conduit-1.3.4.3: test/main.hs
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE CPP #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE FlexibleInstances #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
import Test.Hspec
import Test.Hspec.QuickCheck (prop)
import Test.QuickCheck (getPositive)
import Test.QuickCheck.Monadic (assert, monadicIO, run)
import Data.Conduit (runConduit, (.|), ConduitT, runConduitPure, runConduitRes)
import qualified Data.Conduit as C
import qualified Data.Conduit.Lift as C
import qualified Data.Conduit.Internal as CI
import qualified Data.Conduit.List as CL
import Data.Typeable (Typeable)
import Control.Exception (throw, evaluate)
import Control.Monad.Trans.Resource (runResourceT)
import Control.Monad.Trans.Maybe (MaybeT (MaybeT))
import Control.Monad.State.Strict (modify)
import Data.Maybe (fromMaybe,catMaybes,fromJust)
import qualified Data.List as DL
import qualified Data.List.Split as DLS (chunksOf)
import Control.Monad.ST (runST)
import Data.Monoid
import qualified Data.IORef as I
import Data.Tuple (swap)
import Control.Monad.Trans.Resource (allocate, resourceForkIO)
import Control.Concurrent (threadDelay, killThread)
import Control.Monad.IO.Class (liftIO)
import Control.Monad.Trans.Class (lift)
import Control.Monad.Trans.Writer (execWriter, tell, runWriterT)
import Control.Monad.Trans.State (evalStateT, get, put)
import qualified Control.Monad.Writer as W
import Control.Applicative (pure, (<$>), (<*>))
import qualified Control.Monad.Catch as Catch
import Data.Functor.Identity (Identity,runIdentity)
import Control.Monad (forever, void)
import Data.Void (Void)
import qualified Control.Concurrent.MVar as M
import Control.Monad.Except (catchError, throwError)
import qualified Data.Map as Map
import qualified Data.Conduit.Extra.ZipConduitSpec as ZipConduit
import qualified Data.Conduit.StreamSpec as Stream
import qualified Spec
(@=?) :: (Eq a, Show a) => a -> a -> IO ()
(@=?) = flip shouldBe
-- Quickcheck property for testing equivalence of list processing
-- functions and their conduit counterparts
equivToList :: Eq b => ([a] -> [b]) -> ConduitT a b Identity () -> [a] -> Bool
equivToList f conduit xs =
f xs == runConduitPure (CL.sourceList xs .| conduit .| CL.consume)
-- | Check that two conduits produce the same outputs and return the same result.
bisimilarTo :: (Eq a, Eq r) => ConduitT () a Identity r -> ConduitT () a Identity r -> Bool
left `bisimilarTo` right =
C.runConduitPure (toListRes left) == C.runConduitPure (toListRes right)
where
-- | Sink a conduit into a list and return it alongside the result.
-- So it is, essentially, @sinkList@ plus result.
toListRes :: Monad m => ConduitT () a m r -> ConduitT () Void m ([a], r)
toListRes cond = swap <$> C.fuseBoth cond CL.consume
main :: IO ()
main = hspec $ do
describe "Combinators" Spec.spec
describe "data loss rules" $ do
it "consumes the source to quickly" $ do
x <- runConduitRes $ CL.sourceList [1..10 :: Int] .| do
strings <- CL.map show .| CL.take 5
liftIO $ putStr $ unlines strings
CL.fold (+) 0
40 `shouldBe` x
it "correctly consumes a chunked resource" $ do
x <- runConduitRes $ (CL.sourceList [1..5 :: Int] `mappend` CL.sourceList [6..10]) .| do
strings <- CL.map show .| CL.take 5
liftIO $ putStr $ unlines strings
CL.fold (+) 0
40 `shouldBe` x
describe "filter" $ do
it "even" $ do
x <- runConduitRes $ CL.sourceList [1..10] .| CL.filter even .| CL.consume
x `shouldBe` filter even [1..10 :: Int]
prop "concat" $ equivToList (concat :: [[Int]]->[Int]) CL.concat
describe "mapFoldable" $ do
prop "list" $
equivToList (concatMap (:[]) :: [Int]->[Int]) (CL.mapFoldable (:[]))
let f x = if odd x then Just x else Nothing
prop "Maybe" $
equivToList (catMaybes . map f :: [Int]->[Int]) (CL.mapFoldable f)
prop "scan" $ equivToList (tail . scanl (+) 0 :: [Int]->[Int]) (void $ CL.scan (+) 0)
-- mapFoldableM and scanlM are fully polymorphic in type of monad
-- so it suffice to check only with Identity.
