module Erebos.Object.Internal ( Storage, PartialStorage, StorageCompleteness, openStorage, memoryStorage, deriveEphemeralStorage, derivePartialStorage, Ref, PartialRef, RefDigest, refDigest, readRef, showRef, showRefDigest, refDigestFromByteString, hashToRefDigest, copyRef, partialRef, partialRefFromDigest, Object, PartialObject, Object'(..), RecItem, RecItem'(..), serializeObject, deserializeObject, deserializeObjects, ioLoadObject, ioLoadBytes, storeRawBytes, lazyLoadBytes, storeObject, collectObjects, collectStoredObjects, MonadStorage(..), Storable(..), ZeroStorable(..), StorableText(..), StorableDate(..), StorableUUID(..), Store, StoreRec, evalStore, evalStoreObject, storeBlob, storeRec, storeZero, storeEmpty, storeInt, storeNum, storeText, storeBinary, storeDate, storeUUID, storeRef, storeRawRef, storeMbEmpty, storeMbInt, storeMbNum, storeMbText, storeMbBinary, storeMbDate, storeMbUUID, storeMbRef, storeMbRawRef, storeZRef, storeRecItems, Load, LoadRec, evalLoad, loadCurrentRef, loadCurrentObject, loadRecCurrentRef, loadRecItems, loadBlob, loadRec, loadZero, loadEmpty, loadInt, loadNum, loadText, loadBinary, loadDate, loadUUID, loadRef, loadRawRef, loadMbEmpty, loadMbInt, loadMbNum, loadMbText, loadMbBinary, loadMbDate, loadMbUUID, loadMbRef, loadMbRawRef, loadTexts, loadBinaries, loadRefs, loadRawRefs, loadZRef, Stored, fromStored, storedRef, wrappedStore, wrappedLoad, copyStored, unsafeMapStored, ) where import Control.Applicative import Control.Concurrent import Control.Exception import Control.Monad import Control.Monad.Except import Control.Monad.Reader import Control.Monad.Writer import Crypto.Hash import Data.Bifunctor import Data.ByteString (ByteString) import qualified Data.ByteArray as BA import qualified Data.ByteString as B import qualified Data.ByteString.Char8 as BC import qualified Data.ByteString.Lazy as BL import qualified Data.ByteString.Lazy.Char8 as BLC import Data.Char import Data.Function import qualified Data.HashTable.IO as HT import qualified Data.Map as M import Data.Maybe import Data.Ratio import Data.Set (Set) import qualified Data.Set as S import Data.Text (Text) import qualified Data.Text as T import Data.Text.Encoding import Data.Text.Encoding.Error import Data.Time.Calendar import Data.Time.Clock import Data.Time.Format import Data.Time.LocalTime import Data.UUID (UUID) import qualified Data.UUID as U import System.Directory import System.FilePath import System.IO.Error import System.IO.Unsafe import Erebos.Storage.Internal type Storage = Storage' Complete type PartialStorage = Storage' Partial storageVersion :: String storageVersion = "0.1" openStorage :: FilePath -> IO Storage openStorage path = modifyIOError annotate $ do let versionFileName = "erebos-storage" let versionPath = path versionFileName let writeVersionFile = writeFileOnce versionPath $ BLC.pack $ storageVersion <> "\n" maybeVersion <- handleJust (guard . isDoesNotExistError) (const $ return Nothing) $ Just <$> readFile versionPath version <- case maybeVersion of Just versionContent -> do return $ takeWhile (/= '\n') versionContent Nothing -> do files <- handleJust (guard . isDoesNotExistError) (const $ return []) $ listDirectory path when (not $ or [ null files , versionFileName `elem` files , (versionFileName ++ ".lock") `elem` files , "objects" `elem` files && "heads" `elem` files ]) $ do fail "directory is neither empty, nor an