streaming-bytestring-0.1.7: Fast, effectful byte streams.

Copyright(c) Don Stewart 2006
(c) Duncan Coutts 2006-2011
(c) Michael Thompson 2015
LicenseBSD-style
Maintainerwhat_is_it_to_do_anything@yahoo.com
Stabilityexperimental
Portabilityportable
Safe HaskellNone
LanguageHaskell2010

Streaming.ByteString

Contents

Description

See the simple examples of use here and the ghci examples especially in Streaming.ByteString.Char8. We begin with a slight modification of the documentation to Data.ByteString.Lazy:

A time and space-efficient implementation of effectful byte streams using a stream of packed Word8 arrays, suitable for high performance use, both in terms of large data quantities, or high speed requirements. Streaming ByteStrings are encoded as streams of strict chunks of bytes.

A key feature of streaming ByteStrings is the means to manipulate large or unbounded streams of data without requiring the entire sequence to be resident in memory. To take advantage of this you have to write your functions in a streaming style, e.g. classic pipeline composition. The default I/O chunk size is 32k, which should be good in most circumstances.

Some operations, such as concat, append, and cons, have better complexity than their Data.ByteString equivalents, due to optimisations resulting from the list spine structure. For other operations streaming, like lazy, ByteStrings are usually within a few percent of strict ones.

This module is intended to be imported qualified, to avoid name clashes with Prelude functions. eg.

import qualified Streaming.ByteString as Q

Original GHC implementation by Bryan O'Sullivan. Rewritten to use UArray by Simon Marlow. Rewritten to support slices and use ForeignPtr by David Roundy. Rewritten again and extended by Don Stewart and Duncan Coutts. Lazy variant by Duncan Coutts and Don Stewart. Streaming variant by Michael Thompson, following the ideas of Gabriel Gonzales' pipes-bytestring.

Synopsis

The ByteStream type

data ByteStream m r Source #

A space-efficient representation of a succession of Word8 vectors, supporting many efficient operations.

An effectful ByteStream contains 8-bit bytes, or by using the operations from Streaming.ByteString.Char8 it can be interpreted as containing 8-bit characters.

Instances
MonadTrans ByteStream Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

lift :: Monad m => m a -> ByteStream m a #

MonadBase b m => MonadBase b (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

liftBase :: b α -> ByteStream m α #

Monad m => Monad (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

(>>=) :: ByteStream m a -> (a -> ByteStream m b) -> ByteStream m b #

(>>) :: ByteStream m a -> ByteStream m b -> ByteStream m b #

return :: a -> ByteStream m a #

fail :: String -> ByteStream m a #

Monad m => Functor (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

fmap :: (a -> b) -> ByteStream m a -> ByteStream m b #

(<$) :: a -> ByteStream m b -> ByteStream m a #

Monad m => Applicative (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

pure :: a -> ByteStream m a #

(<*>) :: ByteStream m (a -> b) -> ByteStream m a -> ByteStream m b #

liftA2 :: (a -> b -> c) -> ByteStream m a -> ByteStream m b -> ByteStream m c #

(*>) :: ByteStream m a -> ByteStream m b -> ByteStream m b #

(<*) :: ByteStream m a -> ByteStream m b -> ByteStream m a #

MonadIO m => MonadIO (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

liftIO :: IO a -> ByteStream m a #

MonadThrow m => MonadThrow (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

throwM :: Exception e => e -> ByteStream m a #

MonadCatch m => MonadCatch (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

catch :: Exception e => ByteStream m a -> (e -> ByteStream m a) -> ByteStream m a #

MonadResource m => MonadResource (ByteStream m) Source # 
Instance details

Defined in Streaming.ByteString.Internal

MFunctor ByteStream Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

hoist :: Monad m => (forall a. m a -> n a) -> ByteStream m b -> ByteStream n b #

(m ~ Identity, Show r) => Show (ByteStream m r) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

showsPrec :: Int -> ByteStream m r -> ShowS #

show :: ByteStream m r -> String #

showList :: [ByteStream m r] -> ShowS #

r ~ () => IsString (ByteStream m r) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

fromString :: String -> ByteStream m r #

(Semigroup r, Monad m) => Semigroup (ByteStream m r) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

