blastwind/random_code_snippets · Datasets at Hugging Face

lang stringclasses 10 values	seed stringlengths 5 2.12k
haskell	module P23a where run :: String -> Int run _ = 8 + 300 + 5000 + 20 + 7000 + 30 + 3 + 700 + 50 + 3 + 6 + 400
haskell	{-# htermination (snd :: Tup2 b a -> a) #-} import qualified Prelude data MyBool = MyTrue \| MyFalse data List a = Cons a (List a) \| Nil data Tup2 a b = Tup2 a b ; snd :: Tup2 a b -> b; snd (Tup2 vv y) = y;
haskell	exitText = "One day at a time." fenText :: G.Game -> String fenText game = unlines ["", C.writeFen game] newGame :: Parser State newGame = Parser (MC.string' "new game" $> (Play C.quickGame))
haskell	parseLine = readBoardingPass readNext :: Handle -> IO (Maybe BoardingPass) readNext handle = do done <- hIsEOF handle
haskell	{-# LANGUAGE CPP #-} {-# OPTIONS_GHC -DFOO="bar baz" #-} main = print FOO -- Test that GHC can compile option pragmas containing spaces. -- When a .hsc contains `#define FOO "bar baz"`, hsc2hs emits: -- -- {-# OPTIONS_GHC -optc-DFOO="bar baz" #-}
haskell	import Text.Printf (printf) import Language.Adder.Types -------------------------------------------------------------------------------- -- \| Convert a sequence of x86 `Instructions` into the output assembly -------------------------------------------------------------------------------- asm :: [Instruction] -> Text -------------------------------------------------------------------------------- asm instrs = header <> instrsAsm (instrs) <> "\n" instrsAsm :: [Instruction] -> Text instrsAsm = L.intercalate "\n" . map instrAsm header :: Text
haskell	module BugExportHeadings ( -- * Foo foo -- * Bar , bar -- * Baz , baz -- * One
haskell	-- An alternative nested representation -- -- \| An alternative nested representation for 'Value' that groups assets that -- share a 'PolicyId'. -- newtype ValueNestedRep = ValueNestedRep [ValueNestedBundle] deriving (Eq, Ord, Show) -- \| A bundle within a 'ValueNestedRep' for a single 'PolicyId', or for the -- special case of bcc. -- data ValueNestedBundle = ValueNestedBundleBcc Quantity \| ValueNestedBundle PolicyId (Map AssetName Quantity)
haskell	(CompInt x) == (CompInt y) = x == y (CompString x) == (CompString y) = x == y instance Ord Comparable where compare (CompInt x) (CompInt y) = compare x y compare (CompString x) (CompString y) = compare x y compare (CompInt x) (CompString y) = LT compare (CompString x) (CompInt y) = GT convert x = maybe (CompString x) CompInt (readMaybe (fromMaybe "" x)) toInt (CompInt x) = x toInt _ = 0
haskell	import qualified Pos.DHT.Model as DHT import Test.Pos.Helpers (binaryTest) spec :: Spec
haskell	import qualified Data.Set as S import Ganeti.Errors import Ganeti.JSON (GenericContainer(..), Container) import Ganeti.Objects import Ganeti.Types import Ganeti.Utils
haskell	-- \| Definition of a chronomorphism as an hylomorphism. -- -- This recursion pattern subsumes histomorphisms, futumorphisms and dynamorphisms -- and can be seen as the natural hylomorphism generalization from composing an histomorphism after a futumorphism. -- Therefore, chronomorphisms can 'look back' when consuming a type and 'jump forward' when generating one, via it's fold/unfold operations, respectively. --
haskell	{- f (xs) { f (xs) {} ... while (1) { return f(es) ... ... xs = es; continue; } ... } } -} isTailRecursive f (CBind False [(_, Val t (ECall g _ _))] (CRet (ENew (Tuple 0 _) _ _))) \| t == tUNIT = f == g
haskell	FugitiveMove t -> MultiSet.delete t ft Reveal t _ -> MultiSet.delete t ft DoubleMove move1 move2 -> applyMoveFugitiveTickets move2 (applyMoveFugitiveTickets move1 ft) applyMoveDoubles :: Move -> Int -> Int applyMoveDoubles (DoubleMove m1 m2) dm = applyMoveDoubles m2 (applyMoveDoubles m1 (dm-1)) applyMoveDoubles _ dm = dm
haskell	module Mod where data Mod instance Num Mod where
haskell	diTransform f = let Done _ r = test1 (traceShow f f) in TL.pack $ listToString $ r ++ [TL.unpack $ TL.stripEnd f]
haskell	p _ Nothing = "" cc :: [String] -> String cc [] = mempty cc a = " {" ++ intercalate ", " (filter (not . null) a) ++ "}" instance T.ToJSON MessageCopyOptions where toJSON MessageCopyOptions { new_caption = new_caption, replace_caption = replace_caption, send_copy = send_copy } = A.object [ "@type" A..= T.String "messageCopyOptions", "new_caption" A..= new_caption, "replace_caption" A..= replace_caption, "send_copy" A..= send_copy ] instance T.FromJSON MessageCopyOptions where parseJSON v@(T.Object obj) = do t <- obj A..: "@type" :: T.Parser String case t of
haskell	e'iter = poly1 (\t zero -> eλ (t --> t) (\step -> eλ t'nat (\nat -> (nat %:: t) .: zero .: step))) e'const :: Exp e'const = eλ t'nat (\nat -> e'succ .: e'zero) -- \| basic iteration example -- >>> typecheck e'count == t'nat -- True
haskell	>>= \ (err, res) -> throwIfErr err >> fromGodotVariant res) {-# NOINLINE bindRemoteTransform_set_remote_node #-} -- \| The [NodePath] to the remote node, relative to the RemoteTransform's position in the scene. bindRemoteTransform_set_remote_node :: MethodBind bindRemoteTransform_set_remote_node = unsafePerformIO $ withCString "RemoteTransform" $ \ clsNamePtr ->
haskell	import Distribution.Simple haq = defaultMain
haskell	import Hasmin.Parser.Dimension import Hasmin.Parser.PercentageLength import Hasmin.Types.Gradient import Hasmin.Utils radialgradient :: Parser Gradient radialgradient = functionParser $ do
haskell	context "Server Var" $ do it "requires a non-empty default" $ isRight validServerVar `shouldBe` True it "requires non-empty enums, when present" $ invalidServerVarEnum `shouldBe` Left InvalidEnum it "requires a non-empty description, when present" $ invalidServerVarDescription `shouldBe` Left InvalidDescriptionSV context "Server" $ do it "requires an URL" $ isRight validServer `shouldBe` True it "requires a non-empty description, when present" $ invalidServerDescription `shouldBe` Left InvalidDescriptionS it "requires valid server vars, when present" $ invalidServerVar `shouldBe` Left (InvalidServerVar InvalidDescriptionSV)
haskell	in_a_block x l = not(free x l) diff_blocks :: Int -> Int -> [Int] -> Bool diff_blocks x y xs = abs(posx-posy) /= abs(x-y) where posx = indexOf x xs -1 posy = indexOf y xs -1 first_of_block :: Int -> [Int] -> Bool first_of_block x l \| indexOf x l == 0 = False \| (prev == 0) = is_an_adjacency x next len \| otherwise = (not (is_an_adjacency prev x len) && is_an_adjacency x next len) where prev = return_nth' ((indexOf x l) - 1) l
haskell	} deriving (Show) makeLenses ''Node
haskell	oscillator :: Int -> Vector Double -> StochasticOscillator oscillator l v = let o = oscV l v os = Vec.map snd o tp = mavg (WindowSize 3) os l' = fromIntegral l f (j, x) = (j+l', x) in StochasticOscillator { osc = o