existing erebos storage" createDirectoryIfMissing True $ path writeVersionFile takeWhile (/= '\n') <$> readFile versionPath when (version /= storageVersion) $ do fail $ "unsupported storage version " <> version createDirectoryIfMissing True $ path "objects" createDirectoryIfMissing True $ path "heads" watchers <- newMVar (Nothing, [], WatchList 1 []) refgen <- newMVar =<< HT.new refroots <- newMVar =<< HT.new return $ Storage { stBacking = StorageDir path watchers , stParent = Nothing , stRefGeneration = refgen , stRefRoots = refroots } where annotate e = annotateIOError e "failed to open storage" Nothing (Just path) memoryStorage' :: IO (Storage' c') memoryStorage' = do backing <- StorageMemory <$> newMVar [] <*> newMVar M.empty <*> newMVar M.empty <*> newMVar (WatchList 1 []) refgen <- newMVar =<< HT.new refroots <- newMVar =<< HT.new return $ Storage { stBacking = backing , stParent = Nothing , stRefGeneration = refgen , stRefRoots = refroots } memoryStorage :: IO Storage memoryStorage = memoryStorage' deriveEphemeralStorage :: Storage -> IO Storage deriveEphemeralStorage parent = do st <- memoryStorage return $ st { stParent = Just parent } derivePartialStorage :: Storage -> IO PartialStorage derivePartialStorage parent = do st <- memoryStorage' return $ st { stParent = Just parent } type Ref = Ref' Complete type PartialRef = Ref' Partial zeroRef :: Storage' c -> Ref' c zeroRef s = Ref s (RefDigest h) where h = case digestFromByteString $ B.replicate (hashDigestSize $ digestAlgo h) 0 of Nothing -> error $ "Failed to create zero hash" Just h' -> h' digestAlgo :: Digest a -> a digestAlgo = undefined isZeroRef :: Ref' c -> Bool isZeroRef (Ref _ h) = all (==0) $ BA.unpack h refFromDigest :: Storage' c -> RefDigest -> IO (Maybe (Ref' c)) refFromDigest st dgst = fmap (const $ Ref st dgst) <$> ioLoadBytesFromStorage st dgst readRef :: Storage -> ByteString -> IO (Maybe Ref) readRef s b = case readRefDigest b of Nothing -> return Nothing Just dgst -> refFromDigest s dgst copyRef' :: forall c c'. (StorageCompleteness c, StorageCompleteness c') => Storage' c' -> Ref' c -> IO (c (Ref' c')) copyRef' st ref'@(Ref _ dgst) = refFromDigest st dgst >>= \case Just ref -> return $ return ref Nothing -> doCopy where doCopy = do mbobj' <- ioLoadObject ref' mbobj <- sequence $ copyObject' st <$> mbobj' sequence $ unsafeStoreObject st <$> join mbobj copyRecItem' :: forall c c'. (StorageCompleteness c, StorageCompleteness c') => Storage' c' -> RecItem' c -> IO (c (RecItem' c')) copyRecItem' st = \case RecEmpty -> return $ return $ RecEmpty RecInt x -> return $ return $ RecInt x RecNum x -> return $ return $ RecNum x RecText x -> return $ return $ RecText x RecBinary x -> return $ return $ RecBinary x RecDate x -> return $ return $ RecDate x RecUUID x -> return $ return $ RecUUID x RecRef x -> fmap RecRef <$> copyRef' st x RecUnknown t x -> return $ return $ RecUnknown t x copyObject' :: forall c c'. (StorageCompleteness c, StorageCompleteness c') => Storage' c' -> Object' c -> IO (c (Object' c')) copyObject' _ (Blob bs) = return $ return $ Blob bs copyObject' st (Rec rs) = fmap Rec . sequence <$> mapM (\( n, item ) -> fmap ( n, ) <$> copyRecItem' st item) rs copyObject' _ ZeroObject = return $ return ZeroObject copyObject' _ (UnknownObject otype content) = return $ return $ UnknownObject otype content copyRef :: forall c c' m. (StorageCompleteness c, StorageCompleteness