module Vere.Term ( module Term , localClient , termServer , term ) where import Arvo hiding (Term) import Data.Char import Foreign.Marshal.Alloc import Foreign.Ptr import Foreign.Storable import RIO.FilePath import System.Posix.IO import System.Posix.Terminal import Urbit.Time import UrbitPrelude hiding (getCurrentTime) import Vere.Pier.Types import Data.List ((!!)) import RIO.Directory (createDirectoryIfMissing) import Vere.Term.API (Client(Client)) import qualified Data.ByteString.Internal as BS import qualified Data.ByteString.UTF8 as BS import qualified System.Console.Terminal.Size as TSize import qualified System.Console.Terminfo.Base as T import qualified Vere.NounServ as Serv import qualified Vere.Term.API as Term -- Types ----------------------------------------------------------------------- -- All stateful data in the printing to stdOutput. data LineState = LineState { lsLine :: Text , lsCurPos :: Int , lsSpinTimer :: Maybe (Async ()) , lsSpinCause :: Maybe Text , lsSpinFirstRender :: Bool , lsSpinFrame :: Int , lsPrevEndTime :: Wen } -- A record used in reading data from stdInput. data ReadData = ReadData { rdBuf :: Ptr Word8 , rdEscape :: Bool , rdBracket :: Bool , rdUTF8 :: ByteString , rdUTF8width :: Int } -- Private data to the Client that we keep around for stop(). data Private = Private { pReaderThread :: Async () , pWriterThread :: Async () , pPreviousConfiguration :: TerminalAttributes } -- Utils ----------------------------------------------------------------------- termText :: Text -> T.TermOutput termText = T.termText . unpack initialBlew w h = EvBlip $ BlipEvTerm $ TermEvBlew (UD 1, ()) w h initialHail = EvBlip $ BlipEvTerm $ TermEvHail (UD 1, ()) () -- Version one of this is punting on the ops_u.dem flag: whether we're running -- in daemon mode. spinners :: [Text] spinners = ["|", "/", "-", "\\"] leftBracket :: Text leftBracket = "«" rightBracket :: Text rightBracket = "»" _spin_cool_us = 500000 _spin_warm_us = 50000 _spin_rate_us = 250000 _spin_idle_us = 500000 -------------------------------------------------------------------------------- runMaybeTermOutput :: T.Terminal -> (T.Terminal -> Maybe T.TermOutput) -> RIO e () runMaybeTermOutput t getter = case (getter t) of Nothing -> pure () Just x -> io $ T.runTermOutput t x rioAllocaBytes :: (MonadIO m, MonadUnliftIO m) => Int -> (Ptr a -> m b) -> m b rioAllocaBytes size action = withRunInIO $ \run -> allocaBytes size $ \x -> run (action x) -- Because of legacy reasons, some file operations are in the terminal -- driver. These should be filtered out and handled locally instead of in any -- abstractly connected terminal. isTerminalBlit :: Blit -> Bool isTerminalBlit (Sav _ _) = False isTerminalBlit (Sag _ _) = False isTerminalBlit _ = True -------------------------------------------------------------------------------- termServer :: ∀e. HasLogFunc e => RAcquire e (TChan Client, Port) termServer = mkRAcquire start stop where stop = const (pure ()) start = do serv <- Serv.wsServer @Belt @Term.Ev chan <- newTChanIO pure (chan, 0) {- data Server i o a = Server { sAccept :: STM (Maybe (Conn i o)) , sAsync :: Async () , sData :: a } -} {- Initializes the generalized input/output parts of the terminal. -} localClient :: ∀e. HasLogFunc e => RAcquire e (TSize.Window Word, Client) localClient = fst <$> mkRAcquire start stop where start :: HasLogFunc e => RIO e ((TSize.Window Word, Client), Private) start = do -- Initialize the writing side of the terminal -- t <- io $ T.setupTermFromEnv -- TODO: We still need to actually get the size from the terminal somehow. tsWriteQueue <- newTQueueIO spinnerMVar <- newEmptyTMVarIO pWriterThread <- asyncBound (writeTerminal t tsWriteQueue spinnerMVar) pPreviousConfiguration <- io $ getTerminalAttributes stdInput -- Create a new configuration where we put the terminal in raw mode and -- disable a bunch of preprocessing. let newTermSettings = flip withTime 0 . flip withMinInput 1 $ foldl' withoutMode pPreviousConfiguration disabledFlags io $ setTerminalAttributes stdInput newTermSettings Immediately tsReadQueue <- newTQueueIO pReaderThread <- asyncBound (readTerminal tsReadQueue tsWriteQueue (bell tsWriteQueue)) let client = Client { take = readTQueue tsReadQueue , give = writeTQueue tsWriteQueue } tsize <- io $ TSize.size <&> fromMaybe (TSize.Window 80 24) pure ((tsize, client), Private{..}) stop :: HasLogFunc e => ((TSize.Window Word, Client), Private) -> RIO e () stop ((_, Client{..}), Private{..}) = do -- Note that we don't `cancel pReaderThread` here. This is a deliberate -- decision because fdRead calls into a native function which the runtime -- can't kill. If we were to cancel here, the internal `waitCatch` would -- block until the next piece of keyboard input. Since this only happens -- at shutdown, just leak the file descriptor. cancel pWriterThread -- take the terminal out of raw mode io $ setTerminalAttributes stdInput pPreviousConfiguration Immediately {- A list of terminal flags that we disable. TODO: Terminal library missing CSIZE? -} disabledFlags :: [TerminalMode] disabledFlags = [ StartStopOutput , KeyboardInterrupts , EnableEcho , EchoLF , ProcessInput , ExtendedFunctions , MapCRtoLF , CheckParity , StripHighBit , EnableParity , ProcessOutput ] getCap term cap = T.getCapability term (T.tiGetOutput1 cap) :: Maybe T.TermOutput vtClearScreen t = getCap t "clear" vtClearToBegin t = getCap t "el" vtSoundBell t = getCap t "bel" vtParmLeft t = getCap t "cub1" vtParmRight t = getCap t "cuf1" -- An async which will put into an mvar after a delay. Used to spin the -- spinner in writeTerminal. spinnerHeartBeat :: Int -> Int -> TMVar () -> RIO e () spinnerHeartBeat first rest mvar = do threadDelay first loop where loop = do atomically $ putTMVar mvar () threadDelay rest loop -- Writes data to the terminal. Both the terminal reading, normal logging, -- and effect handling can all emit bytes which go to the terminal. writeTerminal :: T.Terminal -> TQueue Term.Ev -> TMVar () -> RIO e () writeTerminal t q spinner = do currentTime <- io $ now loop (LineState "" 0 Nothing Nothing True 0 currentTime) where writeBlank :: LineState -> RIO e LineState writeBlank ls = do io $ T.runTermOutput t $ termText "\r\n" pure ls writeTrace :: LineState -> Text -> RIO e LineState writeTrace ls p = do io $ T.runTermOutput t $ termText "\r" runMaybeTermOutput t vtClearToBegin io $ T.runTermOutput t $ termText p termRefreshLine t ls {- Figure out how long to wait to show the spinner. When we don't have a vane name to display, we assume its a user action and trigger immediately. Otherwise, if we receive an event shortly after a previous spin, use a shorter delay to avoid giving the impression of a half-idle system. -} doSpin :: LineState -> Maybe Text -> RIO e LineState doSpin ls@LineState{..} mTxt = do current <- io $ now delay <- pure $ case mTxt of Nothing -> 0 Just _ -> if (gap current lsPrevEndTime ^. microSecs) < _spin_idle_us then _spin_warm_us else _spin_cool_us spinTimer <- async $ spinnerHeartBeat delay _spin_rate_us spinner pure $ ls { lsSpinTimer = Just spinTimer , lsSpinCause = mTxt , lsSpinFirstRender = True } unspin :: LineState -> RIO e LineState unspin ls@LineState{..