haskell	import Control.Lens (over, _1, _2) import Data.Either.Validation import Grammar.Common import qualified Grammar.Greek.Morph.ShouldElide.Round as Round import Grammar.Greek.Morph.ShouldElide.Types import Grammar.Greek.Morph.Types import Grammar.Greek.Script.Types
haskell	-- Programming, part 1. We'll be developing a sort of functional image -- library together. This file is made up of explanations (like this) -- and some prepared code. Some definitions you'll have to fill in -- yourself, just like in the previous exercise sets. -- We'll use the JuicyPixels library to generate images. The library -- exposes the Codec.Picture module that has everything we need. import Codec.Picture -- Let's start by defining Colors and Pictures. -- A Color is just three numbers: the red, green and blue components. -- We use Ints for convenience even though the valid range is only
haskell	contents <- readFile "1.lvl" stdGen <- newStdGen let rows = words contents let initialState = Game { level = rows, initialLevel = rows, playerPos = playerInitialPos, playerVel = playerInitialVel, seconds = 0, gen = stdGen, paused = False, gameState = Playing, bounce = False, cameraPos = cameraInitialPos} print rows
haskell	main :: IO () main = hspec spec spec :: Spec spec = do describe "VirtualArrow.Indices.gallagherIndex" $ do it "should be 0 in case of oneDistrictProportionality" $
haskell	-- depending on the current 'temperature'. The temperature is gradually -- reduced according to an annealing schedule, making random jumps less likely -- as the algorithm progresses. simulatedAnnealing :: (Problem p s a) => Schedule -> p s a -> IO (Node s a) simulatedAnnealing schedule prob = go 0 (root prob) where go k current = let t = schedule k in if t == 0 then return current
haskell	module Foobar (foobar) where foobar :: Int foobar = 42
haskell	deriving (Show, Eq) data Adjective = Payer \| Payee
haskell	let e2 = removeAnnotations (textToCheckedExpr e1) let e3 = toCoDBExpr e2 let e4 = fromCoDB e3 let errorMessage = layoutAsString $ "Expected:" <+> line <> indent 2 ( squotes (prettyVerbose e2) <> line <> squotes (prettyVerbose e4)) <> line <> "to be equal" <>
haskell	main = do let limit = 2000000 let primes = filter isPrime [1..limit] let primeSum = sum primes print primeSum
haskell	\| ref < ct && rf `Map.member` mp = return $ mp Map.! rf \| ref >= ct = throwHeapErrorWithStepInfoSTE (\ _ -> HeapLookupOutOfBounds) \| otherwise {- invalid heap ref -} = throwHeapErrorWithStepInfoSTE(\ _ -> InvalidHeapLookup) --- this doesn't validate Heap and heap allocator correctness, VERY UNSAFE :) unsafeRunHSCM :: Natural -> Heap val -> HeapStepCounterM val m b -> m (b,CounterAndHeap val ) unsafeRunHSCM cnt hp (HSCM m) = State.runStateT m (CounterAndHeap 0 0 cnt hp)
haskell	case infer env ctx t of Left err -> Left (TypeErr i err) Right v -> Right (Map.insert x v env, ctx) runRepl i (env, ctx) (DefineCheck x a t) = if x `Map.member` env then Left (EnvErr i x) else case check env ctx a (NfS (Type 0)) of Left err -> case check env ctx a (NfS (Type 1)) of Left err -> Left (TypeErr i err) Right a -> case check env ctx t a of Left err -> Left (TypeErr i err)
haskell	readProb :: FilePath -> IO State readProb path = return . initState =<< BL.readFile path initState :: ByteString -> State initState = either error initialState . parseTask . BL.init
haskell	tuple = [(1, 'a', "asdf"), (2, 'b', "asdf")] -- CAUTION: fst, snd, zip only work on pairs fst tuple -- return its first element snd tuple -- return its second element
haskell	import Control.Monad import Foreign import Foreign.C import Foreign.Marshal.Utils import Foreign.Storable #include "pg_query.h" instance Storable PgQueryError where
haskell	double :: Int -> Int double x = x + x recSum :: Num a => [a] -> a recSum [] = 0 recSum (n:ns) = n + sum ns qsort :: Ord a => [a] -> [a] qsort [] = [] qsort (x:xs) = qsort smaller ++ [x] ++ qsort larger
haskell	-- \| Compose given list of monadic functions withFold :: Monad m => [m a -> m a] -> m a -> m a withFold = foldr (.) id -- \| Turn list into sequence of monadic computations that is then composed withFoldMap :: Monad m => (a -> m b -> m b) -> [a] -> m b -> m b withFoldMap f = withFold . map f
haskell	import Ivory.BSP.STM32L471.MemoryMap import qualified Ivory.BSP.STM32L471.Interrupt as L471 import Ivory.BSP.STM32.Peripheral.RTC rtc :: RTC rtc = mkRTC rtc_periph_base rccenable rccdisable -- L471.RTC_TAMP_STAMP L471.RTC_WKUP L471.RTC_ALARM
haskell	runPlayerAction phase playerId game act = do phaseIs phase game playerIs playerId game getPlayerAction (act playerId game) preSetupAction = runPlayerAction PreSetup setupAction = runPlayerAction Setup
haskell	let m = defaultMaterial let pos = RTCTuple.point 0.0 0.0 0.0 let eyev = RTCTuple.vector 0.0 0.0 (-1.0) let normalv = RTCTuple.vector 0.0 0.0 (-1.0) let light1 = pointLight (Color (1.0,1.0, 1.0 )) (RTCTuple.point 0.0 0.0 (-10.0)) let result = lighting m light1 pos eyev normalv it "result = Color (1.9,1.9,1.9)" $ (Color (1.9, 1.9, 1.9)) ==result `shouldBe` True
haskell	-- Reimplemente a função bin2Int utilizando foldr. type Bit = Int bin2IntFoldr :: [Bit] -> Int bin2IntFoldr = foldr (\ x y -> x + 2 * y ) 0
haskell	module Graphics.GL.AMD.SamplePositions ( -- * Extension Support glGetAMDSamplePositions, gl_AMD_sample_positions, -- * Enums pattern GL_SUBSAMPLE_DISTANCE_AMD, -- * Functions glSetMultisamplefvAMD ) where import Graphics.GL.ExtensionPredicates import Graphics.GL.Tokens
haskell	module CommandLine (askQuestion, askStr, askOption) where askQuestion :: (Read a) => String -> IO a askQuestion = askQuestion' read askStr :: String -> IO String
haskell	it "returns beckon module name" $ N.addBeckonPrefix "beckon.steel.answerPage" `shouldBe` "beckon.steel.answerPage" it "returns beckon module name" $ N.addBeckonPrefix "steel.answerPage" `shouldBe` "beckon.steel.answerPage" describe "getSrcFilePath" $ do it "returns a correct JS file path" $ N.getSrcFilePath Common.FileType.JavaScript "steel.answerPage" `shouldBe`
haskell	identity :: a -> a identity = Prelude.id type ParseError = Text type ParseResult = Either ParseError [ParsedBankRow] type StatementText = ByteString data Handle = Handle
haskell	-- Author: <NAME> <<EMAIL>> module KS.Clean.Old.Options ( OldOptions (..) ) where import KS.Clean.Types data OldOptions = OldOptions { optBeforeDate :: Maybe Date , optArchive :: ShouldArchive , optConfDir :: ConfDir }
haskell	Day10.part2 putStr "\n" putStrLn "-- Day 11 --" putStr "Day 11 Part 1 - Result: " Day11.part1 putStr "Day 11 Part 2 - Result: " Day11.part2 putStr "\n" putStrLn "-- Day 12 --" putStr "Day 12 Part 1 - Result: " Day12.part1 putStr "Day 12 Part 2 - Result: "