(<>) :: ByteStream m r -> ByteStream m r -> ByteStream m r #

sconcat :: NonEmpty (ByteStream m r) -> ByteStream m r #

stimes :: Integral b => b -> ByteStream m r -> ByteStream m r #

(Monoid r, Monad m) => Monoid (ByteStream m r) Source # 
Instance details

Defined in Streaming.ByteString.Internal

Methods

mempty :: ByteStream m r #

mappend :: ByteStream m r -> ByteStream m r -> ByteStream m r #

mconcat :: [ByteStream m r] -> ByteStream m r #

type ByteString = ByteStream Source #

Deprecated: Use ByteStream instead.

A type alias for back-compatibility.

Introducing and eliminating ByteStreams

empty :: ByteStream m () Source #

O(1) The empty ByteStream -- i.e. return () Note that ByteStream m w is generally a monoid for monoidal values of w, like ().

singleton :: Monad m => Word8 -> ByteStream m () Source #

O(1) Yield a Word8 as a minimal ByteStream.

pack :: Monad m => Stream (Of Word8) m r -> ByteStream m r Source #

O(n) Convert a monadic stream of individual Word8s into a packed byte stream.

unpack :: Monad m => ByteStream m r -> Stream (Of Word8) m r Source #

O(n) Converts a packed byte stream into a stream of individual bytes.

fromLazy :: Monad m => ByteString -> ByteStream m () Source #

O(c) Transmute a pseudo-pure lazy bytestring to its representation as a monadic stream of chunks.

>>> Q.putStrLn $ Q.fromLazy "hi"
hi
>>> Q.fromLazy "hi"
Chunk "hi" (Empty (()))  -- note: a 'show' instance works in the identity monad
>>> Q.fromLazy $ BL.fromChunks ["here", "are", "some", "chunks"]
Chunk "here" (Chunk "are" (Chunk "some" (Chunk "chunks" (Empty (())))))

toLazy :: Monad m => ByteStream m r -> m (Of ByteString r) Source #

O(n) Convert an effectful byte stream into a single lazy ByteString with the same internal chunk structure, retaining the original return value.

This is the canonical way of breaking streaming (toStrict and the like are far more demonic). Essentially one is dividing the interleaved layers of effects and bytes into one immense layer of effects, followed by the memory of the succession of bytes.

Because one preserves the return value, toLazy is a suitable argument for mapped:

S.mapped Q.toLazy :: Stream (ByteStream m) m r -> Stream (Of L.ByteString) m r
>>> Q.toLazy "hello"
"hello" :> ()
>>> S.toListM $ traverses Q.toLazy $ Q.lines "one\ntwo\nthree\nfour\nfive\n"
["one","two","three","four","five",""]  -- [L.ByteString]

toLazy_ :: Monad m => ByteStream m r -> m ByteString Source #

O(n) Convert an effectful byte stream into a single lazy ByteStream with the same internal chunk structure. See toLazy which preserve connectedness by keeping the return value of the effectful bytestring.

fromChunks :: Monad m => Stream (Of ByteString) m r -> ByteStream m r Source #

O(c) Convert a monadic stream of individual strict ByteString chunks into a byte stream.

toChunks :: Monad m => ByteStream m r -> Stream (Of ByteString) m r Source #

O(c) Convert a byte stream into a stream of individual strict bytestrings. This of course exposes the internal chunk structure.

fromStrict :: ByteString -> ByteStream m () Source #

O(1) Yield a strict ByteString chunk.

toStrict :: Monad m => ByteStream m r -> m (Of ByteString r) Source #

O(n) Convert a monadic byte stream into a single strict ByteString, retaining the return value of the original pair. This operation is for use with mapped.

mapped R.toStrict :: Monad m => Stream (ByteStream m) m r -> Stream (Of ByteString) m r

It is subject to all the objections one makes to Data.ByteString.Lazy toStrict; all of these are devastating.

toStrict_ :: Monad m => ByteStream m () -> m ByteString Source #

O(n) Convert a byte stream into a single strict ByteString.