c', MonadIO m) => Storage' c' -> Ref' c -> m (LoadResult c (Ref' c')) copyRef st ref' = liftIO $ returnLoadResult <$> copyRef' st ref' copyRecItem :: forall c c' m. (StorageCompleteness c, StorageCompleteness c', MonadIO m) => Storage' c' -> RecItem' c -> m (LoadResult c (RecItem' c')) copyRecItem st item' = liftIO $ returnLoadResult <$> copyRecItem' st item' copyObject :: forall c c'. (StorageCompleteness c, StorageCompleteness c') => Storage' c' -> Object' c -> IO (LoadResult c (Object' c')) copyObject st obj' = returnLoadResult <$> copyObject' st obj' partialRef :: PartialStorage -> Ref -> PartialRef partialRef st (Ref _ dgst) = Ref st dgst partialRefFromDigest :: PartialStorage -> RefDigest -> PartialRef partialRefFromDigest st dgst = Ref st dgst data Object' c = Blob ByteString | Rec [(ByteString, RecItem' c)] | ZeroObject | UnknownObject ByteString ByteString deriving (Show) type Object = Object' Complete type PartialObject = Object' Partial data RecItem' c = RecEmpty | RecInt Integer | RecNum Rational | RecText Text | RecBinary ByteString | RecDate ZonedTime | RecUUID UUID | RecRef (Ref' c) | RecUnknown ByteString ByteString deriving (Show) type RecItem = RecItem' Complete serializeObject :: Object' c -> BL.ByteString serializeObject = \case Blob cnt -> BL.fromChunks [BC.pack "blob ", BC.pack (show $ B.length cnt), BC.singleton '\n', cnt] Rec rec -> let cnt = BL.fromChunks $ concatMap (uncurry serializeRecItem) rec in BL.fromChunks [BC.pack "rec ", BC.pack (show $ BL.length cnt), BC.singleton '\n'] `BL.append` cnt ZeroObject -> BL.empty UnknownObject otype cnt -> BL.fromChunks [ otype, BC.singleton ' ', BC.pack (show $ B.length cnt), BC.singleton '\n', cnt ] -- |Serializes and stores object data without ony dependencies, so is safe only -- if all the referenced objects are already stored or reference is partial. unsafeStoreObject :: Storage' c -> Object' c -> IO (Ref' c) unsafeStoreObject storage = \case ZeroObject -> return $ zeroRef storage obj -> unsafeStoreRawBytes storage $ serializeObject obj storeObject :: PartialStorage -> PartialObject -> IO PartialRef storeObject = unsafeStoreObject storeRawBytes :: PartialStorage -> BL.ByteString -> IO PartialRef storeRawBytes = unsafeStoreRawBytes serializeRecItem :: ByteString -> RecItem' c -> [ByteString] serializeRecItem name (RecEmpty) = [name, BC.pack ":e", BC.singleton ' ', BC.singleton '\n'] serializeRecItem name (RecInt x) = [name, BC.pack ":i", BC.singleton ' ', BC.pack (show x), BC.singleton '\n'] serializeRecItem name (RecNum x) = [name, BC.pack ":n", BC.singleton ' ', BC.pack (showRatio x), BC.singleton '\n'] serializeRecItem name (RecText x) = [name, BC.pack ":t", BC.singleton ' ', escaped, BC.singleton '\n'] where escaped = BC.concatMap escape $ encodeUtf8 x escape '\n' = BC.pack "\n\t" escape c = BC.singleton c serializeRecItem name (RecBinary x) = [name, BC.pack ":b ", showHex x, BC.singleton '\n'] serializeRecItem name (RecDate x) = [name, BC.pack ":d", BC.singleton ' ', BC.pack (formatTime defaultTimeLocale "%s %z" x), BC.singleton '\n'] serializeRecItem name (RecUUID x) = [name, BC.pack ":u", BC.singleton ' ', U.toASCIIBytes x, BC.singleton '\n'] serializeRecItem name (RecRef x) = [name, BC.pack ":r ", showRef x, BC.singleton '\n'] serializeRecItem name (RecUnknown t x) = [ name, BC.singleton ':', t, BC.singleton ' ', x, BC.singleton '\n' ] lazyLoadObject :: forall c. StorageCompleteness c => Ref' c -> LoadResult c (Object' c) lazyLoadObject = returnLoadResult . unsafePerformIO . ioLoadObject ioLoadObject :: forall c. StorageCompleteness c => Ref' c -> IO (c (Object' c)) ioLoadObject ref | isZeroRef ref = return $ return ZeroObject ioLoadObject ref@(Ref st rhash) = do file' <- ioLoadBytes ref return $ do file <- file' let chash = hashToRefDigest file when (chash /= rhash) $ error $ "Hash mismatch on object " ++ BC.unpack (showRef ref) {- TODO throw -} return $ case runExcept $ unsafeDeserializeObject st file of Left err -> error $ err ++ ", ref " ++ BC.unpack (showRef ref) {- TODO throw -} Right (x, rest) | BL.null rest -> x | otherwise -> error $ "Superfluous content after " ++ BC.unpack (showRef ref) {- TODO throw -} lazyLoadBytes :: forall c. StorageCompleteness c => Ref' c -> LoadResult c BL.ByteString lazyLoadBytes ref | isZeroRef ref = returnLoadResult (return BL.empty :: c BL.ByteString) lazyLoadBytes ref = returnLoadResult $ unsafePerformIO $ ioLoadBytes ref unsafeDeserializeObject :: Storage' c -> BL.ByteString -> Except String (Object' c, BL.ByteString) unsafeDeserializeObject _ bytes | BL.null bytes = return (ZeroObject, bytes) unsafeDeserializeObject st bytes = case BLC.break (=='\n') bytes of (line, rest) | Just (otype, len) <- splitObjPrefix line -> do let (content, next) = first BL.toStrict $ BL.splitAt (fromIntegral len) $ BL.drop 1 rest guard $ B.length content == len (,next) <$> case otype of _ | otype == BC.pack "blob" -> return $ Blob content | otype == BC.pack "rec" -> maybe (throwError $ "Malformed record item ") (return . Rec) $ sequence $ map parseRecLine $ mergeCont [] $ BC.lines content | otherwise -> return $ UnknownObject otype content _ -> throwError $ "Malformed object" where splitObjPrefix line = do [otype, tlen] <- return $ BLC.words line (len, rest) <- BLC.readInt tlen guard $ BL.null rest return (BL.toStrict otype, len) mergeCont cs (a:b:rest) | Just ('\t', b') <- BC.uncons b = mergeCont (b':BC.pack "\n":cs) (a:rest) mergeCont cs (a:rest) = B.concat (a : reverse cs) : mergeCont [] rest mergeCont _ [] = [] parseRecLine line = do colon <- BC.elemIndex ':' line space <- BC.elemIndex ' ' line guard $ colon < space let name = B.take colon line itype = B.take (space-colon-1) $ B.drop (colon+1) line content = B.drop (space+1) line let val = fromMaybe (RecUnknown itype content) $ case BC.unpack itype of "e" -> do guard $ B.null content return RecEmpty "i" -> do (num, rest) <- BC.readInteger content guard $ B.null rest return $ RecInt num "n" -> RecNum <$> parseRatio content "t" -> return $ RecText $ decodeUtf8With lenientDecode content "b" -> RecBinary <$> readHex content "d" -> RecDate <$> parseTimeM False defaultTimeLocale "%s %z" (BC.unpack content) "u" -> RecUUID <$> U.fromASCIIBytes content "r" -> RecRef . Ref st <$> readRefDigest content _ -> Nothing return (name, val) deserializeObject :: PartialStorage -> BL.ByteString -> Except String (PartialObject, BL.ByteString) deserializeObject = unsafeDeserializeObject deserializeObjects :: PartialStorage -> BL.ByteString -> Except String [PartialObject] deserializeObjects _ bytes | BL.null bytes = return [] deserializeObjects st bytes = do (obj, rest) <- deserializeObject st bytes (obj:) <$> deserializeObjects st rest collectObjects :: Object -> [Object] collectObjects obj = obj : map fromStored (fst $ collectOtherStored