haskell	ircFormat' C_B = "\x02" ircFormat' Br = "\n" ircFormat' I = "\x1D" ircFormat' C_I = "\x1D" ircFormat' U = "\x1F" ircFormat' C_U = "\x1F" ircFormat' x = damnFormat' x
haskell	level2TestCases = [ ("Single claim should be the claim itself", ["#1 @ 1,3: 4x4"], 1) , ("Given test case", ["#1 @ 1,3: 4x4", "#2 @ 3,1: 4x4", "#3 @ 5,5: 2x2"], 3) ] level2Tests = TestLabel "Level 2" $ TestList (map (makeTestWithLines level2) level2TestCases)
haskell	primalPivot :: Tableau -> Either PivotError Tableau primalPivot (Tableau deref objective context) = do let isOptimal :: Bool isOptimal = Map.null (Map.filter (< 0) objective) when isOptimal (throwError IsOptimal) let entry :: VarName entry = let go :: VarName -- Objective variable
haskell	, ("lparen" , lparen) , ("nil" , nil) , ("of" , fo) , ("rbrack" , rbrack) , ("rparen" , rparen) , ("tick" , tick) , ("underscore" , underscore)
haskell	type Stop = Int data Move = DetectiveMove Detective Ticket Stop \| NullMove Detective Stop \| FugitiveMove Ticket \| Reveal Ticket Stop \| DoubleMove Move Move deriving (Show, Read, Eq) data Player = MrX \| Detectives deriving (Show,Eq)
haskell	spec :: Spec spec = do describe "decodeUtf8" $ do it "is inverse to encodeUtf8" $ do property $ \xs -> (decodeUtf8 . encodeUtf8) xs `shouldBe` xs
haskell	comboTwo _ = [] palindromeProducts :: [[Integer]] -> [Integer] palindromeProducts l = filter isPalindrome (map product l)
haskell	, backend ) where import Control.Lens import Data.Aeson import Data.Text (Text) import Network.HTTP.Types.Header
haskell	,"LinkKeeper (lnkp) Command help" ,"----------(Commands)----------" ,"help \| shows this page" ,"list \| Lists stored links" ,"add (link text) \| adds link to list" ,"open (link number) \| opens link by number" ,"remove (link number) \| removes link by number" ,"-----------------------------" ,""]
haskell	newCommand (n, d, a) = Cmd { cmd = n, desc = d, runner = a } commands' :: [(String, String, ActionRunner)] commands' = [ ( "->" , "Post a message for a new or existing User. Usage: <@user> -> <message>" , postRunner ) , ( "" , "Displays the User's Posts. Usage: <@user>"
haskell	module IR where import Data.Text.Prettyprint.Doc import Data.Text.Prettyprint.Doc.Internal import Data.Text.Prettyprint.Doc.Util import qualified Data.Set as S import qualified Control.Monad.State as ST import qualified Data.Map.Strict as M import qualified OrderedMap as OM import Data.List (elemIndex) import Control.Monad(guard)
haskell	data Nibbles = Nibbles {-# UNPACK #-} !Int -- ^ offset (zero based index of first nibble) -- -- prop> let (Nibbles o _ _) in 0 <= o -- prop> let (Nibbles o l d) in o + l <= 2 * length d -- {-# UNPACK #-} !Int -- ^ length -- -- prop> let (Nibbles _ l _) in 0 <= l
haskell	{-# Language TypeSynonymInstances, TypeFamilies, FlexibleInstances, GeneralizedNewtypeDeriving #-} module Plush.Run.ShellExec ( VarScope(..), VarMode(..), VarEntry, ShellState(), initialShellState,
haskell	-- disc :: Position -> R -> sh :~> Position disc (originX, originY, originZ) radiusMax _ix gen = do radius <- uniformR (0,radiusMax) gen theta <- uniformR (0, pi) gen phi <- uniformR (0, 2pi) gen return ( originX + radius sin theta * cos phi , originY + radius * sin theta * sin phi , originZ + radius * cos theta )
haskell	relBase (newXs, output) where newCursorPosition = if newValPosition == position then position else position + 2 newXs = take newValPosition xs ++ head input : drop (newValPosition + 1) xs newValPosition = xs !! arg1 -- a -> out
haskell	x <- atomically $ PQ.deleteMin pq putStrLn $ "x = " ++ show x -- prints 2 @ -} module Data.STM.PriorityQueue.Class ( PriorityQueue(..) ) where import Control.Concurrent.STM class PriorityQueue q where -- \| /O(1)/. Creates empty priority queue. new :: (Ord k) => STM (q k v)
haskell	pure fa {-# INLINE (=<<&) #-} -- The void function implemented with Functor / Applicative or Monad is slow. -- GHC cannot optimize it, especially when using in IO monad, it could slow -- down function even more than 10 times (!). void :: m a -> m () void = unsafeCoerce ; {-# INLINE void #-} when , unless :: (Applicative m, Mempty a) => Bool -> m a -> m a when_ , unless_ :: (Applicative m) => Bool -> m a -> m () whenM , unlessM :: (Monad m , Mempty a) => m Bool -> m a -> m a whenM_, unlessM_ :: (Monad m ) => m Bool -> m a -> m () when p s = ifThenElse p s (pure mempty) ; {-# INLINE when #-}
haskell	--- ENVIRONMENT MANAGEMENT --- type EnvParser = StateT Env Parser parseEnv :: EnvParser a -> BS -> Either String (Env, BS) parseEnv f = toEither `o` parse $ runStateT f initialEnv where toEither (Fail{}) = Left "Header parsing failure" toEither (Partial _) = Left "Consumed all input while parsed header" toEither (Done r (_, env)) = Right (env, r)
haskell	Copyright : (c) 2020 <NAME> License : BSD3 Maintainer : <NAME> <<EMAIL>> Stability : experimental Portability : portable Language : Haskell2010 -}
haskell	import Test.Tasty names :: TestTree names =
haskell	isbn xs = verify $ mapMaybe parse xs where parse c \| c == 'X' = Just 10 \| isDigit c = Just $ digitToInt c \| otherwise = Nothing verify :: [Int] -> Bool verify xs@[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10] = (x1 * 10 + x2 * 9 + x3 * 8 + x4 * 7 + x5 * 6 + x6 * 5 + x7 * 4 + x8 * 3 + x9 * 2 + x10) `mod` 11 == 0 && all (< 10) (take 9 xs) verify _ = False
haskell	S2 :: { fs1 :: a } -> S a updS s x = s { fs1=x } ------------------ GADT data T a b where T1 :: { ft1 :: a, ft2 :: c, ft3 :: d } -> T a Int T2 :: { ft1 :: a, ft3 :: c } -> T a Int T3 :: T Int b f :: T a1 b -> a2 -> T a2 b f x v = x { ft1 = v } ------------------ Type family data family R a
haskell	module Alpaca.View.Layout ( renderWithLayout ) where import Data.Text.Lazy (Text) import Text.Blaze.Html5 as H import Text.Blaze.Html5.Attributes as A renderWithLayout :: Text -> Html -> Html renderWithLayout title body = docTypeHtml $ do H.head $ do H.title $ toHtml title H.body body
haskell	-- \| Constraint representing the fact that the field @x@ can be get and set on -- the record type @r@ and has field type @a@. This constraint will be solved -- automatically, but manual instances may be provided as well. -- -- The function should satisfy the invariant: -- -- > uncurry ($) (hasField @x r) == r
haskell	scalar :: ScalarType s -> s -> LLVM.Constant scalar (SingleScalarType s) = single s scalar (VectorScalarType s) = vector s single :: SingleType s -> s -> LLVM.Constant single (NumSingleType s) = num s vector :: VectorType s -> s -> LLVM.Constant vector (VectorType _ s) (Vec ba#) = LLVM.Vector