Note that this is an expensive operation that forces the whole monadic ByteString into memory and then copies all the data. If possible, try to avoid converting back and forth between streaming and strict bytestrings.

effects :: Monad m => ByteStream m r -> m r Source #

Perform the effects contained in an effectful bytestring, ignoring the bytes.

copy :: Monad m => ByteStream m r -> ByteStream (ByteStream m) r Source #

Make the information in a bytestring available to more than one eliminating fold, e.g.

>>> Q.count 'l' $ Q.count 'o' $ Q.copy $ "hello\nworld"
3 :> (2 :> ())
>>> Q.length $ Q.count 'l' $ Q.count 'o' $ Q.copy $ Q.copy "hello\nworld"
11 :> (3 :> (2 :> ()))
>>> runResourceT $ Q.writeFile "hello2.txt" $ Q.writeFile "hello1.txt" $ Q.copy $ "hello\nworld\n"
>>> :! cat hello2.txt
hello
world
>>> :! cat hello1.txt
hello
world

This sort of manipulation could as well be acheived by combining folds - using Control.Foldl for example. But any sort of manipulation can be involved in the fold. Here are a couple of trivial complications involving splitting by lines:

>>> let doubleLines = Q.unlines . maps (<* Q.chunk "\n" ) . Q.lines
>>> let emphasize = Q.unlines . maps (<* Q.chunk "!" ) . Q.lines
>>> runResourceT $ Q.writeFile "hello2.txt" $ emphasize $ Q.writeFile "hello1.txt" $ doubleLines $ Q.copy $ "hello\nworld"
>>> :! cat hello2.txt
hello!
world!
>>> :! cat hello1.txt
hello

world

As with the parallel operations in Streaming.Prelude, we have

Q.effects . Q.copy       = id
hoist Q.effects . Q.copy = id

The duplication does not by itself involve the copying of bytestring chunks; it just makes two references to each chunk as it arises. This does, however double the number of constructors associated with each chunk.

drained :: (Monad m, MonadTrans t, Monad (t m)) => t m (ByteStream m r) -> t m r Source #

Perform the effects contained in the second in an effectful pair of bytestrings, ignoring the bytes. It would typically be used at the type

ByteStream m (ByteStream m r) -> ByteStream m r

mwrap :: m (ByteStream m r) -> ByteStream m r Source #

Reconceive an effect that results in an effectful bytestring as an effectful bytestring. Compare Streaming.mwrap. The closes equivalent of

>>> Streaming.wrap :: f (Stream f m r) -> Stream f m r

is here consChunk. mwrap is the smart constructor for the internal Go constructor.

distribute :: (Monad m, MonadTrans t, MFunctor t, Monad (t m), Monad (t (ByteStream m))) => ByteStream (t m) a -> t (ByteStream m) a Source #

Given a byte stream on a transformed monad, make it possible to 'run' transformer.

Transforming ByteStreams

map :: Monad m => (Word8 -> Word8) -> ByteStream m r -> ByteStream m r Source #

O(n) map f xs is the ByteStream obtained by applying f to each element of xs.

intercalate :: Monad m => ByteStream m () -> Stream (ByteStream m) m r -> ByteStream m r Source #

O(n) The intercalate function takes a ByteStream and a list of ByteStreams and concatenates the list after interspersing the first argument between each element of the list.

intersperse :: Monad m => Word8 -> ByteStream m r -> ByteStream m r Source #

The intersperse function takes a Word8 and a ByteStream and `intersperses' that byte between the elements of the ByteStream. It is analogous to the intersperse function on Streams.

Basic interface

cons :: Monad m => Word8 -> ByteStream m r -> ByteStream m r Source #

O(1) cons is analogous to (:) for lists.

cons' :: Word8 -> ByteStream m r -> ByteStream m r Source #

O(1) Unlike cons, 'cons\'' is strict in the ByteString that we are consing onto. More precisely, it forces the head and the first chunk. It does this because, for space efficiency, it may coalesce the new byte onto the first 'chunk' rather than starting a new 'chunk'.