} = do maybe (pure ()) cancel lsSpinTimer -- We do a final flush of the spinner mvar to ensure we don't -- have a lingering signal which will redisplay the spinner after -- we call termRefreshLine below. atomically $ tryTakeTMVar spinner -- If we ever actually ran the spinner display callback, we need -- to force a redisplay of the command prompt. ls <- if not lsSpinFirstRender then termRefreshLine t ls else pure ls endTime <- io $ now pure $ ls { lsSpinTimer = Nothing, lsPrevEndTime = endTime } execEv :: LineState -> Term.Ev -> RIO e LineState execEv ls = \case Term.Blits bs -> foldM (writeBlit t) ls bs Term.Trace p -> writeTrace ls (unCord p) Term.Blank -> writeBlank ls Term.Spinr (Just txt) -> doSpin ls (unCord <$> txt) Term.Spinr Nothing -> unspin ls spin :: LineState -> RIO e LineState spin ls@LineState{..} = do let spinner = (spinners !! lsSpinFrame) ++ case lsSpinCause of Nothing -> "" Just str -> leftBracket ++ str ++ rightBracket io $ T.runTermOutput t $ termText spinner termSpinnerMoveLeft t (length spinner) let newFrame = (lsSpinFrame + 1) `mod` (length spinners) pure $ ls { lsSpinFirstRender = False , lsSpinFrame = newFrame } loop :: LineState -> RIO e () loop ls = do join $ atomically $ asum [ readTQueue q >>= pure . (execEv ls >=> loop) , takeTMVar spinner >> pure (spin ls >>= loop) ] -- Writes an individual blit to the screen writeBlit :: T.Terminal -> LineState -> Blit -> RIO e LineState writeBlit t ls = \case Bel () -> do runMaybeTermOutput t vtSoundBell pure ls Clr () -> do runMaybeTermOutput t vtClearScreen termRefreshLine t ls Hop w -> termShowCursor t ls (fromIntegral w) Lin c -> do ls2 <- termShowClear t ls termShowLine t ls2 (pack c) Mor () -> termShowMore t ls Sag path noun -> pure ls Sav path atom -> pure ls Url url -> pure ls -- Moves the cursor to the requested position termShowCursor :: T.Terminal -> LineState -> Int -> RIO e LineState termShowCursor t ls@LineState{..} {-line pos)-} newPos = do if newPos < lsCurPos then do replicateM_ (lsCurPos - newPos) (runMaybeTermOutput t vtParmLeft) pure ls { lsCurPos = newPos } else if newPos > lsCurPos then do replicateM_ (newPos - lsCurPos) (runMaybeTermOutput t vtParmRight) pure ls { lsCurPos = newPos } else pure ls -- Moves the cursor left without any mutation of the LineState. Used only -- in cursor spinning. termSpinnerMoveLeft :: T.Terminal -> Int -> RIO e () termSpinnerMoveLeft t count = replicateM_ count (runMaybeTermOutput t vtParmLeft) -- Displays and sets the current line termShowLine :: T.Terminal -> LineState -> Text -> RIO e LineState termShowLine t ls newStr = do io $ T.runTermOutput t $ termText newStr pure ls { lsLine = newStr, lsCurPos = (length newStr) } termShowClear :: T.Terminal -> LineState -> RIO e LineState termShowClear t ls = do io $ T.runTermOutput t $ termText "\r" runMaybeTermOutput t vtClearToBegin pure ls { lsLine = "", lsCurPos = 0 } -- New Current Line termShowMore :: T.Terminal -> LineState -> RIO e LineState termShowMore t ls = do io $ T.runTermOutput t $ termText "\r\n" pure ls { lsLine = "", lsCurPos = 0 } -- Redraw the current LineState, maintaining the current curpos termRefreshLine :: T.Terminal -> LineState -> RIO e LineState termRefreshLine t ls = do let line = (lsLine ls) curPos = (lsCurPos ls) ls <- termShowClear t ls ls <- termShowLine t ls line termShowCursor t ls curPos -- ring my bell bell :: TQueue Term.Ev -> RIO e () bell q = atomically $ writeTQueue q $ Term.Blits [Bel ()] -- Reads data from stdInput and emit the proper effect -- -- This entire path is a divergence from how term.c does things, -- probably. First, the vtime is 0, not 1 in term.c. So (IIUC), we'll -- always have a latency of 1/10 of a second. -- -- A better way to do this would be to get some sort of epoll on stdInput, -- since that's kinda closer to what libuv does? readTerminal :: forall e. HasLogFunc e => TQueue Belt -> TQueue Term.Ev -> (RIO e ()) -> RIO e () readTerminal rq wq bell = rioAllocaBytes 1 $ \ buf -> loop (ReadData buf False False mempty 0) where loop :: ReadData -> RIO e () loop rd@ReadData{..