haskell	-> a -> Int -> Int -> a -> a -> a -> vector (Complex a) gaussianPinwheel1 numR2Freqs periodR2 stdR2 sigma thetaFreq rFreq periodEnv stdTheta stdR = let a = 1 / (stdR2 * sqrt 2) in VG.concat . parMap rdeepseq (\(radialFreq, angularFreq) -> let pinwheel = centerHollowArray numR2Freqs $
haskell	singleton = Singleton (<:>) :: a -> NonEmptyList a -> NonEmptyList a x <:> xs = Cons x xs instance Functor NonEmptyList where fmap f (Singleton a) = Singleton (f a) fmap f (Cons x xs) = Cons (f x) (fmap f xs)
haskell	Maintainer : <EMAIL> Stability : experimental Portability : POSIX This is an experimental API. Nakadi-client provides a 'MonadNakadi' instance for the 'IO' monad accessing a global mutable configuration. This module exports the user-visible API for managing this global configuration.
haskell	import Ivory.BSP.STM32F412.SYSCFG.Peripheral import Ivory.BSP.STM32F412.SYSCFG.Regs import Ivory.BSP.STM32F412.RCC import Ivory.BSP.STM32F412.MemoryMap (syscfg_periph_base) syscfg :: SYSCFG syscfg = mkSYSCFG syscfg_periph_base rccenable rccdisable where rccenable = modifyReg rcc_reg_apb2enr $ setBit rcc_apb2enr_syscfgen
haskell	-- a member of the graph. maybeVertex :: k -> Maybe G.Vertex } -- \| The node for the given key. Return Nothing if the key is not -- a member of the graph. maybeNode :: DAG k v -> k -> Maybe v maybeNode DAG{..} k = _1 . nodeDesc <$> maybeVertex k {-# INLINE maybeNode #-} -- \| The edge list for the given key. Return Nothing if the key is not -- a member of the graph. maybeEdges :: DAG k v -> k -> Maybe [k] maybeEdges DAG{..} k = _3 . nodeDesc <$> maybeVertex k {-# INLINE maybeEdges #-}
haskell	newTask title taskTime "" tags = Task { _taskHeadingL = Heading title taskTime , _taskDescL = Nothing , _taskTagsL = Tags tags } newTask title taskTime desc tags = Task { _taskHeadingL = Heading title taskTime , _taskDescL = Just $ Desc desc , _taskTagsL = Tags tags } completeTask :: Time -> Task -> Task completeTask t = taskHeadingL . taskTimeL . timeEndL %~ (<\|> Just t)
haskell	query conn lookupTargets (Only websiteID) where lookupTargets = "SELECT TargetID, UserID, WebsiteID, Selector, Hash, Content " <> "FROM Targets " <> "WHERE websiteID = ?"
haskell	import qualified Lib.Client.Translation.Translation as ClientTranslation import qualified Lib.Model.Data as Data import Graphics.UI.Threepenny.Core import qualified Graphics.UI.Threepenny as UI data Picker = Picker { _container :: Element , _selection :: Event ()
haskell	factorial :: (Integral a) => a -> a factorial 0 = 1 factorial n = n * factorial (n-1) calcBmis :: (RealFloat a) => [(a,a)] -> [a] calcBmis xs = [bmi w h \| (w,h) <- xs]
haskell	generateInputFile :: forall arch abi i o. (InSymbol arch abi ~ i, U.Universe i, Show i) => FilePath -> FSTGenerator arch abi -> IO () generateInputFile fp fst = Sys.withFile fp Sys.WriteMode $ \file ->
haskell	module WiredTiger.Raw.Context where import qualified Data.Map.Strict as Map import Language.C.Inline.Context import Language.C.Types import WiredTiger.Raw.Types wiredtigerCtx :: Context wiredtigerCtx = mempty { ctxTypesTable = Map.fromList
haskell	, magnify' ) where import Universum import Control.Monad.Identity (Identity) import Control.Monad.Trans.Except (ExceptT, mapExceptT) import Lens.Micro.Mtl ((.=)) import Lens.Micro as L import Lens.Micro.Mtl as LM import Lens.Micro.Mtl.Internal as LMI -- I don't know how to call these operators
haskell	`shouldBe` (Just mockItem, [[GetItem existingItemId]]) it "should return Nothing, if the Item does not belong to user" $ runTest (getItemBelongingToUserId existingItemId 456 mockEnv) `shouldBe` (Nothing, [[GetItem existingItemId]]) it "should return Nothing, if the Item does not exist" $ runTest (getItemBelongingToUserId 123 existingItemUserId mockEnv)
haskell	let masses = map read input :: [Int] let partOne = sum (map fuel masses) let partTwo = sum (map revisedFuel masses) print partOne print partTwo fuel :: Int -> Int fuel m = m `div` 3 - 2 -- Why greater than 5? Because 5 `div` - 2 = 0, and the puzzle tells us to -- treat values lower than 0 as 0 revisedFuel :: Int -> Int revisedFuel m
haskell	-- Stability : provisional -- Portability : portable -- -- This module corresponds to chapter 6 (AL Contexts and the ALC API) of the -- OpenAL Specification and Reference (version 1.1). --
haskell	trominoTilingLinks :: Links trominoTilingLinks = (items, [], options) where items = monomino ++ squares monomino = [ it "m" ] squares = [ it $ show r ++ show c \| r <- [0..7], c <- [0..7] ] -- m 00 -- m 01 -- .. -- 00 01 02 -- 00 10 20 options = monominoes ++ trominoes
haskell	module Andromeda.Simulator ( module X ) where import Andromeda.Simulator.Types as X import Andromeda.Simulator.Actions as X import Andromeda.Simulator.Runtime as X import Andromeda.Simulator.Internal.SimulationCompiler as X
haskell	deriveSafeStore ''UUID -- orphans from filesystem-path instance Binary FilePath where put = Binary.put . F.encodeString get = F.decodeString <$> Binary.get instance SafeCopy FilePath where version = 1 kind = base errorTypeName _ = "Filesystem.Path.FilePath" putCopy = contain . safePut . F.encodeString getCopy = contain $ F.decodeString <$> safeGet
haskell	shouldBe (encodeDigestWith b $ f s) h -- \| Test that Nix-like base32 encoding roundtrips prop_nixBase32Roundtrip :: Property prop_nixBase32Roundtrip = forAllShrink nonEmptyString genericShrink $ \x -> pure (encodeUtf8 x) === (B32.decode . B32.encode . encodeUtf8 $ x) -- \| API variants prop_nixBase16Roundtrip :: StorePathHashPart -> Property prop_nixBase16Roundtrip x = pure (coerce x) === decodeWith Base16 (encodeWith Base16 $ coerce x) -- \| Hash encoding conversion ground-truth. -- Similiar to nix/tests/hash.sh spec_nixhash :: Spec spec_nixhash = do
haskell	-- (Cons p1 (Cons p4 (Cons p2 (Cons p3 Nil)))) } @-} -- testAlternate3 = trivial -- {-@ testAlternate4 :: { -- alternate Nil (Cons p8 (Cons p9 Nil)) = -- (Cons p8 (Cons p9 Nil)) } @-} -- testAlternate4 = trivial
haskell	g2i :: GoodsTile -> String g2i (GoodsTile (Dice i)) = " " ++ show i ++ " " --Maybe Goods to Initials mg2i :: Maybe GoodsTile -> String mg2i Nothing = " " mg2i (Just g) = g2i g
haskell	data Method = DELETE \| GET \| POST \| PUT deriving (Eq, Ord, Read, Show) -- \| Braintree Request Parameters data BraintreeParameter = BTDict [(ByteString, BraintreeParameter)] \| BTList [BraintreeParameter] \| BTBool Bool \| BTInt Int
haskell	module Luna.Std where import Luna.Prelude import Data.Map (Map) import qualified Data.Map as Map
haskell	import qualified Data.Binary.Get as Binary import qualified Data.ByteString.Lazy as BS import qualified Data.ByteString.Lazy.Builder as BS import qualified Data.Text.Lazy as L import qualified Data.Text.Lazy.Encoding as L import qualified Network.Socket as N hiding ( recv ) import qualified Network.Socket.ByteString.Lazy as N