So that means you can't use a lazy recursive contruction like this:

let xs = cons\' c xs in xs

You can however use cons, as well as repeat and cycle, to build infinite byte streams.

snoc :: Monad m => ByteStream m r -> Word8 -> ByteStream m r Source #

O(n/c) Append a byte to the end of a ByteStream.

append :: Monad m => ByteStream m r -> ByteStream m s -> ByteStream m s Source #

O(n/c) Append two ByteStrings together.

filter :: Monad m => (Word8 -> Bool) -> ByteStream m r -> ByteStream m r Source #

O(n) filter, applied to a predicate and a ByteStream, returns a ByteStream containing those characters that satisfy the predicate.

uncons :: Monad m => ByteStream m r -> m (Maybe (Word8, ByteStream m r)) Source #

O(1) Extract the head and tail of a ByteStream, or Nothing if it is empty.

nextByte :: Monad m => ByteStream m r -> m (Either r (Word8, ByteStream m r)) Source #

O(1) Extract the head and tail of a ByteStream, or its return value if it is empty. This is the 'natural' uncons for an effectful byte stream.

denull :: Monad m => Stream (ByteStream m) m r -> Stream (ByteStream m) m r Source #

Remove empty ByteStrings from a stream of bytestrings.

Substrings

Breaking strings

break :: Monad m => (Word8 -> Bool) -> ByteStream m r -> ByteStream m (ByteStream m r) Source #

break p is equivalent to span (not . p).

drop :: Monad m => Int64 -> ByteStream m r -> ByteStream m r Source #

O(n/c) drop n xs returns the suffix of xs after the first n elements, or [] if n > length xs.

>>> Q.putStrLn $ Q.drop 6 "Wisconsin"
sin
>>> Q.putStrLn $ Q.drop 16 "Wisconsin"
>>> 

dropWhile :: Monad m => (Word8 -> Bool) -> ByteStream m r -> ByteStream m r Source #

dropWhile p xs returns the suffix remaining after takeWhile p xs.

group :: Monad m => ByteStream m r -> Stream (ByteStream m) m r Source #

The group function takes a ByteStream and returns a list of ByteStreams such that the concatenation of the result is equal to the argument. Moreover, each sublist in the result contains only equal elements. For example,

group "Mississippi" = ["M","i","ss","i","ss","i","pp","i"]

It is a special case of groupBy, which allows the programmer to supply their own equality test.

groupBy :: Monad m => (Word8 -> Word8 -> Bool) -> ByteStream m r -> Stream (ByteStream m) m r Source #

The groupBy function is a generalized version of group.

span :: Monad m => (Word8 -> Bool) -> ByteStream m r -> ByteStream m (ByteStream m r) Source #

span p xs breaks the ByteStream into two segments. It is equivalent to (takeWhile p xs, dropWhile p xs).

splitAt :: Monad m => Int64 -> ByteStream m r -> ByteStream m (ByteStream m r) Source #

O(n/c) splitAt n xs is equivalent to (take n xs, drop n xs).

>>> rest <- Q.putStrLn $ Q.splitAt 3 "therapist is a danger to good hyphenation, as Knuth notes"
the
>>> Q.putStrLn $ Q.splitAt 19 rest
rapist is a danger

splitWith :: Monad m => (Word8 -> Bool) -> ByteStream m r -> Stream (ByteStream m) m r Source #

O(n) Splits a ByteStream into components delimited by separators, where the predicate returns True for a separator element. The resulting components do not contain the separators. Two adjacent separators result in an empty component in the output. eg.

splitWith (=='a') "aabbaca" == ["","","bb","c",""]
splitWith (=='a') []        == []

take :: Monad m => Int64 -> ByteStream m r -> ByteStream m () Source #

O(n/c) take n, applied to a ByteStream xs, returns the prefix of xs of length n, or xs itself if n > length xs.

Note that in the streaming context this drops the final return value; splitAt preserves this information, and is sometimes to be preferred.

>>> Q.putStrLn $ Q.take 8 $ "Is there a God?" >> return True
Is there
>>> Q.putStrLn $ "Is there a God?" >> return True
Is there a God?
True
>>> rest <- Q.putStrLn $ Q.splitAt 8 $ "Is there a God?" >> return True
Is there
>>> Q.effects  rest
True

takeWhile :: Monad m => (Word8 -> Bool) -> ByteStream m r -> ByteStream m () Source #

takeWhile, applied to a predicate p and a ByteStream xs, returns the longest prefix (possibly empty) of xs of elements that satisfy p.

