStream t, Monad m, Ord a, Storable a) => Int -- window size -> Int -- tick size -> Fold m (RTree a, Array a) b -> t m a -> t m b slidingSessionBuffer = undefined -} ------------------------------------------------------------------------------ -- Keyed Session Windows ------------------------------------------------------------------------------ {- -- | Keyed variable size space windows. Close the window if we do not receive a -- window event in the next "spaceout" elements. {-# INLINABLE classifyChunksBy #-} classifyChunksBy :: (IsStream t, MonadAsync m, Ord k) => Int -- ^ window spaceout (spread) -> Bool -- ^ reset the spaceout when a chunk window element is received -> Fold m a b -- ^ Fold to be applied to chunk window elements -> t m (k, a, Bool) -- ^ chunk key, data, last element -> t m (k, b) classifyChunksBy spanout reset (Fold step initial extract) str = undefined -- | Like 'classifyChunksOf' but the chunk size is reset if an element is -- received within the chunk size window. The chunk gets closed only if no -- element is received within the chunk window. -- {-# INLINABLE classifyKeepAliveChunks #-} classifyKeepAliveChunks :: (IsStream t, MonadAsync m, Ord k) => Int -- ^ window spaceout (spread) -> Fold m a b -- ^ Fold to be applied to chunk window elements -> t m (k, a, Bool) -- ^ chunk key, data, last element -> t m (k, b) classifyKeepAliveChunks spanout = classifyChunksBy spanout True -} -- | @classifySessionsBy tick timeout reset f stream@ groups together all input -- stream elements that belong to the same session. @timeout@ is the maximum -- lifetime of a session in seconds. All elements belonging to a session are -- purged after this duration. If "reset" is 'Ture' then the timeout is reset -- after every event received in the session. Session duration is measured -- using the timestamp of the first element seen for that session. To detect -- session timeouts, a monotonic event time clock is maintained using the -- timestamps seen in the inputs and a timer with a tick duration specified by -- @tick@. -- -- @session key@ is a key that uniquely identifies the session for the given -- element, @timestamp@ characterizes the time when the input element was -- generated, this is an absolute time measured from some @Epoch@. @session -- close@ is a boolean indicating whether this element marks the closing of the -- session. When an input element with @session close@ set to @True@ is seen -- the session is purged immediately. -- -- All the input elements belonging to a session are collected using the fold -- @f@. The session key and the fold result are emitted in the output stream -- when the session is purged either via the session close event or via the -- session lifetime timeout. -- -- @since 0.7.0 {-# INLINABLE classifySessionsBy #-} classifySessionsBy :: (IsStream t, MonadAsync m, Ord k) => Double -- ^ timer tick in seconds -> Double -- ^ session timeout -> Bool -- ^ reset the timeout when an event is received -> Fold m a b -- ^ Fold to be applied to session events -> t m (k, a, Bool, AbsTime) -- ^ session key, timestamp, close event, data -> t m (k, b) classifySessionsBy tick timeout reset (Fold step initial extract) str = S.concatMap (\(Tuple4' _ _ _ s) -> s) $ S.scanlM' sstep szero stream where timeoutMs = toRelTime (round (timeout * 1000) :: MilliSecond64) tickMs = toRelTime (round (tick * 1000) :: MilliSecond64) szero = Tuple4' (toAbsTime (0 :: MilliSecond64)) H.empty Map.empty S.nil -- Got a new stream input element sstep (Tuple4' evTime hp mp _) (Just (key, a, closing, ts)) = -- XXX we should use a heap in pinned memory to scale it to a large -- size -- -- deleting a key from the heap is expensive, so we never delete a -- key, we just purge it from the Map and it gets purged from the -- heap on timeout. We just need an extra lookup in the Map when -- the key is purged from the heap, that should not be expensive. -- -- To detect session inactivity we keep a timestamp of the latest event -- in the Map along with the fold result. When we purge the session -- from the heap we match the timestamp in the heap with the timestamp -- in the Map, if the latest timestamp is newer and has not expired we -- reinsert the key in the heap. -- -- XXX if the key is an Int, we can also use an IntMap for slightly -- better performance. -- let accumulate v = do Tuple' _ old <- maybe (initial >>= return . Tuple' ts) return v new <- step old a return $ Tuple' ts new in if closing