haskell

module P23a where run :: String -> Int run _ = 8 + 300 + 5000 + 20 + 7000 + 30 + 3 + 700 + 50 + 3 + 6 + 400

haskell

{-# htermination (snd :: Tup2 b a -> a) #-} import qualified Prelude data MyBool = MyTrue | MyFalse data List a = Cons a (List a) | Nil data Tup2 a b = Tup2 a b ; snd :: Tup2 a b -> b; snd (Tup2 vv y) = y;

haskell

exitText = "One day at a time." fenText :: G.Game -> String fenText game = unlines ["", C.writeFen game] newGame :: Parser State newGame = Parser (MC.string' "new game" $> (Play C.quickGame))

haskell

parseLine = readBoardingPass readNext :: Handle -> IO (Maybe BoardingPass) readNext handle = do done <- hIsEOF handle

haskell

{-# LANGUAGE CPP #-} {-# OPTIONS_GHC -DFOO="bar baz" #-} main = print FOO -- Test that GHC can compile option pragmas containing spaces. -- When a .hsc contains `#define FOO "bar baz"`, hsc2hs emits: -- -- {-# OPTIONS_GHC -optc-DFOO="bar baz" #-}

haskell

import Text.Printf (printf) import Language.Adder.Types -------------------------------------------------------------------------------- -- | Convert a sequence of x86 `Instructions` into the output assembly -------------------------------------------------------------------------------- asm :: [Instruction] -> Text -------------------------------------------------------------------------------- asm instrs = header <> instrsAsm (instrs) <> "\n" instrsAsm :: [Instruction] -> Text instrsAsm = L.intercalate "\n" . map instrAsm header :: Text

haskell

module BugExportHeadings ( -- * Foo foo -- * Bar , bar -- * Baz , baz -- * One

haskell

-- An alternative nested representation -- -- | An alternative nested representation for 'Value' that groups assets that -- share a 'PolicyId'. -- newtype ValueNestedRep = ValueNestedRep [ValueNestedBundle] deriving (Eq, Ord, Show) -- | A bundle within a 'ValueNestedRep' for a single 'PolicyId', or for the -- special case of bcc. -- data ValueNestedBundle = ValueNestedBundleBcc Quantity | ValueNestedBundle PolicyId (Map AssetName Quantity)

haskell

(CompInt x) == (CompInt y) = x == y (CompString x) == (CompString y) = x == y instance Ord Comparable where compare (CompInt x) (CompInt y) = compare x y compare (CompString x) (CompString y) = compare x y compare (CompInt x) (CompString y) = LT compare (CompString x) (CompInt y) = GT convert x = maybe (CompString x) CompInt (readMaybe (fromMaybe "" x)) toInt (CompInt x) = x toInt _ = 0

haskell

import qualified Pos.DHT.Model as DHT import Test.Pos.Helpers (binaryTest) spec :: Spec

haskell

import qualified Data.Set as S import Ganeti.Errors import Ganeti.JSON (GenericContainer(..), Container) import Ganeti.Objects import Ganeti.Types import Ganeti.Utils

haskell

-- | Definition of a chronomorphism as an hylomorphism. -- -- This recursion pattern subsumes histomorphisms, futumorphisms and dynamorphisms -- and can be seen as the natural hylomorphism generalization from composing an histomorphism after a futumorphism. -- Therefore, chronomorphisms can 'look back' when consuming a type and 'jump forward' when generating one, via it's fold/unfold operations, respectively. --

haskell

{- f (xs) { f (xs) {} ... while (1) { return f(es) ... ... xs = es; continue; } ... } } -} isTailRecursive f (CBind False [(_, Val t (ECall g _ _))] (CRet (ENew (Tuple 0 _) _ _))) | t == tUNIT = f == g

haskell

FugitiveMove t -> MultiSet.delete t ft Reveal t _ -> MultiSet.delete t ft DoubleMove move1 move2 -> applyMoveFugitiveTickets move2 (applyMoveFugitiveTickets move1 ft) applyMoveDoubles :: Move -> Int -> Int applyMoveDoubles (DoubleMove m1 m2) dm = applyMoveDoubles m2 (applyMoveDoubles m1 (dm-1)) applyMoveDoubles _ dm = dm

haskell

module Mod where data Mod instance Num Mod where

haskell

diTransform f = let Done _ r = test1 (traceShow f f) in TL.pack $ listToString $ r ++ [TL.unpack $ TL.stripEnd f]

haskell

p _ Nothing = "" cc :: [String] -> String cc [] = mempty cc a = " {" ++ intercalate ", " (filter (not . null) a) ++ "}" instance T.ToJSON MessageCopyOptions where toJSON MessageCopyOptions { new_caption = new_caption, replace_caption = replace_caption, send_copy = send_copy } = A.object [ "@type" A..= T.String "messageCopyOptions", "new_caption" A..= new_caption, "replace_caption" A..= replace_caption, "send_copy" A..= send_copy ] instance T.FromJSON MessageCopyOptions where parseJSON v@(T.Object obj) = do t <- obj A..: "@type" :: T.Parser String case t of

haskell

e'iter = poly1 (\t zero -> eλ (t --> t) (\step -> eλ t'nat (\nat -> (nat %:: t) .: zero .: step))) e'const :: Exp e'const = eλ t'nat (\nat -> e'succ .: e'zero) -- | basic iteration example -- >>> typecheck e'count == t'nat -- True

haskell

>>= \ (err, res) -> throwIfErr err >> fromGodotVariant res) {-# NOINLINE bindRemoteTransform_set_remote_node #-} -- | The [NodePath] to the remote node, relative to the RemoteTransform's position in the scene. bindRemoteTransform_set_remote_node :: MethodBind bindRemoteTransform_set_remote_node = unsafePerformIO $ withCString "RemoteTransform" $ \ clsNamePtr ->

haskell

import Distribution.Simple haq = defaultMain

haskell

import Hasmin.Parser.Dimension import Hasmin.Parser.PercentageLength import Hasmin.Types.Gradient import Hasmin.Utils radialgradient :: Parser Gradient radialgradient = functionParser $ do

haskell

context "Server Var" $ do it "requires a non-empty default" $ isRight validServerVar `shouldBe` True it "requires non-empty enums, when present" $ invalidServerVarEnum `shouldBe` Left InvalidEnum it "requires a non-empty description, when present" $ invalidServerVarDescription `shouldBe` Left InvalidDescriptionSV context "Server" $ do it "requires an URL" $ isRight validServer `shouldBe` True it "requires a non-empty description, when present" $ invalidServerDescription `shouldBe` Left InvalidDescriptionS it "requires valid server vars, when present" $ invalidServerVar `shouldBe` Left (InvalidServerVar InvalidDescriptionSV)

haskell

in_a_block x l = not(free x l) diff_blocks :: Int -> Int -> [Int] -> Bool diff_blocks x y xs = abs(posx-posy) /= abs(x-y) where posx = indexOf x xs -1 posy = indexOf y xs -1 first_of_block :: Int -> [Int] -> Bool first_of_block x l | indexOf x l == 0 = False | (prev == 0) = is_an_adjacency x next len | otherwise = (not (is_an_adjacency prev x len) && is_an_adjacency x next len) where prev = return_nth' ((indexOf x l) - 1) l