Breaking into many substrings

split :: Monad m => Word8 -> ByteStream m r -> Stream (ByteStream m) m r Source #

O(n) Break a ByteStream into pieces separated by the byte argument, consuming the delimiter. I.e.

split '\n' "a\nb\nd\ne" == ["a","b","d","e"]
split 'a'  "aXaXaXa"    == ["","X","X","X",""]
split 'x'  "x"          == ["",""]

and

intercalate [c] . split c == id
split == splitWith . (==)

As for all splitting functions in this library, this function does not copy the substrings, it just constructs new ByteStreams that are slices of the original.

Special folds

concat :: Monad m => Stream (ByteStream m) m r -> ByteStream m r Source #

O(n) Concatenate a stream of byte streams.

Builders

toStreamingByteStringWith :: MonadIO m => AllocationStrategy -> Builder -> ByteStream m () Source #

Take a builder and convert it to a genuine streaming bytestring, using a specific allocation strategy.

toStreamingByteString :: MonadIO m => Builder -> ByteStream m () Source #

Take a builder constructed otherwise and convert it to a genuine streaming bytestring.

>>> Q.putStrLn $ Q.toStreamingByteString $ stringUtf8 "哈斯克尔" <> stringUtf8 " " <> integerDec 98
哈斯克尔 98

This benchmark shows its indistinguishable performance is indistinguishable from toLazyByteString

toBuilder :: ByteStream IO () -> Builder Source #

A simple construction of a builder from a ByteString.

>>> let aaa = "10000 is a number\n" :: Q.ByteString IO ()
>>> hPutBuilder  IO.stdout $ toBuilder  aaa
10000 is a number

concatBuilders :: Stream (Of Builder) IO () -> Builder Source #

Concatenate a stream of builders (not a streaming bytestring!) into a single builder.

>>> let aa = yield (integerDec 10000) >> yield (string8 " is a number.") >> yield (char8 '\n')
>>> hPutBuilder IO.stdout $ concatBuilders aa
10000 is a number.

Building ByteStreams

Infinite ByteStreams

repeat :: Word8 -> ByteStream m r Source #

repeat x is an infinite ByteStream, with x the value of every element.

>>> R.stdout $ R.take 50 $ R.repeat 60
<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
>>> Q.putStrLn $ Q.take 50 $ Q.repeat 'z'
zzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzzz

iterate :: (Word8 -> Word8) -> Word8 -> ByteStream m r Source #

iterate f x returns an infinite ByteStream of repeated applications -- of f to x:

iterate f x == [x, f x, f (f x), ...]
>>> R.stdout $ R.take 50 $ R.iterate succ 39
()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXY
>>> Q.putStrLn $ Q.take 50 $ Q.iterate succ '\''
()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXY

cycle :: Monad m => ByteStream m r -> ByteStream m s Source #

cycle ties a finite ByteStream into a circular one, or equivalently, the infinite repetition of the original ByteStream. For an empty bytestring (like return 17) it of course makes an unproductive loop

>>> Q.putStrLn $ Q.take 7 $ Q.cycle  "y\n"
y
y
y
y

Unfolding ByteStreams

unfoldM :: Monad m => (a -> Maybe (Word8, a)) -> a -> ByteStream m () Source #

O(n) The unfoldM function is analogous to the Stream unfoldr. unfoldM builds a ByteStream from a seed value. The function takes the element and returns Nothing if it is done producing the ByteStream or returns Just (a,b), in which case, a is a prepending to the ByteStream and b is used as the next element in a recursive call.

unfoldr :: (a -> Either r (Word8, a)) -> a -> ByteStream m r Source #

Like unfoldM, but yields a final r when the Word8 generation is complete.

reread :: Monad m => (s -> m (Maybe ByteString)) -> s -> ByteStream m () Source #

Stream chunks from something that contains IO (Maybe ByteString) until it returns Nothing. reread is of particular use rendering io-streams input streams as byte streams in the present sense.