describe "mapFoldableM" $ do
prop "list" $
equivToList (concatMap (:[]) :: [Int]->[Int]) (CL.mapFoldableM (return . (:[])))
let f x = if odd x then Just x else Nothing
prop "Maybe" $
equivToList (catMaybes . map f :: [Int]->[Int]) (CL.mapFoldableM (return . f))
prop "scanM" $ equivToList (tail . scanl (+) 0) (void $ CL.scanM (\a s -> return $ a + s) (0 :: Int))
describe "ResourceT" $ do
it "resourceForkIO" $ do
counter <- I.newIORef 0
let w = allocate
(I.atomicModifyIORef counter $ \i ->
(i + 1, ()))
(const $ I.atomicModifyIORef counter $ \i ->
(i - 1, ()))
runResourceT $ do
_ <- w
_ <- resourceForkIO $ return ()
_ <- resourceForkIO $ return ()
sequence_ $ replicate 1000 $ do
tid <- resourceForkIO $ return ()
liftIO $ killThread tid
_ <- resourceForkIO $ return ()
_ <- resourceForkIO $ return ()
return ()
-- give enough of a chance to the cleanup code to finish
threadDelay 1000
res <- I.readIORef counter
res `shouldBe` (0 :: Int)
describe "sum" $ do
it "works for 1..10" $ do
x <- runConduitRes $ CL.sourceList [1..10] .| CL.fold (+) (0 :: Int)
x `shouldBe` sum [1..10]
prop "is idempotent" $ \list ->
(runST $ runConduit $ CL.sourceList list .| CL.fold (+) (0 :: Int))
== sum list
describe "foldMap" $ do
it "sums 1..10" $ do
Sum x <- runConduit $ CL.sourceList [1..(10 :: Int)] .| CL.foldMap Sum
x `shouldBe` sum [1..10]
it "preserves order" $ do
x <- runConduit $ CL.sourceList [[4],[2],[3],[1]] .| CL.foldMap (++[(9 :: Int)])
x `shouldBe` [4,9,2,9,3,9,1,9]
describe "foldMapM" $ do
it "sums 1..10" $ do
Sum x <- runConduit $ CL.sourceList [1..(10 :: Int)] .| CL.foldMapM (return . Sum)
x `shouldBe` sum [1..10]
it "preserves order" $ do
x <- runConduit $ CL.sourceList [[4],[2],[3],[1]] .| CL.foldMapM (return . (++[(9 :: Int)]))
x `shouldBe` [4,9,2,9,3,9,1,9]
describe "unfold" $ do
it "works" $ do
let f 0 = Nothing
f i = Just (show i, i - 1)
seed = 10 :: Int
x <- runConduit $ CL.unfold f seed .| CL.consume
let y = DL.unfoldr f seed
x `shouldBe` y
describe "unfoldM" $ do
it "works" $ do
let f 0 = Nothing
f i = Just (show i, i - 1)
seed = 10 :: Int
x <- runConduit $ CL.unfoldM (return . f) seed .| CL.consume
let y = DL.unfoldr f seed
x `shouldBe` y
describe "uncons" $ do
prop "folds to list" $ \xs ->
let src = C.sealConduitT $ CL.sourceList xs in
(xs :: [Int]) == DL.unfoldr CL.uncons src
prop "works with unfold" $ \xs ->
let src = CL.sourceList xs in
CL.unfold CL.uncons (C.sealConduitT src) `bisimilarTo` (src :: ConduitT () Int Identity ())
describe "unconsEither" $ do
let
eitherToMaybe :: Either l a -> Maybe a
eitherToMaybe (Left _) = Nothing
eitherToMaybe (Right a) = Just a
prop "folds outputs to list" $ \xs ->
let src = C.sealConduitT $ CL.sourceList xs in
(xs :: [Int]) == DL.unfoldr (eitherToMaybe . CL.unconsEither) src
prop "works with unfoldEither" $ \(xs, r) ->
let src = CL.sourceList xs *> pure r in
CL.unfoldEither CL.unconsEither (C.sealConduitT src) `bisimilarTo` (src :: ConduitT () Int Identity Int)
describe "Monoid instance for Source" $ do
it "mappend" $ do
x <- runConduitRes $ (CL.sourceList [1..5 :: Int] `mappend` CL.sourceList [6..10]) .| CL.fold (+) 0
x `shouldBe` sum [1..10]
it "mconcat" $ do
x <- runConduitRes $ mconcat
[ CL.sourceList [1..5 :: Int]