S.empty obj) collectStoredObjects :: Stored Object -> [Stored Object] collectStoredObjects obj = obj : (fst $ collectOtherStored S.empty $ fromStored obj) collectOtherStored :: Set RefDigest -> Object -> ([Stored Object], Set RefDigest) collectOtherStored seen (Rec items) = foldr helper ([], seen) $ map snd items where helper (RecRef ref) (xs, s) | r <- refDigest ref , r `S.notMember` s = let o = wrappedLoad ref (xs', s') = collectOtherStored (S.insert r s) $ fromStored o in ((o : xs') ++ xs, s') helper _ (xs, s) = (xs, s) collectOtherStored seen _ = ([], seen) deriving instance StorableUUID HeadID deriving instance StorableUUID HeadTypeID class Monad m => MonadStorage m where getStorage :: m Storage mstore :: Storable a => a -> m (Stored a) default mstore :: MonadIO m => Storable a => a -> m (Stored a) mstore x = do st <- getStorage wrappedStore st x instance MonadIO m => MonadStorage (ReaderT Storage m) where getStorage = ask class Storable a where store' :: a -> Store load' :: Load a store :: StorageCompleteness c => Storage' c -> a -> IO (Ref' c) store st = evalStore st . store' load :: Ref -> a load = evalLoad load' class Storable a => ZeroStorable a where fromZero :: Storage -> a data Store = StoreBlob ByteString | StoreRec (forall c. StorageCompleteness c => Storage' c -> [IO [(ByteString, RecItem' c)]]) | StoreZero | StoreUnknown ByteString ByteString evalStore :: StorageCompleteness c => Storage' c -> Store -> IO (Ref' c) evalStore st = unsafeStoreObject st <=< evalStoreObject st evalStoreObject :: StorageCompleteness c => Storage' c -> Store -> IO (Object' c) evalStoreObject _ (StoreBlob x) = return $ Blob x evalStoreObject s (StoreRec f) = Rec . concat <$> sequence (f s) evalStoreObject _ StoreZero = return ZeroObject evalStoreObject _ (StoreUnknown otype content) = return $ UnknownObject otype content newtype StoreRecM c a = StoreRecM (ReaderT (Storage' c) (Writer [IO [(ByteString, RecItem' c)]]) a) deriving (Functor, Applicative, Monad) type StoreRec c = StoreRecM c () newtype Load a = Load (ReaderT (Ref, Object) (Except String) a) deriving (Functor, Applicative, Alternative, Monad, MonadPlus, MonadError String) evalLoad :: Load a -> Ref -> a evalLoad (Load f) ref = either (error {- TODO throw -} . ((BC.unpack (showRef ref) ++ ": ")++)) id $ runExcept $ runReaderT f (ref, lazyLoadObject ref) loadCurrentRef :: Load Ref loadCurrentRef = Load $ asks fst loadCurrentObject :: Load Object loadCurrentObject = Load $ asks snd newtype LoadRec a = LoadRec (ReaderT (Ref, [(ByteString, RecItem)]) (Except String) a) deriving (Functor, Applicative, Alternative, Monad, MonadPlus, MonadError String) loadRecCurrentRef :: LoadRec Ref loadRecCurrentRef = LoadRec $ asks fst loadRecItems :: LoadRec [(ByteString, RecItem)] loadRecItems = LoadRec $ asks snd instance Storable Object where store' (Blob bs) = StoreBlob bs store' (Rec xs) = StoreRec $ \st -> return $ do Rec xs' <- copyObject st (Rec xs) return xs' store' ZeroObject = StoreZero store' (UnknownObject otype content) = StoreUnknown otype content load' = loadCurrentObject store st = unsafeStoreObject st <=< copyObject st load = lazyLoadObject instance Storable ByteString where store' = storeBlob load' = loadBlob id instance Storable a => Storable [a] where store' [] = storeZero store' (x:xs) = storeRec $ do storeRef "i" x storeRef "n" xs load' = loadCurrentObject >>= \case ZeroObject -> return [] _ -> loadRec $ (:) <$> loadRef "i" <*> loadRef "n" instance Storable a => ZeroStorable [a] where fromZero _ = [] storeBlob :: ByteString -> Store storeBlob = StoreBlob storeRec :: (forall c. StorageCompleteness c => StoreRec c) -> Store storeRec sr = StoreRec $ do let StoreRecM r = sr execWriter . runReaderT r storeZero :: Store storeZero = StoreZero class StorableText a where toText :: a -> Text fromText :: MonadError String m => Text -> m a instance StorableText Text where toText = id; fromText = return instance StorableText [Char] where toText = T.pack; fromText = return . T.unpack class StorableDate a where toDate :: a -> ZonedTime fromDate :: ZonedTime -> a instance StorableDate ZonedTime where toDate = id; fromDate = id instance StorableDate UTCTime where toDate = utcToZonedTime utc fromDate = zonedTimeToUTC instance StorableDate Day where toDate day = toDate $ UTCTime day 0 fromDate = utctDay . fromDate class StorableUUID a where toUUID :: a -> UUID fromUUID :: UUID -> a instance StorableUUID UUID where toUUID = id; fromUUID = id storeEmpty :: String -> StoreRec c storeEmpty name = StoreRecM $ tell [return [(BC.pack name, RecEmpty)]] storeMbEmpty :: String -> Maybe () -> StoreRec c storeMbEmpty name = maybe (return ()) (const $ storeEmpty name) storeInt :: Integral a => String -> a -> StoreRec c storeInt name x = StoreRecM $ tell [return [(BC.pack name, RecInt $ toInteger x)]] storeMbInt :: Integral a => String -> Maybe a -> StoreRec c storeMbInt name = maybe (return ()) (storeInt name) storeNum :: (Real a, Fractional a) => String -> a -> StoreRec c storeNum name x = StoreRecM $ tell [return [(BC.pack name, RecNum $ toRational x)]] storeMbNum :: (Real a, Fractional a) => String -> Maybe a -> StoreRec c storeMbNum name = maybe (return ()) (storeNum name) storeText :: StorableText a => String -> a -> StoreRec c storeText name x = StoreRecM $ tell [return [(BC.pack name, RecText $ toText x)]] storeMbText :: StorableText a => String -> Maybe a -> StoreRec c storeMbText name = maybe (return ()) (storeText name) storeBinary :: BA.ByteArrayAccess a => String -> a -> StoreRec c storeBinary name x = StoreRecM $ tell [return [(BC.pack name, RecBinary $ BA.convert x)]] storeMbBinary :: BA.ByteArrayAccess a => String -> Maybe a -> StoreRec c storeMbBinary name = maybe (return ()) (storeBinary name) storeDate :: StorableDate a => String -> a -> StoreRec c storeDate name x = StoreRecM $ tell [return [(BC.pack name, RecDate $ toDate x)]] storeMbDate :: StorableDate a => String -> Maybe a -> StoreRec c storeMbDate name = maybe (return ()) (storeDate name) storeUUID :: StorableUUID a => String -> a -> StoreRec c storeUUID name x = StoreRecM $ tell [return [(BC.pack name, RecUUID $ toUUID x)]] storeMbUUID :: StorableUUID a => String -> Maybe a -> StoreRec c storeMbUUID name = maybe (return ()) (storeUUID name) storeRef :: Storable a => StorageCompleteness c => String -> a -> StoreRec c storeRef name x = StoreRecM $ do s <- ask tell $ (:[]) $ do ref <- store s x return [(BC.pack name, RecRef ref)] storeMbRef :: Storable a => StorageCompleteness c => String -> Maybe a -> StoreRec c storeMbRef name = maybe (return ()) (storeRef name) storeRawRef :: StorageCompleteness c => String -> Ref -> StoreRec c storeRawRef name ref = StoreRecM $ do st <- ask tell $ (:[]) $ do ref' <- copyRef st ref return [(BC.pack name, RecRef ref')] storeMbRawRef :: StorageCompleteness c => String -> Maybe Ref -> StoreRec c storeMbRawRef name = maybe (return ()) (storeRawRef name) storeZRef :: (ZeroStorable a, StorageCompleteness c) => String -> a -> StoreRec c storeZRef name x = StoreRecM $ do s <- ask tell $ (:[]) $ do ref <- store s x return $ if isZeroRef ref then [] else [(BC.pack name, RecRef ref)] storeRecItems :: StorageCompleteness c => [ ( ByteString, RecItem ) ] -> StoreRec c storeRecItems items = StoreRecM $ do st <- ask tell $ flip map items $ \( name, value ) -> do value' <- copyRecItem st value return [ ( name, value' ) ] loadBlob :: (ByteString -> a) -> Load a loadBlob f = loadCurrentObject >>= \case Blob x -> return $ f x _ -> throwError "Expecting blob" loadRec :: LoadRec a -> Load a loadRec (LoadRec lrec) = loadCurrentObject >>= \case Rec rs -> do ref <- loadCurrentRef either throwError return $ runExcept $ runReaderT lrec (ref, rs) _ -> throwError "Expecting record" loadZero :: a -> Load a loadZero x = loadCurrentObject >>= \case ZeroObject -> return x _ -> throwError "Expecting zero" loadEmpty :: String -> LoadRec () loadEmpty name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbEmpty name loadMbEmpty :: String -> LoadRec (Maybe ()) loadMbEmpty name = listToMaybe . mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecEmpty ) | name' == bname = Just () p _ = Nothing loadInt :: Num a => String -> LoadRec a loadInt name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbInt name loadMbInt :: Num a => String -> LoadRec (Maybe a) loadMbInt name = listToMaybe . mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecInt x ) | name' == bname = Just (fromInteger x) p _ = Nothing loadNum :: (Real a, Fractional a) => String -> LoadRec a loadNum name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbNum name loadMbNum :: (Real a, Fractional a) => String -> LoadRec (Maybe a) loadMbNum name = listToMaybe . mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecNum x ) | name' == bname = Just (fromRational x) p _ = Nothing loadText :: StorableText a => String -> LoadRec a loadText name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbText name loadMbText :: StorableText a => String -> LoadRec (Maybe a) loadMbText name = listToMaybe <$> loadTexts name loadTexts :: StorableText a => String -> LoadRec [a] loadTexts name = sequence . mapMaybe p =<< loadRecItems where bname = BC.pack name p ( name', RecText x ) | name' == bname = Just (fromText x) p _ = Nothing loadBinary :: BA.ByteArray a => String -> LoadRec a loadBinary name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbBinary name loadMbBinary :: BA.ByteArray a => String -> LoadRec (Maybe a) loadMbBinary name = listToMaybe <$> loadBinaries name loadBinaries :: BA.ByteArray a => String -> LoadRec [a] loadBinaries name = mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecBinary x ) | name' == bname = Just (BA.convert x) p _ = Nothing loadDate :: StorableDate a => String -> LoadRec a loadDate name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbDate name loadMbDate :: StorableDate a => String -> LoadRec (Maybe a) loadMbDate name = listToMaybe . mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecDate x ) | name' == bname = Just (fromDate x) p _ = Nothing loadUUID :: StorableUUID a => String -> LoadRec a loadUUID name = maybe (throwError $ "Missing record iteem '"++name++"'") return =<< loadMbUUID name