then do let (r, mp') = Map.updateLookupWithKey (\_ _ -> Nothing) key mp Tuple' _ acc <- accumulate r res <- extract acc return $ Tuple4' evTime hp mp' (S.yield (key, res)) else do let r = Map.lookup key mp acc <- accumulate r let mp' = Map.insert key acc mp let hp' = case r of Nothing -> let expiry = addToAbsTime ts timeoutMs in H.insert (Entry expiry key) hp Just _ -> hp -- Event time is maintained as monotonically increasing -- time. If we have lagged behind any of the timestamps -- seen then we increase it to match the latest time seen -- in the timestamps. We also increase it on timer ticks. return $ Tuple4' (max evTime ts) hp' mp' S.nil -- Got a timer tick event -- XXX can we yield the entries without accumulating them? sstep (Tuple4' evTime heap sessions _) Nothing = do (hp', mp', out) <- go heap sessions S.nil return $ Tuple4' curTime hp' mp' out where curTime = addToAbsTime evTime tickMs go hp mp out = do let hres = H.uncons hp case hres of Just (Entry ts key, hp') -> do let duration = diffAbsTime curTime ts if duration >= timeoutMs then do let (r, mp') = Map.updateLookupWithKey (\_ _ -> Nothing) key mp case r of Nothing -> go hp' mp' out Just (Tuple' latestTS acc) -> do let dur = diffAbsTime curTime latestTS if dur >= timeoutMs || not reset then do sess <- extract acc go hp' mp' ((key, sess) `S.cons` out) else -- reset the session timeout let expiry = addToAbsTime latestTS timeoutMs hp'' = H.insert (Entry expiry key) hp' mp'' = Map.insert key (Tuple' latestTS acc) mp' in go hp'' mp'' out else return (hp, mp, out) Nothing -> return (hp, mp, out) -- merge timer events in the stream stream = S.map Just str `parallel` S.repeatM timer timer = do liftIO $ threadDelay (round $ tick * 1000000) return Nothing -- | Like 'classifySessionsOf' but the session is kept alive if an event is -- received within the session window. The session times out and gets closed -- only if no event is received within the specified session window size. -- -- @since 0.7.0 {-# INLINABLE classifyKeepAliveSessions #-} classifyKeepAliveSessions :: (IsStream t, MonadAsync m, Ord k) => Double -- ^ session inactive timeout -> Fold m a b -- ^ Fold to be applied to session payload data -> t m (k, a, Bool, AbsTime) -- ^ session key, data, close flag, timestamp -> t m (k, b) classifyKeepAliveSessions timeout = classifySessionsBy 1 timeout True ------------------------------------------------------------------------------ -- Keyed tumbling windows ------------------------------------------------------------------------------ -- Tumbling windows is a special case of sliding windows where the window slide -- is the same as the window size. Or it can be a special case of session -- windows where the reset flag is set to False. -- XXX instead of using the early termination flag in the stream, we can use an -- early terminating fold instead. {- -- | Split the stream into fixed size chunks of specified size. Within each -- such chunk fold the elements in buckets identified by the keys. A particular -- bucket fold can be terminated early if a closing flag is encountered in an -- element for that key. -- -- @since 0.7.0 {-# INLINABLE classifyChunksOf #-} classifyChunksOf :: (IsStream t, MonadAsync m, Ord k) => Int -- ^ window size -> Fold m a b -- ^ Fold to be applied to window events -> t m (k, a, Bool) -- ^ window key, data, close event -> t m (k, b) classifyChunksOf wsize = classifyChunksBy wsize False -} -- | Split the stream into fixed size time windows of specified interval in -- seconds. Within each such window, fold the elements in buckets identified by -- the keys. A particular bucket fold can be terminated early if a closing flag -- is encountered in an element for that key. Once a fold is terminated the key -- and value for that bucket are emitted in the output stream. -- -- Session @timestamp@ in the input stream is an absolute time from some epoch, -- characterizing the time when the input element was generated. To detect -- session window end, a monotonic event time clock is maintained synced with -- the timestamps with a clock resolution of 1 second. -- -- @since 0.7.0 {-# INLINABLE classifySessionsOf #-} classifySessionsOf :: (IsStream t, MonadAsync m, Ord k) => Double -- ^ time window size -> Fold m a b -- ^ Fold to be applied to window events -> t m (k, a, Bool, AbsTime) -- ^ window key, data, close flag, timestamp -> t m (k, b) classifySessionsOf interval = classifySessionsBy 1 interval False -}