haskell

} deriving (Show) makeLenses ''Node

haskell

oscillator :: Int -> Vector Double -> StochasticOscillator oscillator l v = let o = oscV l v os = Vec.map snd o tp = mavg (WindowSize 3) os l' = fromIntegral l f (j, x) = (j+l', x) in StochasticOscillator { osc = o

haskell

import Control.Lens (over, _1, _2) import Data.Either.Validation import Grammar.Common import qualified Grammar.Greek.Morph.ShouldElide.Round as Round import Grammar.Greek.Morph.ShouldElide.Types import Grammar.Greek.Morph.Types import Grammar.Greek.Script.Types

haskell

-- Programming, part 1. We'll be developing a sort of functional image -- library together. This file is made up of explanations (like this) -- and some prepared code. Some definitions you'll have to fill in -- yourself, just like in the previous exercise sets. -- We'll use the JuicyPixels library to generate images. The library -- exposes the Codec.Picture module that has everything we need. import Codec.Picture -- Let's start by defining Colors and Pictures. -- A Color is just three numbers: the red, green and blue components. -- We use Ints for convenience even though the valid range is only

haskell

contents <- readFile "1.lvl" stdGen <- newStdGen let rows = words contents let initialState = Game { level = rows, initialLevel = rows, playerPos = playerInitialPos, playerVel = playerInitialVel, seconds = 0, gen = stdGen, paused = False, gameState = Playing, bounce = False, cameraPos = cameraInitialPos} print rows

haskell

main :: IO () main = hspec spec spec :: Spec spec = do describe "VirtualArrow.Indices.gallagherIndex" $ do it "should be 0 in case of oneDistrictProportionality" $

haskell

-- depending on the current 'temperature'. The temperature is gradually -- reduced according to an annealing schedule, making random jumps less likely -- as the algorithm progresses. simulatedAnnealing :: (Problem p s a) => Schedule -> p s a -> IO (Node s a) simulatedAnnealing schedule prob = go 0 (root prob) where go k current = let t = schedule k in if t == 0 then return current

haskell

module Foobar (foobar) where foobar :: Int foobar = 42

haskell

deriving (Show, Eq) data Adjective = Payer | Payee

haskell

let e2 = removeAnnotations (textToCheckedExpr e1) let e3 = toCoDBExpr e2 let e4 = fromCoDB e3 let errorMessage = layoutAsString $ "Expected:" <+> line <> indent 2 ( squotes (prettyVerbose e2) <> line <> squotes (prettyVerbose e4)) <> line <> "to be equal" <>

haskell

main = do let limit = 2000000 let primes = filter isPrime [1..limit] let primeSum = sum primes print primeSum

haskell

| ref < ct && rf `Map.member` mp = return $ mp Map.! rf | ref >= ct = throwHeapErrorWithStepInfoSTE (\ _ -> HeapLookupOutOfBounds) | otherwise {- invalid heap ref -} = throwHeapErrorWithStepInfoSTE(\ _ -> InvalidHeapLookup) --- this doesn't validate Heap and heap allocator correctness, VERY UNSAFE :) unsafeRunHSCM :: Natural -> Heap val -> HeapStepCounterM val m b -> m (b,CounterAndHeap val ) unsafeRunHSCM cnt hp (HSCM m) = State.runStateT m (CounterAndHeap 0 0 cnt hp)

haskell

case infer env ctx t of Left err -> Left (TypeErr i err) Right v -> Right (Map.insert x v env, ctx) runRepl i (env, ctx) (DefineCheck x a t) = if x `Map.member` env then Left (EnvErr i x) else case check env ctx a (NfS (Type 0)) of Left err -> case check env ctx a (NfS (Type 1)) of Left err -> Left (TypeErr i err) Right a -> case check env ctx t a of Left err -> Left (TypeErr i err)

haskell

readProb :: FilePath -> IO State readProb path = return . initState =<< BL.readFile path initState :: ByteString -> State initState = either error initialState . parseTask . BL.init

haskell

tuple = [(1, 'a', "asdf"), (2, 'b', "asdf")] -- CAUTION: fst, snd, zip only work on pairs fst tuple -- return its first element snd tuple -- return its second element

haskell

import Control.Monad import Foreign import Foreign.C import Foreign.Marshal.Utils import Foreign.Storable #include "pg_query.h" instance Storable PgQueryError where

haskell

double :: Int -> Int double x = x + x recSum :: Num a => [a] -> a recSum [] = 0 recSum (n:ns) = n + sum ns qsort :: Ord a => [a] -> [a] qsort [] = [] qsort (x:xs) = qsort smaller ++ [x] ++ qsort larger

haskell

-- | Compose given list of monadic functions withFold :: Monad m => [m a -> m a] -> m a -> m a withFold = foldr (.) id -- | Turn list into sequence of monadic computations that is then composed withFoldMap :: Monad m => (a -> m b -> m b) -> [a] -> m b -> m b withFoldMap f = withFold . map f

haskell

import Ivory.BSP.STM32L471.MemoryMap import qualified Ivory.BSP.STM32L471.Interrupt as L471 import Ivory.BSP.STM32.Peripheral.RTC rtc :: RTC rtc = mkRTC rtc_periph_base rccenable rccdisable -- L471.RTC_TAMP_STAMP L471.RTC_WKUP L471.RTC_ALARM

haskell

runPlayerAction phase playerId game act = do phaseIs phase game playerIs playerId game getPlayerAction (act playerId game) preSetupAction = runPlayerAction PreSetup setupAction = runPlayerAction Setup

haskell

let m = defaultMaterial let pos = RTCTuple.point 0.0 0.0 0.0 let eyev = RTCTuple.vector 0.0 0.0 (-1.0) let normalv = RTCTuple.vector 0.0 0.0 (-1.0) let light1 = pointLight (Color (1.0,1.0, 1.0 )) (RTCTuple.point 0.0 0.0 (-10.0)) let result = lighting m light1 pos eyev normalv it "result = Color (1.9,1.9,1.9)" $ (Color (1.9, 1.9, 1.9)) ==result `shouldBe` True

haskell

-- Reimplemente a função bin2Int utilizando foldr. type Bit = Int bin2IntFoldr :: [Bit] -> Int bin2IntFoldr = foldr (\ x y -> x + 2 * y ) 0

haskell

module Graphics.GL.AMD.SamplePositions ( -- * Extension Support glGetAMDSamplePositions, gl_AMD_sample_positions, -- * Enums pattern GL_SUBSAMPLE_DISTANCE_AMD, -- * Functions glSetMultisamplefvAMD ) where import Graphics.GL.ExtensionPredicates import Graphics.GL.Tokens

haskell

module CommandLine (askQuestion, askStr, askOption) where askQuestion :: (Read a) => String -> IO a askQuestion = askQuestion' read askStr :: String -> IO String

haskell

it "returns beckon module name" $ N.addBeckonPrefix "beckon.steel.answerPage" `shouldBe` "beckon.steel.answerPage" it "returns beckon module name" $ N.addBeckonPrefix "steel.answerPage" `shouldBe` "beckon.steel.answerPage" describe "getSrcFilePath" $ do it "returns a correct JS file path" $ N.getSrcFilePath Common.FileType.JavaScript "steel.answerPage" `shouldBe`

haskell

identity :: a -> a identity = Prelude.id type ParseError = Text type ParseResult = Either ParseError [ParsedBankRow] type StatementText = ByteString data Handle = Handle

haskell

-- Author: <NAME> <<EMAIL>> module KS.Clean.Old.Options ( OldOptions (..) ) where import KS.Clean.Types data OldOptions = OldOptions { optBeforeDate :: Maybe Date , optArchive :: ShouldArchive , optConfDir :: ConfDir }