Q.reread Streams.read            :: InputStream B.ByteString -> Q.ByteString IO ()
Q.reread (liftIO . Streams.read) :: MonadIO m => InputStream B.ByteString -> Q.ByteString m ()

The other direction here is

Streams.unfoldM Q.unconsChunk    :: Q.ByteString IO r -> IO (InputStream B.ByteString)

Folds, including support for Foldl

foldr :: Monad m => (Word8 -> a -> a) -> a -> ByteStream m () -> m a Source #

foldr, applied to a binary operator, a starting value (typically the right-identity of the operator), and a ByteStream, reduces the ByteStream using the binary operator, from right to left.

foldr cons = id

fold :: Monad m => (x -> Word8 -> x) -> x -> (x -> b) -> ByteStream m () -> m b Source #

fold, applied to a binary operator, a starting value (typically the left-identity of the operator), and a ByteStream, reduces the ByteStream using the binary operator, from left to right. We use the style of the foldl libarary for left folds

fold_ :: Monad m => (x -> Word8 -> x) -> x -> (x -> b) -> ByteStream m r -> m (Of b r) Source #

fold_ keeps the return value of the left-folded bytestring. Useful for simultaneous folds over a segmented bytestream.

head :: Monad m => ByteStream m r -> m (Of (Maybe Word8) r) Source #

O(c) Extract the first element of a ByteStream, if there is one. Suitable for use with mapped:

S.mapped Q.head :: Stream (Q.ByteStream m) m r -> Stream (Of (Maybe Word8)) m r

head_ :: Monad m => ByteStream m r -> m Word8 Source #

O(1) Extract the first element of a ByteStream, which must be non-empty.

last :: Monad m => ByteStream m r -> m (Of (Maybe Word8) r) Source #

Extract the last element of a ByteStream, if possible. Suitable for use with mapped:

S.mapped Q.last :: Streaming (ByteStream m) m r -> Stream (Of (Maybe Word8)) m r

last_ :: Monad m => ByteStream m r -> m Word8 Source #

O(n/c) Extract the last element of a ByteStream, which must be finite and non-empty.

length :: Monad m => ByteStream m r -> m (Of Int r) Source #

O(n/c) length returns the length of a byte stream as an Int together with the return value. This makes various maps possible.

>>> Q.length "one\ntwo\three\nfour\nfive\n"
23 :> ()
>>> S.print $ S.take 3 $ mapped Q.length $ Q.lines "one\ntwo\three\nfour\nfive\n"
3
8
4

length_ :: Monad m => ByteStream m r -> m Int Source #

Like length, report the length in bytes of the ByteStream by running through its contents. Since the return value is in the effect m, this is one way to "get out" of the stream.

null :: Monad m => ByteStream m r -> m (Of Bool r) Source #

Test whether a ByteStream is empty, collecting its return value; to reach the return value, this operation must check the whole length of the string.

>>> Q.null "one\ntwo\three\nfour\nfive\n"
False :> ()
>>> Q.null ""
True :> ()
>>> S.print $ mapped R.null $ Q.lines "yours,\nMeredith"
False
False

Suitable for use with mapped:

S.mapped Q.null :: Streaming (ByteStream m) m r -> Stream (Of Bool) m r

null_ :: Monad m => ByteStream m r -> m Bool Source #

O(1) Test whether a ByteStream is empty. The value is of course in the monad of the effects.

>>> Q.null "one\ntwo\three\nfour\nfive\n"
False
>>> Q.null $ Q.take 0 Q.stdin
True
>>> :t Q.null $ Q.take 0 Q.stdin
Q.null $ Q.take 0 Q.stdin :: MonadIO m => m Bool

nulls :: Monad m => ByteStream m r -> m (Sum (ByteStream m) (ByteStream m) r) Source #

O1 Distinguish empty from non-empty lines, while maintaining streaming; the empty ByteStrings are on the right

>>> nulls  ::  ByteStream m r -> m (Sum (ByteStream m) (ByteStream m) r)

There are many ways to remove null bytestrings from a Stream (ByteStream m) m r (besides using denull). If we pass next to