, CL.sourceList [6..10]
, CL.sourceList [11..20]
] .| CL.fold (+) 0
x `shouldBe` sum [1..20]
describe "zipping" $ do
it "zipping two small lists" $ do
res <- runConduitRes $ CI.zipSources (CL.sourceList [1..10]) (CL.sourceList [11..12]) .| CL.consume
res @=? zip [1..10 :: Int] [11..12 :: Int]
describe "zipping sinks" $ do
it "take all" $ do
res <- runConduitRes $ CL.sourceList [1..10] .| CI.zipSinks CL.consume CL.consume
res @=? ([1..10 :: Int], [1..10 :: Int])
it "take fewer on left" $ do
res <- runConduitRes $ CL.sourceList [1..10] .| CI.zipSinks (CL.take 4) CL.consume
res @=? ([1..4 :: Int], [1..10 :: Int])
it "take fewer on right" $ do
res <- runConduitRes $ CL.sourceList [1..10] .| CI.zipSinks CL.consume (CL.take 4)
res @=? ([1..10 :: Int], [1..4 :: Int])
describe "Monad instance for Sink" $ do
it "binding" $ do
x <- runConduitRes $ CL.sourceList [1..10] .| do
_ <- CL.take 5
CL.fold (+) (0 :: Int)
x `shouldBe` sum [6..10]
describe "Applicative instance for Sink" $ do
it "<$> and <*>" $ do
x <- runConduitRes $ CL.sourceList [1..10] .|
(+) <$> pure 5 <*> CL.fold (+) (0 :: Int)
x `shouldBe` sum [1..10] + 5
describe "resumable sources" $ do
it "simple" $ do
(x, y, z) <- runConduitRes $ do
let src1 = CL.sourceList [1..10 :: Int]
(src2, x) <- src1 C.$$+ CL.take 5
(src3, y) <- src2 C.$$++ CL.fold (+) 0
z <- src3 C.$$+- CL.consume
return (x, y, z)
x `shouldBe` [1..5] :: IO ()
y `shouldBe` sum [6..10]
z `shouldBe` []
describe "conduits" $ do
it "map, left" $ do
x <- runConduitRes $
CL.sourceList [1..10]
.| CL.map (* 2)
.| CL.fold (+) 0
x `shouldBe` 2 * sum [1..10 :: Int]
it "map, left >+>" $ do
x <- runConduitRes $
CI.ConduitT
((CI.unConduitT (CL.sourceList [1..10]) CI.Done
CI.>+> CI.injectLeftovers ((\c -> c `CI.unConduitT` CI.Done) $ CL.map (* 2))) >>=)
.| CL.fold (+) 0
x `shouldBe` 2 * sum [1..10 :: Int]
it "map, right" $ do
x <- runConduitRes $
CL.sourceList [1..10]
.| CL.map (* 2)
.| CL.fold (+) 0
x `shouldBe` 2 * sum [1..10 :: Int]
prop "chunksOf" $ \(positive, xs) ->
let p = getPositive positive
conduit = CL.sourceList xs .| CL.chunksOf p .| CL.consume
in DLS.chunksOf p (xs :: [Int]) == runConduitPure conduit
it "chunksOf (zero)" $
let conduit = return () .| CL.chunksOf 0 .| CL.consume
in evaluate (runConduitPure conduit) `shouldThrow` anyException
it "chunksOf (negative)" $
let conduit = return () .| CL.chunksOf (-5) .| CL.consume
in evaluate (runConduitPure conduit) `shouldThrow` anyException
it "groupBy" $ do
let input = [1::Int, 1, 2, 3, 3, 3, 4, 5, 5]
x <- runConduitRes $ CL.sourceList input
.| CL.groupBy (==)
.| CL.consume
x `shouldBe` DL.groupBy (==) input
it "groupBy (nondup begin/end)" $ do
let input = [1::Int, 2, 3, 3, 3, 4, 5]
x <- runConduitRes $ CL.sourceList input
.| CL.groupBy (==)
.| CL.consume
x `shouldBe` DL.groupBy (==) input
it "groupOn1" $ do
let input = [1::Int, 1, 2, 3, 3, 3, 4, 5, 5]
x <- runConduitRes $ CL.sourceList input
.| CL.groupOn1 id
.| CL.consume
x `shouldBe` [(1,[1]), (2, []), (3,[3,3]), (4,[]), (5, [5])]
it "groupOn1 (nondup begin/end)" $ do
let input = [1::Int, 2, 3, 3, 3, 4, 5]
x <- runConduitRes $ CL.sourceList input
.| CL.groupOn1 id
.| CL.consume
x `shouldBe` [(1,[]), (2, []), (3,[3,3]), (4,[]), (5, [])]