} = do -- The problem with using fdRead raw is that it will text encode -- things like \ESC instead of 27. That makes it broken for our -- purposes. -- t <- io $ try (fdReadBuf stdInput rdBuf 1) case t of Left (e :: IOException) -> do -- Ignore EAGAINs when doing reads loop rd Right 0 -> loop rd Right _ -> do w <- io $ peek rdBuf -- print ("{" ++ (show w) ++ "}") let c = BS.w2c w if rdEscape then if rdBracket then do case c of 'A' -> sendBelt $ Aro U 'B' -> sendBelt $ Aro D 'C' -> sendBelt $ Aro R 'D' -> sendBelt $ Aro L _ -> bell loop rd { rdEscape = False, rdBracket = False} else if isAsciiLower c then do sendBelt $ Met $ Cord $ pack [c] loop rd { rdEscape = False } else if c == '.' then do sendBelt $ Met $ Cord "dot" loop rd { rdEscape = False } else if w == 8 || w == 127 then do sendBelt $ Met $ Cord "bac" loop rd { rdEscape = False } else if c == '[' || c == '0' then do loop rd { rdBracket = True } else do bell loop rd { rdEscape = False } else if rdUTF8width /= 0 then do -- continue reading into the utf8 accumulation buffer rd@ReadData{..} <- pure rd { rdUTF8 = snoc rdUTF8 w } if length rdUTF8 /= rdUTF8width then loop rd else do case BS.decode rdUTF8 of Nothing -> error "empty utf8 accumulation buffer" Just (c, bytes) | bytes /= rdUTF8width -> error "utf8 character size mismatch?!" Just (c, bytes) -> sendBelt $ Txt $ Tour $ [c] loop rd { rdUTF8 = mempty, rdUTF8width = 0 } else if w >= 32 && w < 127 then do sendBelt $ Txt $ Tour $ [c] loop rd else if w == 0 then do bell loop rd else if w == 8 || w == 127 then do sendBelt $ Bac () loop rd else if w == 13 then do sendBelt $ Ret () loop rd else if w == 3 then do -- ETX (^C) logDebug $ displayShow "Ctrl-c interrupt" atomically $ do writeTQueue wq $ Term.Trace "interrupt\r\n" writeTQueue rq $ Ctl $ Cord "c" loop rd else if w <= 26 then do sendBelt $ Ctl $ Cord $ pack [BS.w2c (w + 97 - 1)] loop rd else if w == 27 then do loop rd { rdEscape = True } else do -- start the utf8 accumulation buffer loop rd { rdUTF8 = singleton w, rdUTF8width = if w < 224 then 2 else if w < 240 then 3 else 4 } sendBelt :: HasLogFunc e => Belt -> RIO e () sendBelt b = do logDebug $ displayShow ("terminalBelt", b) atomically $ writeTQueue rq b -------------------------------------------------------------------------------- term :: forall e. HasLogFunc e => (TSize.Window Word, Client) -> (STM ()) -> FilePath -> KingId -> QueueEv -> ([Ev], RAcquire e (EffCb e TermEf)) term (tsize, Client{..}) shutdownSTM pierPath king enqueueEv = (initialEvents, runTerm) where TSize.Window wi hi = tsize initialEvents = [(initialBlew hi wi), initialHail] runTerm :: RAcquire e (EffCb e TermEf) runTerm = do tim <- mkRAcquire start stop pure handleEffect start :: RIO e (Async ()) start = async readBelt stop :: Async () -> RIO e () stop rb = cancel rb readBelt :: RIO e () readBelt = forever $ do b <- atomically take let blip = EvBlip $ BlipEvTerm $ TermEvBelt (UD 1, ()) $ b atomically $ enqueueEv $ blip handleEffect :: TermEf -> RIO e () handleEffect = \case TermEfBlit _ blits -> do let (termBlits, fsWrites) = partition isTerminalBlit blits atomically $ give (Term.Blits termBlits) for_ fsWrites handleFsWrite TermEfInit _ _ -> pure () TermEfLogo path _ -> do atomically $ shutdownSTM TermEfMass _ _ -> pure () handleFsWrite :: Blit -> RIO e () handleFsWrite (Sag path noun) = performPut path (jamBS noun) handleFsWrite (Sav path atom) = performPut path (atom ^. atomBytes) handleFsWrite _ = pure () performPut :: Path -> ByteString -> RIO e () performPut path bs = do let putOutFile = pierPath ".urb" "put" (pathToFilePath path) createDirectoryIfMissing True (takeDirectory putOutFile) writeFile putOutFile bs