haskell

Day10.part2 putStr "\n" putStrLn "-- Day 11 --" putStr "Day 11 Part 1 - Result: " Day11.part1 putStr "Day 11 Part 2 - Result: " Day11.part2 putStr "\n" putStrLn "-- Day 12 --" putStr "Day 12 Part 1 - Result: " Day12.part1 putStr "Day 12 Part 2 - Result: "

haskell

ircFormat' C_B = "\x02" ircFormat' Br = "\n" ircFormat' I = "\x1D" ircFormat' C_I = "\x1D" ircFormat' U = "\x1F" ircFormat' C_U = "\x1F" ircFormat' x = damnFormat' x

haskell

level2TestCases = [ ("Single claim should be the claim itself", ["#1 @ 1,3: 4x4"], 1) , ("Given test case", ["#1 @ 1,3: 4x4", "#2 @ 3,1: 4x4", "#3 @ 5,5: 2x2"], 3) ] level2Tests = TestLabel "Level 2" $ TestList (map (makeTestWithLines level2) level2TestCases)

haskell

primalPivot :: Tableau -> Either PivotError Tableau primalPivot (Tableau deref objective context) = do let isOptimal :: Bool isOptimal = Map.null (Map.filter (< 0) objective) when isOptimal (throwError IsOptimal) let entry :: VarName entry = let go :: VarName -- Objective variable

haskell

, ("lparen" , lparen) , ("nil" , nil) , ("of" , fo) , ("rbrack" , rbrack) , ("rparen" , rparen) , ("tick" , tick) , ("underscore" , underscore)

haskell

haskell

spec :: Spec spec = do describe "decodeUtf8" $ do it "is inverse to encodeUtf8" $ do property $ \xs -> (decodeUtf8 . encodeUtf8) xs `shouldBe` xs

haskell

comboTwo _ = [] palindromeProducts :: [[Integer]] -> [Integer] palindromeProducts l = filter isPalindrome (map product l)

haskell

, backend ) where import Control.Lens import Data.Aeson import Data.Text (Text) import Network.HTTP.Types.Header

haskell

,"LinkKeeper (lnkp) Command help" ,"----------(Commands)----------" ,"help | shows this page" ,"list | Lists stored links" ,"add (link text) | adds link to list" ,"open (link number) | opens link by number" ,"remove (link number) | removes link by number" ,"-----------------------------" ,""]

haskell

newCommand (n, d, a) = Cmd { cmd = n, desc = d, runner = a } commands' :: [(String, String, ActionRunner)] commands' = [ ( "->" , "Post a message for a new or existing User. Usage: <@user> -> <message>" , postRunner ) , ( "" , "Displays the User's Posts. Usage: <@user>"

haskell

module IR where import Data.Text.Prettyprint.Doc import Data.Text.Prettyprint.Doc.Internal import Data.Text.Prettyprint.Doc.Util import qualified Data.Set as S import qualified Control.Monad.State as ST import qualified Data.Map.Strict as M import qualified OrderedMap as OM import Data.List (elemIndex) import Control.Monad(guard)

haskell

data Nibbles = Nibbles {-# UNPACK #-} !Int -- ^ offset (zero based index of first nibble) -- -- prop> let (Nibbles o _ _) in 0 <= o -- prop> let (Nibbles o l d) in o + l <= 2 * length d -- {-# UNPACK #-} !Int -- ^ length -- -- prop> let (Nibbles _ l _) in 0 <= l

haskell

{-# Language TypeSynonymInstances, TypeFamilies, FlexibleInstances, GeneralizedNewtypeDeriving #-} module Plush.Run.ShellExec ( VarScope(..), VarMode(..), VarEntry, ShellState(), initialShellState,

haskell

-- disc :: Position -> R -> sh :~> Position disc (originX, originY, originZ) radiusMax _ix gen = do radius <- uniformR (0,radiusMax) gen theta <- uniformR (0, pi) gen phi <- uniformR (0, 2*pi) gen return ( originX + radius * sin theta * cos phi , originY + radius * sin theta * sin phi , originZ + radius * cos theta )

haskell

relBase (newXs, output) where newCursorPosition = if newValPosition == position then position else position + 2 newXs = take newValPosition xs ++ head input : drop (newValPosition + 1) xs newValPosition = xs !! arg1 -- a -> out

haskell

x <- atomically $ PQ.deleteMin pq putStrLn $ "x = " ++ show x -- prints 2 @ -} module Data.STM.PriorityQueue.Class ( PriorityQueue(..) ) where import Control.Concurrent.STM class PriorityQueue q where -- | /O(1)/. Creates empty priority queue. new :: (Ord k) => STM (q k v)

haskell

pure fa {-# INLINE (=<<&) #-} -- The void function implemented with Functor / Applicative or Monad is slow. -- GHC cannot optimize it, especially when using in IO monad, it could slow -- down function even more than 10 times (!). void :: m a -> m () void = unsafeCoerce ; {-# INLINE void #-} when , unless :: (Applicative m, Mempty a) => Bool -> m a -> m a when_ , unless_ :: (Applicative m) => Bool -> m a -> m () whenM , unlessM :: (Monad m , Mempty a) => m Bool -> m a -> m a whenM_, unlessM_ :: (Monad m ) => m Bool -> m a -> m () when p s = ifThenElse p s (pure mempty) ; {-# INLINE when #-}

haskell

--- ENVIRONMENT MANAGEMENT --- type EnvParser = StateT Env Parser parseEnv :: EnvParser a -> BS -> Either String (Env, BS) parseEnv f = toEither `o` parse $ runStateT f initialEnv where toEither (Fail{}) = Left "Header parsing failure" toEither (Partial _) = Left "Consumed all input while parsed header" toEither (Done r (_, env)) = Right (env, r)

haskell

import Test.Tasty names :: TestTree names =

haskell

isbn xs = verify $ mapMaybe parse xs where parse c | c == 'X' = Just 10 | isDigit c = Just $ digitToInt c | otherwise = Nothing verify :: [Int] -> Bool verify xs@[x1, x2, x3, x4, x5, x6, x7, x8, x9, x10] = (x1 * 10 + x2 * 9 + x3 * 8 + x4 * 7 + x5 * 6 + x6 * 5 + x7 * 4 + x8 * 3 + x9 * 2 + x10) `mod` 11 == 0 && all (< 10) (take 9 xs) verify _ = False

haskell

S2 :: { fs1 :: a } -> S a updS s x = s { fs1=x } ------------------ GADT data T a b where T1 :: { ft1 :: a, ft2 :: c, ft3 :: d } -> T a Int T2 :: { ft1 :: a, ft3 :: c } -> T a Int T3 :: T Int b f :: T a1 b -> a2 -> T a2 b f x v = x { ft1 = v } ------------------ Type family data family R a

haskell

module Alpaca.View.Layout ( renderWithLayout ) where import Data.Text.Lazy (Text) import Text.Blaze.Html5 as H import Text.Blaze.Html5.Attributes as A renderWithLayout :: Text -> Html -> Html renderWithLayout title body = docTypeHtml $ do H.head $ do H.title $ toHtml title H.body body

haskell

-- | Constraint representing the fact that the field @x@ can be get and set on -- the record type @r@ and has field type @a@. This constraint will be solved -- automatically, but manual instances may be provided as well. -- -- The function should satisfy the invariant: -- -- > uncurry ($) (hasField @x r) == r

haskell

scalar :: ScalarType s -> s -> LLVM.Constant scalar (SingleScalarType s) = single s scalar (VectorScalarType s) = vector s single :: SingleType s -> s -> LLVM.Constant single (NumSingleType s) = num s vector :: VectorType s -> s -> LLVM.Constant vector (VectorType _ s) (Vec ba#) = LLVM.Vector

haskell

-> a -> Int -> Int -> a -> a -> a -> vector (Complex a) gaussianPinwheel1 numR2Freqs periodR2 stdR2 sigma thetaFreq rFreq periodEnv stdTheta stdR = let a = 1 / (stdR2 * sqrt 2) in VG.concat . parMap rdeepseq (\(radialFreq, angularFreq) -> let pinwheel = centerHollowArray numR2Freqs $

haskell

singleton = Singleton (<:>) :: a -> NonEmptyList a -> NonEmptyList a x <:> xs = Cons x xs instance Functor NonEmptyList where fmap f (Singleton a) = Singleton (f a) fmap f (Cons x xs) = Cons (f x) (fmap f xs)

haskell

Maintainer : <EMAIL> Stability : experimental Portability : POSIX This is an experimental API. Nakadi-client provides a 'MonadNakadi' instance for the 'IO' monad accessing a global mutable configuration. This module exports the user-visible API for managing this global configuration.