loadMbUUID :: StorableUUID a => String -> LoadRec (Maybe a) loadMbUUID name = listToMaybe . mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecUUID x ) | name' == bname = Just (fromUUID x) p _ = Nothing loadRawRef :: String -> LoadRec Ref loadRawRef name = maybe (throwError $ "Missing record item '"++name++"'") return =<< loadMbRawRef name loadMbRawRef :: String -> LoadRec (Maybe Ref) loadMbRawRef name = listToMaybe <$> loadRawRefs name loadRawRefs :: String -> LoadRec [Ref] loadRawRefs name = mapMaybe p <$> loadRecItems where bname = BC.pack name p ( name', RecRef x ) | name' == bname = Just x p _ = Nothing loadRef :: Storable a => String -> LoadRec a loadRef name = load <$> loadRawRef name loadMbRef :: Storable a => String -> LoadRec (Maybe a) loadMbRef name = fmap load <$> loadMbRawRef name loadRefs :: Storable a => String -> LoadRec [a] loadRefs name = map load <$> loadRawRefs name loadZRef :: ZeroStorable a => String -> LoadRec a loadZRef name = loadMbRef name >>= \case Nothing -> do Ref st _ <- loadRecCurrentRef return $ fromZero st Just x -> return x type Stored a = Stored' Complete a instance Storable a => Storable (Stored a) where store st = copyRef st . storedRef store' (Stored _ x) = store' x load' = Stored <$> loadCurrentRef <*> load' instance ZeroStorable a => ZeroStorable (Stored a) where fromZero st = Stored (zeroRef st) $ fromZero st fromStored :: Stored a -> a fromStored (Stored _ x) = x storedRef :: Stored a -> Ref storedRef (Stored ref _) = ref wrappedStore :: MonadIO m => Storable a => Storage -> a -> m (Stored a) wrappedStore st x = do ref <- liftIO $ store st x return $ Stored ref x wrappedLoad :: Storable a => Ref -> Stored a wrappedLoad ref = Stored ref (load ref) copyStored :: forall c c' m a. (StorageCompleteness c, StorageCompleteness c', MonadIO m) => Storage' c' -> Stored' c a -> m (LoadResult c (Stored' c' a)) copyStored st (Stored ref' x) = liftIO $ returnLoadResult . fmap (flip Stored x) <$> copyRef' st ref' -- |Passed function needs to preserve the object representation to be safe unsafeMapStored :: (a -> b) -> Stored a -> Stored b unsafeMapStored f (Stored ref x) = Stored ref (f x) showRatio :: Rational -> String showRatio r = case decimalRatio r of Just (n, 1) -> show n Just (n', d) -> let n = abs n' in (if n' < 0 then "-" else "") ++ show (n `div` d) ++ "." ++ (concatMap (show.(`mod` 10).snd) $ reverse $ takeWhile ((>1).fst) $ zip (iterate (`div` 10) d) (iterate (`div` 10) (n `mod` d))) Nothing -> show (numerator r) ++ "/" ++ show (denominator r) decimalRatio :: Rational -> Maybe (Integer, Integer) decimalRatio r = do let n = numerator r d = denominator r (c2, d') = takeFactors 2 d (c5, d'') = takeFactors 5 d' guard $ d'' == 1 let m = if c2 > c5 then 5 ^ (c2 - c5) else 2 ^ (c5 - c2) return (n * m, d * m) takeFactors :: Integer -> Integer -> (Integer, Integer) takeFactors f n | n `mod` f == 0 = let (c, n') = takeFactors f (n `div` f) in (c+1, n') | otherwise = (0, n) parseRatio :: ByteString -> Maybe Rational parseRatio bs = case BC.groupBy ((==) `on` isNumber) bs of (m:xs) | m == BC.pack "-" -> negate <$> positive xs xs -> positive xs where positive = \case [bx] -> fromInteger . fst <$> BC.readInteger bx [bx, op, by] -> do (x, _) <- BC.readInteger bx (y, _) <- BC.readInteger by case BC.unpack op of "." -> return $ (x % 1) + (y % (10 ^ BC.length by)) "/" -> return $ x % y _ -> Nothing _ -> Nothing