it "mapMaybe" $ do
let input = [Just (1::Int), Nothing, Just 2, Nothing, Just 3]
x <- runConduitRes $ CL.sourceList input
.| CL.mapMaybe ((+2) <$>)
.| CL.consume
x `shouldBe` [3, 4, 5]
it "mapMaybeM" $ do
let input = [Just (1::Int), Nothing, Just 2, Nothing, Just 3]
x <- runConduitRes $ CL.sourceList input
.| CL.mapMaybeM (return . ((+2) <$>))
.| CL.consume
x `shouldBe` [3, 4, 5]
it "catMaybes" $ do
let input = [Just (1::Int), Nothing, Just 2, Nothing, Just 3]
x <- runConduitRes $ CL.sourceList input
.| CL.catMaybes
.| CL.consume
x `shouldBe` [1, 2, 3]
it "concatMap" $ do
let input = [1, 11, 21]
x <- runConduitRes $ CL.sourceList input
.| CL.concatMap (\i -> enumFromTo i (i + 9))
.| CL.fold (+) (0 :: Int)
x `shouldBe` sum [1..30]
it "bind together" $ do
let conduit = CL.map (+ 5) .| CL.map (* 2)
x <- runConduitRes $ CL.sourceList [1..10] .| conduit .| CL.fold (+) 0
x `shouldBe` sum (map (* 2) $ map (+ 5) [1..10 :: Int])
#if !FAST
describe "isolate" $ do
it "bound to resumable source" $ do
(x, y) <- runConduitRes $ do
let src1 = CL.sourceList [1..10 :: Int]
(src2, x) <- src1 .| CL.isolate 5 C.$$+ CL.consume
y <- src2 C.$$+- CL.consume
return (x, y)
x `shouldBe` [1..5]
y `shouldBe` []
it "bound to sink, non-resumable" $ do
(x, y) <- runConduitRes $ do
CL.sourceList [1..10 :: Int] .| do
x <- CL.isolate 5 .| CL.consume
y <- CL.consume
return (x, y)
x `shouldBe` [1..5]
y `shouldBe` [6..10]
it "bound to sink, resumable" $ do
(x, y) <- runConduitRes $ do
let src1 = CL.sourceList [1..10 :: Int]
(src2, x) <- src1 C.$$+ CL.isolate 5 .| CL.consume
y <- src2 C.$$+- CL.consume
return (x, y)
x `shouldBe` [1..5]
y `shouldBe` [6..10]
it "consumes all data" $ do
x <- runConduitRes $ CL.sourceList [1..10 :: Int] .| do
CL.isolate 5 .| CL.sinkNull
CL.consume
x `shouldBe` [6..10]
describe "sequence" $ do
it "simple sink" $ do
let sumSink = do
ma <- CL.head
case ma of
Nothing -> return 0
Just a -> (+a) . fromMaybe 0 <$> CL.head
res <- runConduitRes $ CL.sourceList [1..11 :: Int]
.| CL.sequence sumSink
.| CL.consume
res `shouldBe` [3, 7, 11, 15, 19, 11]
it "sink with unpull behaviour" $ do
let sumSink = do
ma <- CL.head
case ma of
Nothing -> return 0
Just a -> (+a) . fromMaybe 0 <$> CL.peek
res <- runConduitRes $ CL.sourceList [1..11 :: Int]
.| CL.sequence sumSink
.| CL.consume
res `shouldBe` [3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 11]
#endif
describe "peek" $ do
it "works" $ do
(a, b) <- runConduitRes $ CL.sourceList [1..10 :: Int] .| do
a <- CL.peek
b <- CL.consume
return (a, b)
(a, b) `shouldBe` (Just 1, [1..10])
describe "unbuffering" $ do
it "works" $ do
x <- runConduitRes $ do
let src1 = CL.sourceList [1..10 :: Int]
(src2, ()) <- src1 C.$$+ CL.drop 5
src2 C.$$+- CL.fold (+) 0
x `shouldBe` sum [6..10]
describe "operators" $ do
it "only use .|" $
runConduitPure
( CL.sourceList [1..10 :: Int]
.| CL.map (+ 1)
.| CL.map (subtract 1)
.| CL.mapM (return . (* 2))
.| CL.map (`div` 2)
.| CL.fold (+) 0
) `shouldBe` sum [1..10]
it "only use =$" $
runConduitPure
( CL.sourceList [1..10 :: Int]
.| CL.map (+ 1)
.| CL.map (subtract 1)
.| CL.map (* 2)
.| CL.map (`div` 2)
.| CL.fold (+) 0
) `shouldBe` sum [1..10]
it "chain" $ do
x <- runConduit