>>> mapped nulls bs :: Stream (Sum (ByteStream m) (ByteStream m)) m r

then can then apply Streaming.separate to get

>>> separate (mapped nulls bs) :: Stream (ByteStream m) (Stream (ByteStream m) m) r

The inner monad is now made of the empty bytestrings; we act on this with hoist , considering that

>>> :t Q.effects . Q.concat
Q.effects . Q.concat
  :: Monad m => Stream (Q.ByteStream m) m r -> m r

we have

>>> hoist (Q.effects . Q.concat) . separate . mapped Q.nulls
  :: Monad n =>  Stream (Q.ByteStream n) n b -> Stream (Q.ByteStream n) n b

testNull :: Monad m => ByteStream m r -> m (Of Bool (ByteStream m r)) Source #

Similar to null, but yields the remainder of the ByteStream stream when an answer has been determined.

count :: Monad m => Word8 -> ByteStream m r -> m (Of Int r) Source #

Returns the number of times its argument appears in the ByteStream. Suitable for use with mapped:

S.mapped (Q.count 37) :: Stream (Q.ByteStream m) m r -> Stream (Of Int) m r

count_ :: Monad m => Word8 -> ByteStream m r -> m Int Source #

Returns the number of times its argument appears in the ByteStream.

count = length . elemIndices

I/O with ByteStreams

Standard input and output

getContents :: MonadIO m => ByteStream m () Source #

Equivalent to hGetContents stdin. Will read lazily.

stdin :: MonadIO m => ByteStream m () Source #

Pipes-style nomenclature for getContents.

stdout :: MonadIO m => ByteStream m r -> m r Source #

Pipes-style nomenclature for putStr.

interact :: (ByteStream IO () -> ByteStream IO r) -> IO r Source #

A synonym for hPut, for compatibility

hPutStr :: Handle -> ByteStream IO r -> IO r hPutStr = hPut

  • - | Write a ByteStream to stdout putStr :: ByteStream IO r -> IO r putStr = hPut IO.stdout

The interact function takes a function of type ByteStream -> ByteStream as its argument. The entire input from the standard input device is passed to this function as its argument, and the resulting string is output on the standard output device.

interact morph = stdout (morph stdin)

Files

readFile :: MonadResource m => FilePath -> ByteStream m () Source #

Read an entire file into a chunked ByteStream IO (). The handle will be held open until EOF is encountered. The block governed by runResourceT will end with the closing of any handles opened.

>>> :! cat hello.txt
Hello world.
Goodbye world.
>>> runResourceT $ Q.stdout $ Q.readFile "hello.txt"
Hello world.
Goodbye world.

writeFile :: MonadResource m => FilePath -> ByteStream m r -> m r Source #

Write a ByteStream to a file. Use runResourceT to ensure that the handle is closed.

>>> :set -XOverloadedStrings
>>> runResourceT $ Q.writeFile "hello.txt" "Hello world.\nGoodbye world.\n"
>>> :! cat "hello.txt"
Hello world.
Goodbye world.
>>> runResourceT $ Q.writeFile "hello2.txt" $ Q.readFile "hello.txt"
>>> :! cat hello2.txt
Hello world.
Goodbye world.

appendFile :: MonadResource m => FilePath -> ByteStream m r -> m r Source #

Append a ByteStream to a file. Use runResourceT to ensure that the handle is closed.

>>> runResourceT $ Q.writeFile "hello.txt" "Hello world.\nGoodbye world.\n"
>>> runResourceT $ Q.stdout $ Q.readFile "hello.txt"
Hello world.
Goodbye world.
>>> runResourceT $ Q.appendFile "hello.txt" "sincerely yours,\nArthur\n"
>>> runResourceT $ Q.stdout $  Q.readFile "hello.txt"
Hello world.
Goodbye world.
sincerely yours,
Arthur

I/O with Handles

fromHandle :: MonadIO m => Handle -> ByteStream m () Source #

Pipes-style nomenclature for hGetContents.

toHandle :: MonadIO m => Handle -> ByteStream m r -> m r Source #

Pipes nomenclature for hPut.

hGet :: MonadIO m => Handle -> Int -> ByteStream m () Source #

Read n bytes into a ByteStream, directly from the specified Handle.

hGetContents :: MonadIO m => Handle -> ByteStream m () Source #

Read entire handle contents lazily into a ByteStream. Chunks are read on demand, using the default chunk size.