haskell

import Ivory.BSP.STM32F412.SYSCFG.Peripheral import Ivory.BSP.STM32F412.SYSCFG.Regs import Ivory.BSP.STM32F412.RCC import Ivory.BSP.STM32F412.MemoryMap (syscfg_periph_base) syscfg :: SYSCFG syscfg = mkSYSCFG syscfg_periph_base rccenable rccdisable where rccenable = modifyReg rcc_reg_apb2enr $ setBit rcc_apb2enr_syscfgen

haskell

-- a member of the graph. maybeVertex :: k -> Maybe G.Vertex } -- | The node for the given key. Return Nothing if the key is not -- a member of the graph. maybeNode :: DAG k v -> k -> Maybe v maybeNode DAG{..} k = _1 . nodeDesc <$> maybeVertex k {-# INLINE maybeNode #-} -- | The edge list for the given key. Return Nothing if the key is not -- a member of the graph. maybeEdges :: DAG k v -> k -> Maybe [k] maybeEdges DAG{..} k = _3 . nodeDesc <$> maybeVertex k {-# INLINE maybeEdges #-}

haskell

newTask title taskTime "" tags = Task { _taskHeadingL = Heading title taskTime , _taskDescL = Nothing , _taskTagsL = Tags tags } newTask title taskTime desc tags = Task { _taskHeadingL = Heading title taskTime , _taskDescL = Just $ Desc desc , _taskTagsL = Tags tags } completeTask :: Time -> Task -> Task completeTask t = taskHeadingL . taskTimeL . timeEndL %~ (<|> Just t)

haskell

query conn lookupTargets (Only websiteID) where lookupTargets = "SELECT TargetID, UserID, WebsiteID, Selector, Hash, Content " <> "FROM Targets " <> "WHERE websiteID = ?"

haskell

import qualified Lib.Client.Translation.Translation as ClientTranslation import qualified Lib.Model.Data as Data import Graphics.UI.Threepenny.Core import qualified Graphics.UI.Threepenny as UI data Picker = Picker { _container :: Element , _selection :: Event ()

haskell

factorial :: (Integral a) => a -> a factorial 0 = 1 factorial n = n * factorial (n-1) calcBmis :: (RealFloat a) => [(a,a)] -> [a] calcBmis xs = [bmi w h | (w,h) <- xs]

haskell

generateInputFile :: forall arch abi i o. (InSymbol arch abi ~ i, U.Universe i, Show i) => FilePath -> FSTGenerator arch abi -> IO () generateInputFile fp fst = Sys.withFile fp Sys.WriteMode $ \file ->

haskell

module WiredTiger.Raw.Context where import qualified Data.Map.Strict as Map import Language.C.Inline.Context import Language.C.Types import WiredTiger.Raw.Types wiredtigerCtx :: Context wiredtigerCtx = mempty { ctxTypesTable = Map.fromList

haskell

, magnify' ) where import Universum import Control.Monad.Identity (Identity) import Control.Monad.Trans.Except (ExceptT, mapExceptT) import Lens.Micro.Mtl ((.=)) import Lens.Micro as L import Lens.Micro.Mtl as LM import Lens.Micro.Mtl.Internal as LMI -- I don't know how to call these operators

haskell

`shouldBe` (Just mockItem, [[GetItem existingItemId]]) it "should return Nothing, if the Item does not belong to user" $ runTest (getItemBelongingToUserId existingItemId 456 mockEnv) `shouldBe` (Nothing, [[GetItem existingItemId]]) it "should return Nothing, if the Item does not exist" $ runTest (getItemBelongingToUserId 123 existingItemUserId mockEnv)

haskell

let masses = map read input :: [Int] let partOne = sum (map fuel masses) let partTwo = sum (map revisedFuel masses) print partOne print partTwo fuel :: Int -> Int fuel m = m `div` 3 - 2 -- Why greater than 5? Because 5 `div` - 2 = 0, and the puzzle tells us to -- treat values lower than 0 as 0 revisedFuel :: Int -> Int revisedFuel m

haskell

-- Stability : provisional -- Portability : portable -- -- This module corresponds to chapter 6 (AL Contexts and the ALC API) of the -- OpenAL Specification and Reference (version 1.1). --

haskell

trominoTilingLinks :: Links trominoTilingLinks = (items, [], options) where items = monomino ++ squares monomino = [ it "m" ] squares = [ it $ show r ++ show c | r <- [0..7], c <- [0..7] ] -- m 00 -- m 01 -- .. -- 00 01 02 -- 00 10 20 options = monominoes ++ trominoes

haskell

module Andromeda.Simulator ( module X ) where import Andromeda.Simulator.Types as X import Andromeda.Simulator.Actions as X import Andromeda.Simulator.Runtime as X import Andromeda.Simulator.Internal.SimulationCompiler as X

haskell

deriveSafeStore ''UUID -- orphans from filesystem-path instance Binary FilePath where put = Binary.put . F.encodeString get = F.decodeString <$> Binary.get instance SafeCopy FilePath where version = 1 kind = base errorTypeName _ = "Filesystem.Path.FilePath" putCopy = contain . safePut . F.encodeString getCopy = contain $ F.decodeString <$> safeGet

haskell

shouldBe (encodeDigestWith b $ f s) h -- | Test that Nix-like base32 encoding roundtrips prop_nixBase32Roundtrip :: Property prop_nixBase32Roundtrip = forAllShrink nonEmptyString genericShrink $ \x -> pure (encodeUtf8 x) === (B32.decode . B32.encode . encodeUtf8 $ x) -- | API variants prop_nixBase16Roundtrip :: StorePathHashPart -> Property prop_nixBase16Roundtrip x = pure (coerce x) === decodeWith Base16 (encodeWith Base16 $ coerce x) -- | Hash encoding conversion ground-truth. -- Similiar to nix/tests/hash.sh spec_nixhash :: Spec spec_nixhash = do

haskell

-- (Cons p1 (Cons p4 (Cons p2 (Cons p3 Nil)))) } @-} -- testAlternate3 = trivial -- {-@ testAlternate4 :: { -- alternate Nil (Cons p8 (Cons p9 Nil)) = -- (Cons p8 (Cons p9 Nil)) } @-} -- testAlternate4 = trivial

haskell

g2i :: GoodsTile -> String g2i (GoodsTile (Dice i)) = " " ++ show i ++ " " --Maybe Goods to Initials mg2i :: Maybe GoodsTile -> String mg2i Nothing = " " mg2i (Just g) = g2i g

haskell

haskell

module Luna.Std where import Luna.Prelude import Data.Map (Map) import qualified Data.Map as Map

haskell

import qualified Data.Binary.Get as Binary import qualified Data.ByteString.Lazy as BS import qualified Data.ByteString.Lazy.Builder as BS import qualified Data.Text.Lazy as L import qualified Data.Text.Lazy.Encoding as L import qualified Network.Socket as N hiding ( recv ) import qualified Network.Socket.ByteString.Lazy as N