$ CL.sourceList [1..10 :: Int]
.| CL.map (+ 1)
.| CL.map (+ 1)
.| CL.map (+ 1)
.| CL.map (subtract 3)
.| CL.map (* 2)
.| CL.map (`div` 2)
.| CL.map (+ 1)
.| CL.map (+ 1)
.| CL.map (+ 1)
.| CL.map (subtract 3)
.| CL.fold (+) 0
x `shouldBe` sum [1..10]
describe "termination" $ do
it "terminates early" $ do
let src = forever $ C.yield ()
x <- runConduit $ src .| CL.head
x `shouldBe` Just ()
it "bracket" $ do
ref <- I.newIORef (0 :: Int)
let src = C.bracketP
(I.modifyIORef ref (+ 1))
(\() -> I.modifyIORef ref (+ 2))
(\() -> forever $ C.yield (1 :: Int))
val <- runConduitRes $ src .| CL.isolate 10 .| CL.fold (+) 0
val `shouldBe` 10
i <- I.readIORef ref
i `shouldBe` 3
it "bracket skipped if not needed" $ do
ref <- I.newIORef (0 :: Int)
let src = C.bracketP
(I.modifyIORef ref (+ 1))
(\() -> I.modifyIORef ref (+ 2))
(\() -> forever $ C.yield (1 :: Int))
src' = CL.sourceList $ repeat 1
val <- runConduitRes $ (src' >> src) .| CL.isolate 10 .| CL.fold (+) 0
val `shouldBe` 10
i <- I.readIORef ref
i `shouldBe` 0
it "bracket + toPipe" $ do
ref <- I.newIORef (0 :: Int)
let src = C.bracketP
(I.modifyIORef ref (+ 1))
(\() -> I.modifyIORef ref (+ 2))
(\() -> forever $ C.yield (1 :: Int))
val <- runConduitRes $ src .| CL.isolate 10 .| CL.fold (+) 0
val `shouldBe` 10
i <- I.readIORef ref
i `shouldBe` 3
it "bracket skipped if not needed" $ do
ref <- I.newIORef (0 :: Int)
let src = C.bracketP
(I.modifyIORef ref (+ 1))
(\() -> I.modifyIORef ref (+ 2))
(\() -> forever $ C.yield (1 :: Int))
src' = CL.sourceList $ repeat 1
val <- runConduitRes $ (src' >> src) .| CL.isolate 10 .| CL.fold (+) 0
val `shouldBe` 10
i <- I.readIORef ref
i `shouldBe` 0
describe "invariant violations" $ do
it "leftovers without input" $ do
ref <- I.newIORef []
let add x = I.modifyIORef ref (x:)
adder' = CI.NeedInput (\a -> liftIO (add a) >> adder') return
adder = CI.ConduitT (adder' >>=)
residue x = CI.ConduitT $ \rest -> CI.Leftover (rest ()) x
_ <- runConduit $ C.yield 1 .| adder
x <- I.readIORef ref
x `shouldBe` [1 :: Int]
I.writeIORef ref []
_ <- runConduit $ C.yield 1 .| ((residue 2 >> residue 3) >> adder)
y <- I.readIORef ref
y `shouldBe` [1, 2, 3]
I.writeIORef ref []
_ <- runConduit $ C.yield 1 .| (residue 2 >> (residue 3 >> adder))
z <- I.readIORef ref
z `shouldBe` [1, 2, 3]
I.writeIORef ref []
describe "sane yield/await'" $ do
it' "yield terminates" $ do
let is = [1..10] ++ undefined
src [] = return ()
src (x:xs) = C.yield x >> src xs
x <- runConduit $ src is .| CL.take 10
x `shouldBe` [1..10 :: Int]
it' "yield terminates (2)" $ do
let is = [1..10] ++ undefined
x <- runConduit $ mapM_ C.yield is .| CL.take 10
x `shouldBe` [1..10 :: Int]
describe "upstream results" $ do
it' "works" $ do
let foldUp :: (b -> a -> b) -> b -> CI.Pipe l a Void u IO (u, b)
foldUp f b = CI.awaitE >>= either (\u -> return (u, b)) (\a -> let b' = f b a in b' `seq` foldUp f b')
passFold :: (b -> a -> b) -> b -> CI.Pipe l a a () IO b
passFold f b = CI.await >>= maybe (return b) (\a -> let b' = f b a in b' `seq` CI.yield a >> passFold f b')
(x, y) <- CI.runPipe $ mapM_ CI.yield [1..10 :: Int] CI.>+> passFold (+) 0 CI.>+> foldUp (*) 1
(x, y) `shouldBe` (sum [1..10], product [1..10])
describe "input/output mapping" $ do
it' "mapOutput" $ do