Note: the Handle should be placed in binary mode with hSetBinaryMode for hGetContents to work correctly.

hGetContentsN :: MonadIO m => Int -> Handle -> ByteStream m () Source #

Read entire handle contents lazily into a ByteStream. Chunks are read on demand, in at most k-sized chunks. It does not block waiting for a whole k-sized chunk, so if less than k bytes are available then they will be returned immediately as a smaller chunk.

Note: the Handle should be placed in binary mode with hSetBinaryMode for hGetContentsN to work correctly.

hGetN :: MonadIO m => Int -> Handle -> Int -> ByteStream m () Source #

Read n bytes into a ByteStream, directly from the specified Handle, in chunks of size k.

hGetNonBlocking :: MonadIO m => Handle -> Int -> ByteStream m () Source #

hGetNonBlocking is similar to hGet, except that it will never block waiting for data to become available, instead it returns only whatever data is available. If there is no data available to be read, hGetNonBlocking returns empty.

Note: on Windows and with Haskell implementation other than GHC, this function does not work correctly; it behaves identically to hGet.

hGetNonBlockingN :: MonadIO m => Int -> Handle -> Int -> ByteStream m () Source #

hGetNonBlockingN is similar to hGetContentsN, except that it will never block waiting for data to become available, instead it returns only whatever data is available. Chunks are read on demand, in k-sized chunks.

hPut :: MonadIO m => Handle -> ByteStream m r -> m r Source #

Outputs a ByteStream to the specified Handle.

Etc.

zipWithStream :: Monad m => (forall x. a -> ByteStream m x -> ByteStream m x) -> [a] -> Stream (ByteStream m) m r -> Stream (ByteStream m) m r Source #

Zip a list and a stream-of-byte-streams together.

Simple chunkwise operations

unconsChunk :: Monad m => ByteStream m r -> m (Maybe (ByteString, ByteStream m r)) Source #

Like uncons, but yields the entire first ByteString chunk that the stream is holding onto. If there wasn't one, it tries to fetch it.

nextChunk :: Monad m => ByteStream m r -> m (Either r (ByteString, ByteStream m r)) Source #

Similar to unconsChunk, but yields the final r return value when there is no subsequent chunk.

chunk :: ByteString -> ByteStream m () Source #

Yield-style smart constructor for Chunk.

foldrChunks :: Monad m => (ByteString -> a -> a) -> a -> ByteStream m r -> m a Source #

Consume the chunks of an effectful ByteString with a natural right fold.

foldlChunks :: Monad m => (a -> ByteString -> a) -> a -> ByteStream m r -> m (Of a r) Source #

Consume the chunks of an effectful ByteString with a left fold. Suitable for use with mapped.

chunkFold :: Monad m => (x -> ByteString -> x) -> x -> (x -> a) -> ByteStream m r -> m (Of a r) Source #

chunkFold is preferable to foldlChunks since it is an appropriate argument for Control.Foldl.purely which permits many folds and sinks to be run simultaneously on one bytestream.

chunkFoldM :: Monad m => (x -> ByteString -> m x) -> m x -> (x -> m a) -> ByteStream m r -> m (Of a r) Source #

chunkFoldM is preferable to foldlChunksM since it is an appropriate argument for impurely which permits many folds and sinks to be run simultaneously on one bytestream.

chunkMap :: Monad m => (ByteString -> ByteString) -> ByteStream m r -> ByteStream m r Source #

Instead of mapping over each Word8 or Char, map over each strict ByteString chunk in the stream.

chunkMapM :: Monad m => (ByteString -> m ByteString) -> ByteStream m r -> ByteStream m r Source #

Like chunkMap, but map effectfully.

chunkMapM_ :: Monad m => (ByteString -> m x) -> ByteStream m r -> m r Source #

Like chunkMapM, but discard the result of each effectful mapping.