x <- runConduit $ C.mapOutput (+ 1) (CL.sourceList [1..10 :: Int]) .| CL.fold (+) 0
x `shouldBe` sum [2..11]
it' "mapOutputMaybe" $ do
x <- runConduit $ C.mapOutputMaybe (\i -> if even i then Just i else Nothing) (CL.sourceList [1..10 :: Int]) .| CL.fold (+) 0
x `shouldBe` sum [2, 4..10]
it' "mapInput" $ do
xyz <- runConduit $ (CL.sourceList $ map show [1..10 :: Int]) .| do
(x, y) <- C.mapInput read (Just . show) $ ((do
x <- CL.isolate 5 .| CL.fold (+) 0
y <- CL.peek
return (x :: Int, y :: Maybe Int)) :: ConduitT Int Void IO (Int, Maybe Int))
z <- CL.consume
return (x, y, concat z)
xyz `shouldBe` (sum [1..5], Just 6, "678910")
describe "left/right identity" $ do
it' "left identity" $ do
x <- runConduit $ CL.sourceList [1..10 :: Int] .| CI.ConduitT (CI.idP >>=) .| CL.fold (+) 0
y <- runConduit $ CL.sourceList [1..10 :: Int] .| CL.fold (+) 0
x `shouldBe` y
it' "right identity" $ do
x <- CI.runPipe $ mapM_ CI.yield [1..10 :: Int] CI.>+> (CI.injectLeftovers $ (\c -> c `CI.unConduitT` CI.Done) $ CL.fold (+) 0) CI.>+> CI.idP
y <- CI.runPipe $ mapM_ CI.yield [1..10 :: Int] CI.>+> (CI.injectLeftovers $ (\c -> c `CI.unConduitT` CI.Done) $ CL.fold (+) 0)
x `shouldBe` y
describe "generalizing" $ do
it' "works" $ do
x <- CI.runPipe
$ CI.sourceToPipe (CL.sourceList [1..10 :: Int])
CI.>+> CI.conduitToPipe (CL.map (+ 1))
CI.>+> CI.sinkToPipe (CL.fold (+) 0)
x `shouldBe` sum [2..11]
describe "withUpstream" $ do
it' "works" $ do
let src = mapM_ CI.yield [1..10 :: Int] >> return True
fold f =
loop
where
loop accum =
CI.await >>= maybe (return accum) go
where
go a =
let accum' = f accum a
in accum' `seq` loop accum'
sink = CI.withUpstream $ fold (+) 0
res <- CI.runPipe $ src CI.>+> sink
res `shouldBe` (True, sum [1..10])
describe "iterate" $ do
it' "works" $ do
res <- runConduit $ CL.iterate (+ 1) (1 :: Int) .| CL.isolate 10 .| CL.fold (+) 0
res `shouldBe` sum [1..10]
prop "replicate" $ \cnt' -> do
let cnt = min cnt' 100
res <- runConduit $ CL.replicate cnt () .| CL.consume
res `shouldBe` replicate cnt ()
prop "replicateM" $ \cnt' -> do
ref <- I.newIORef 0
let cnt = min cnt' 100
res <- runConduit $ CL.replicateM cnt (I.modifyIORef ref (+ 1)) .| CL.consume
res `shouldBe` replicate cnt ()
ref' <- I.readIORef ref
ref' `shouldBe` (if cnt' <= 0 then 0 else cnt)
describe "injectLeftovers" $ do
it "works" $ do
let src = mapM_ CI.yield [1..10 :: Int]
conduit = CI.injectLeftovers $ (\c -> c `CI.unConduitT` CI.Done) $ C.awaitForever $ \i -> do
js <- CL.take 2
mapM_ C.leftover $ reverse js
C.yield i
res <- runConduit $ CI.ConduitT ((src CI.>+> CI.injectLeftovers conduit) >>=) .| CL.consume
res `shouldBe` [1..10]
describe "monad transformer laws" $ do
it "transPipe" $ do
let source = CL.sourceList $ replicate 10 ()
let tell' x = tell [x :: Int]
let replaceNum1 = C.awaitForever $ \() -> do
i <- lift get
lift $ (put $ i + 1) >> (get >>= lift . tell')
C.yield i
let replaceNum2 = C.awaitForever $ \() -> do
i <- lift get
lift $ put $ i + 1
lift $ get >>= lift . tell'
C.yield i
x <- runWriterT $ runConduit $ source .| C.transPipe (`evalStateT` 1) replaceNum1 .| CL.consume
y <- runWriterT $ runConduit $ source .| C.transPipe (`evalStateT` 1) replaceNum2 .| CL.consume
x `shouldBe` y
describe "iterM" $ do
prop "behavior" $ \l -> monadicIO $ do
let counter ref = CL.iterM (const $ liftIO $ M.modifyMVar_ ref (\i -> return $! i + 1))
v <- run $ do
ref <- M.newMVar 0
runConduit $ CL.sourceList l .| counter ref .| CL.mapM_ (const $ return ())
M.readMVar ref
assert $ v == length (l :: [Int])
prop "mapM_ equivalence" $ \l -> monadicIO $ do
let runTest h = run $ do
ref <- M.newMVar (0 :: Int)
let f = action ref
s <- runConduit $ CL.sourceList (l :: [Int]) .| h f .| CL.fold (+) 0
c <- M.readMVar ref
return (c, s)
action ref = const $ liftIO $ M.modifyMVar_ ref (\i -> return $! i + 1)
(c1, s1) <- runTest CL.iterM
(c2, s2) <- runTest (\f -> CL.mapM (\a -> f a >>= \() -> return a))
assert $ c1 == c2
assert $ s1 == s2
describe "generalizing" $ do
it "works" $ do
let src :: Int -> ConduitT () Int IO ()
src i = CL.sourceList [1..i]
sink :: ConduitT Int Void IO Int
sink = CL.fold (+) 0
res <- runConduit $ C.yield 10 .| C.awaitForever (C.toProducer . src) .| (C.toConsumer sink >>= C.yield) .| C.await
res `shouldBe` Just (sum [1..10])
describe "mergeSource" $ do
it "works" $ do
let src :: ConduitT () String IO ()
src = CL.sourceList ["A", "B", "C"]
withIndex :: ConduitT String (Integer, String) IO ()
withIndex = CI.mergeSource (CL.sourceList [1..])
output <- runConduit $ src .| withIndex .| CL.consume
output `shouldBe` [(1, "A"), (2, "B"), (3, "C")]
it "does stop processing when the source exhausted" $ do
let src :: ConduitT () Integer IO ()
src = CL.sourceList [1..]
withShortAlphaIndex :: ConduitT Integer (String, Integer) IO ()
withShortAlphaIndex = CI.mergeSource (CL.sourceList ["A", "B", "C"])
output <- runConduit $ src .| withShortAlphaIndex .| CL.consume
output `shouldBe` [("A", 1), ("B", 2), ("C", 3)]
describe "passthroughSink" $ do
it "works" $ do
ref <- I.newIORef (-1)
let sink = CL.fold (+) (0 :: Int)
conduit = C.passthroughSink sink (I.writeIORef ref)
input = [1..10]
output <- runConduit $ mapM_ C.yield input .| conduit .| CL.consume
output `shouldBe` input
x <- I.readIORef ref
x `shouldBe` sum input
it "does nothing when downstream does nothing" $ do
ref <- I.newIORef (-1)
let sink = CL.fold (+) (0 :: Int)
conduit = C.passthroughSink sink (I.writeIORef ref)
input = [undefined]
runConduit $ mapM_ C.yield input .| conduit .| return ()
x <- I.readIORef ref
x `shouldBe` (-1)
it "handles the last input correctly #304" $ do
ref <- I.newIORef (-1 :: Int)
let sink = CL.mapM_ (I.writeIORef ref)
conduit = C.passthroughSink sink (const (return ()))
res <- runConduit $ mapM_ C.yield [1..] .| conduit .| CL.take 5
res `shouldBe` [1..5]
x <- I.readIORef ref
x `shouldBe` 5
describe "mtl instances" $ do
it "ErrorT" $ do
let src = flip catchError (const $ C.yield 4) $ do
lift $ return ()
C.yield 1
lift $ return ()
C.yield 2
lift $ return ()
() <- throwError DummyError
lift $ return ()
C.yield 3
lift $ return ()
runConduit (src .| CL.consume) `shouldBe` Right [1, 2, 4 :: Int]
describe "WriterT" $
it "pass" $
let writer = W.pass $ do
W.tell [1 :: Int]
pure ((), (2:))
in execWriter (runConduit writer) `shouldBe` [2, 1]
describe "Data.Conduit.Lift" $ do
it "execStateC" $ do
let sink = C.execStateLC 0 $ CL.mapM_ $ modify . (+)
src = mapM_ C.yield [1..10 :: Int]
res <- runConduit $ src .| sink
res `shouldBe` sum [1..10]
it "execWriterC" $ do
let sink = C.execWriterLC $ CL.mapM_ $ tell . return
src = mapM_ C.yield [1..10 :: Int]
res <- runConduit $ src .| sink
res `shouldBe` [1..10]
it "runExceptC" $ do
let sink = C.runExceptC $ do
x <- C.catchExceptC (lift $ throwError "foo") return
return $ x ++ "bar"
res <- runConduit $ return () .| sink
res `shouldBe` Right ("foobar" :: String)
it "runMaybeC" $ do
let src = void $ C.runMaybeC $ do
C.yield 1
() <- lift $ MaybeT $ return Nothing
C.yield 2
sink = CL.consume
res <- runConduit $ src .| sink
res `shouldBe` [1 :: Int]
describe "sequenceSources" $ do
it "works" $ do
let src1 = mapM_ C.yield [1, 2, 3 :: Int]
src2 = mapM_ C.yield [3, 2, 1]
src3 = mapM_ C.yield $ repeat 2
srcs = C.sequenceSources $ Map.fromList
[ (1 :: Int, src1)
, (2, src2)
, (3, src3)
]
res <- runConduit $ srcs .| CL.consume
res `shouldBe`
[ Map.fromList [(1, 1), (2, 3), (3, 2)]
, Map.fromList [(1, 2), (2, 2), (3, 2)]
, Map.fromList [(1, 3), (2, 1), (3, 2)]
]
describe "zipSink" $ do
it "zip equal-sized" $ do
x <- runConduitRes $
CL.sourceList [1..100] .|
C.sequenceSinks [ CL.fold (+) 0,
(`mod` 101) <$> CL.fold (*) 1 ]
x `shouldBe` [5050, 100 :: Integer]
it "zip distinct sizes" $ do
let sink = C.getZipSink $
(*) <$> C.ZipSink (CL.fold (+) 0)
<*> C.ZipSink (Data.Maybe.fromJust <$> C.await)
x <- runConduitRes $ CL.sourceList [100,99..1] .| sink
x `shouldBe` (505000 :: Integer)
describe "upstream results" $ do
it "fuseBoth" $ do
let upstream = do
C.yield ("hello" :: String)
CL.isolate 5 .| CL.fold (+) 0
downstream = C.fuseBoth upstream CL.consume
res <- runConduit $ CL.sourceList [1..10 :: Int] .| do
(x, y) <- downstream
z <- CL.consume
return (x, y, z)
res `shouldBe` (sum [1..5], ["hello"], [6..10])
it "fuseBothMaybe with no result" $ do
let src = mapM_ C.yield [1 :: Int ..]
sink = CL.isolate 5 .| CL.fold (+) 0
(mup, down) <- runConduit $ C.fuseBothMaybe src sink
mup `shouldBe` (Nothing :: Maybe ())
down `shouldBe` sum [1..5]
it "fuseBothMaybe with result" $ do
let src = mapM_ C.yield [1 :: Int .. 5]
sink = CL.isolate 6 .| CL.fold (+) 0
(mup, down) <- runConduit $ C.fuseBothMaybe src sink
mup `shouldBe` Just ()
down `shouldBe` sum [1..5]
it "fuseBothMaybe with almost result" $ do
let src = mapM_ C.yield [1 :: Int .. 5]
sink = CL.isolate 5 .| CL.fold (+) 0
(mup, down) <- runConduit $ C.fuseBothMaybe src sink
mup `shouldBe` (Nothing :: Maybe ())
down `shouldBe` sum [1..5]
describe "catching exceptions" $ do
it "works" $ do
let src = do
C.yield 1
() <- Catch.throwM DummyError
C.yield 2
src' = do
CI.catchC src (\DummyError -> C.yield (3 :: Int))
res <- runConduit $ src' .| CL.consume
res `shouldBe` [1, 3]
describe "sourceToList" $ do
it "works lazily in Identity" $ do
let src = C.yield 1 >> C.yield 2 >> throw DummyError
let res = runIdentity $ C.sourceToList src
take 2 res `shouldBe` [1, 2 :: Int]
it "is not lazy in IO" $ do
let src = C.yield 1 >> C.yield (2 :: Int) >> throw DummyError
C.sourceToList src `shouldThrow` (==DummyError)
ZipConduit.spec
Stream.spec
it' :: String -> IO () -> Spec
it' = it
data DummyError = DummyError
deriving (Show, Eq, Typeable)
instance Catch.Exception DummyError