{-| Top-Level Pier Management This is the code that starts the IO drivers and deals with communication between the serf, the log, and the IO drivers. -} module Urbit.Vere.Pier ( booted, resumed, getSnapshot, pier, runPersist, runCompute, generateBootSeq ) where import Urbit.Prelude import RIO.Directory import System.Random import Urbit.Arvo import Urbit.King.Config import Urbit.Vere.Pier.Types import Control.Monad.Trans.Maybe import Data.Text (append) import System.Posix.Files (ownerModes, setFileMode) import Urbit.King.App (HasConfigDir(..), HasStderrLogFunc(..)) import Urbit.Vere.Ames (ames) import Urbit.Vere.Behn (behn) import Urbit.Vere.Clay (clay) import Urbit.Vere.Http.Client (client) import Urbit.Vere.Http.Server (serv) import Urbit.Vere.Log (EventLog) import Urbit.Vere.Serf (Serf, SerfState(..), doJob, sStderr) import qualified System.Entropy as Ent import qualified Urbit.King.API as King import qualified Urbit.Time as Time import qualified Urbit.Vere.Log as Log import qualified Urbit.Vere.Serf as Serf import qualified Urbit.Vere.Term as Term import qualified Urbit.Vere.Term.API as Term import qualified Urbit.Vere.Term.Demux as Term import qualified Urbit.Vere.Term.Render as Term -------------------------------------------------------------------------------- _ioDrivers = [] :: [IODriver] setupPierDirectory :: FilePath -> RIO e () setupPierDirectory shipPath = do for_ ["put", "get", "log", "chk"] $ \seg -> do let pax = shipPath <> "/.urb/" <> seg createDirectoryIfMissing True pax io $ setFileMode pax ownerModes -- Load pill into boot sequence. ----------------------------------------------- genEntropy :: RIO e Word512 genEntropy = fromIntegral . bytesAtom <$> io (Ent.getEntropy 64) generateBootSeq :: Ship -> Pill -> Bool -> LegacyBootEvent -> RIO e BootSeq generateBootSeq ship Pill{..} lite boot = do ent <- genEntropy let ovums = preKern ent <> pKernelOvums <> postKern <> pUserspaceOvums pure $ BootSeq ident pBootFormulas ovums where ident = LogIdentity ship isFake (fromIntegral $ length pBootFormulas) preKern ent = [ EvBlip $ BlipEvArvo $ ArvoEvWhom () ship , EvBlip $ BlipEvArvo $ ArvoEvWack () ent ] postKern = [ EvBlip $ BlipEvTerm $ TermEvBoot (1,()) lite boot ] isFake = case boot of Fake _ -> True _ -> False -- Write a batch of jobs into the event log ------------------------------------ writeJobs :: EventLog -> Vector Job -> RIO e () writeJobs log !jobs = do expect <- Log.nextEv log events <- fmap fromList $ traverse fromJob (zip [expect..] $ toList jobs) Log.appendEvents log events where fromJob :: (EventId, Job) -> RIO e ByteString fromJob (expectedId, job) = do unless (expectedId == jobId job) $ error $ show ("bad job id!", expectedId, jobId job) pure $ jamBS $ jobPayload job jobPayload :: Job -> Noun jobPayload (RunNok (LifeCyc _ m n)) = toNoun (m, n) jobPayload (DoWork (Work _ m d o)) = toNoun (m, d, o) -- Boot a new ship. ------------------------------------------------------------ booted :: (HasPierConfig e, HasStderrLogFunc e, HasLogFunc e) => Pill -> Bool -> Serf.Flags -> Ship -> LegacyBootEvent -> RAcquire e (Serf e, EventLog, SerfState) booted pill lite flags ship boot = do seq@(BootSeq ident x y) <- rio $ generateBootSeq ship pill lite boot rio $ logTrace "BootSeq Computed" pierPath <- view pierPathL liftRIO (setupPierDirectory pierPath) rio $ logTrace "Directory Setup" log <- Log.new (pierPath <> "/.urb/log") ident rio $ logTrace "Event Log Initialized" serf <- Serf.run (Serf.Config pierPath flags) rio $ logTrace "Serf Started" rio $ do (events, serfSt) <- Serf.bootFromSeq serf seq logTrace "Boot Sequence completed" Serf.snapshot serf serfSt logTrace "Snapshot taken" writeJobs log (fromList events) logTrace "Events written" pure (serf, log, serfSt) -- Resume an existing ship. ---------------------------------------------------- resumed :: (HasStderrLogFunc e, HasPierConfig e, HasLogFunc e) => Maybe Word64 -> Serf.Flags -> RAcquire e (Serf e, EventLog, SerfState) resumed event flags = do rio $ logTrace "Resuming ship" top <- view pierPathL tap <- fmap (fromMaybe top) $ rio $ runMaybeT $ do ev <- MaybeT (pure event) MaybeT (getSnapshot top ev) rio $ logTrace $ display @Text ("pier: " <> pack top) rio $ logTrace $ display @Text ("running serf in: " <> pack tap) log <- Log.existing (top <> "/.urb/log") serf <- Serf.run (Serf.Config tap flags) serfSt <- rio $ Serf.replay serf log event rio $ Serf.snapshot serf serfSt pure (serf, log, serfSt) getSnapshot :: forall e. FilePath -> Word64 -> RIO e (Maybe FilePath) getSnapshot top last = do lastSnapshot <- lastMay <$> listReplays pure (replayToPath <$> lastSnapshot) where replayDir = top ".partial-replay" replayToPath eId = replayDir show eId listReplays :: RIO e [Word64] listReplays = do createDirectoryIfMissing True replayDir snapshotNums <- mapMaybe readMay <$> listDirectory replayDir pure $ sort (filter (<= fromIntegral last) snapshotNums) -- Run Pier -------------------------------------------------------------------- acquireWorker :: RIO e () -> RAcquire e (Async ()) acquireWorker act = mkRAcquire (async act) cancel pier :: ∀e. (HasConfigDir e, HasLogFunc e, HasNetworkConfig e, HasPierConfig e) => (Serf e, EventLog, SerfState) -> MVar () -> RAcquire e () pier (serf, log, ss) mStart = do computeQ <- newTQueueIO persistQ <- newTQueueIO executeQ <- newTQueueIO saveM <- newEmptyTMVarIO shutdownM <- newEmptyTMVarIO kapi ← King.kingAPI termApiQ <- atomically $ do q <- newTQueue writeTVar (King.kTermConn kapi) (Just $ writeTQueue q) pure q let shutdownEvent = putTMVar shutdownM () inst <- io (KingId . UV . fromIntegral <$> randomIO @Word16) -- (sz, local) <- Term.localClient -- (waitExternalTerm, termServPort) <- Term.termServer (demux, muxed) <- atomically $ do res <- Term.mkDemux -- Term.addDemux local res pure (res, Term.useDemux res) -- rio $ logInfo $ display $ -- "TERMSERV Terminal Server running on port: " <> tshow termServPort acquireWorker $ forever $ do logTrace "TERMSERV Waiting for external terminal." atomically $ do ext <- Term.connClient <$> readTQueue termApiQ Term.addDemux ext demux logTrace "TERMSERV External terminal connected." swapMVar (sStderr serf) (atomically . Term.trace muxed) let logId = Log.identity log let ship = who logId -- Our call above to set the logging function which echos errors from the -- Serf doesn't have the appended \r\n because those \r\n s are added in -- the c serf code. Logging output from our haskell process must manually -- add them. let showErr = atomically . Term.trace muxed . (flip append "\r\n") let (bootEvents, startDrivers) = drivers inst ship (isFake logId) (writeTQueue computeQ) shutdownEvent (Term.TSize{tsWide=80, tsTall=24}, muxed) showErr io $ atomically $ for_ bootEvents (writeTQueue computeQ) tExe <- startDrivers >>= router (readTQueue executeQ) tDisk <- runPersist log persistQ (writeTQueue executeQ) tCpu <- runCompute serf ss (readTQueue computeQ) (takeTMVar saveM) (takeTMVar shutdownM) (Term.spin muxed) (Term.stopSpin muxed) (writeTQueue persistQ) tSaveSignal <- saveSignalThread saveM putMVar mStart () -- Wait for something to die. let ded = asum [ death "effect thread" tExe , death "persist thread" tDisk , death "compute thread" tCpu ] atomically ded >>= \case Left (txt, exn) -> logError $ displayShow ("Somthing died", txt, exn) Right tag -> logError $ displayShow ("Something simply exited", tag) atomically $ (Term.spin muxed) (Just "shutdown") death :: Text -> Async () -> STM (Either (Text, SomeException) Text) death tag tid = do waitCatchSTM tid <&> \case Left exn -> Left (tag, exn) Right () -> Right tag saveSignalThread :: TMVar () -> RAcquire e (Async ()) saveSignalThread tm = mkRAcquire start cancel where start = async $ forever $ do threadDelay (120 * 1000000) -- 120 seconds atomically $ putTMVar tm () -- Start All Drivers ----------------------------------------------------------- data Drivers e = Drivers { dAmes :: EffCb e AmesEf , dBehn :: EffCb e BehnEf , dHttpClient :: EffCb e HttpClientEf , dHttpServer :: EffCb e HttpServerEf , dNewt :: EffCb e NewtEf , dSync :: EffCb e SyncEf , dTerm :: EffCb e TermEf } drivers :: (HasLogFunc e, HasNetworkConfig e, HasPierConfig e) => KingId -> Ship -> Bool -> (Ev -> STM ()) -> STM() -> (Term.TSize, Term.Client) -> (Text -> RIO e ()) -> ([Ev], RAcquire e (Drivers e)) drivers inst who isFake plan shutdownSTM termSys stderr = (initialEvents, runDrivers) where (behnBorn, runBehn) = behn inst plan (amesBorn, runAmes) = ames inst who isFake plan stderr (httpBorn, runHttp) = serv inst plan isFake (clayBorn, runClay) = clay inst plan (irisBorn, runIris) = client inst plan (termBorn, runTerm) = Term.term termSys shutdownSTM inst plan initialEvents = mconcat [behnBorn, clayBorn, amesBorn, httpBorn, termBorn, irisBorn] runDrivers = do dNewt <- runAmes dBehn <- liftAcquire $ runBehn dAmes <- pure $ const $ pure () dHttpClient <- runIris dHttpServer <- runHttp dSync <- runClay dTerm <- runTerm pure (Drivers{..}) -- Route Effects to Drivers ---------------------------------------------------- router :: HasLogFunc e => STM FX -> Drivers e -> RAcquire e (Async ()) router waitFx Drivers{..} = mkRAcquire start cancel where start = async $ forever $ do fx <- atomically waitFx for_ fx $ \ef -> do logEffect ef case ef of GoodParse (EfVega _ _) -> error "TODO" GoodParse (EfExit _ _) -> error "TODO" GoodParse (EfVane (VEAmes ef)) -> dAmes ef GoodParse (EfVane (VEBehn ef)) -> dBehn ef GoodParse (EfVane (VEBoat ef)) -> dSync ef GoodParse (EfVane (VEClay ef)) -> dSync ef GoodParse (EfVane (VEHttpClient ef)) -> dHttpClient ef GoodParse (EfVane (VEHttpServer ef)) -> dHttpServer ef GoodParse (EfVane (VENewt ef)) -> dNewt ef GoodParse (EfVane (VESync ef)) -> dSync ef GoodParse (EfVane (VETerm ef)) -> dTerm ef FailParse n -> logError $ display $ pack @Text (ppShow n) -- Compute Thread -------------------------------------------------------------- data ComputeRequest = CREvent Ev | CRSave () | CRShutdown () deriving (Eq, Show) logEvent :: HasLogFunc e => Ev -> RIO e () logEvent ev = logDebug $ display $ "[EVENT]\n" <> pretty where pretty :: Text pretty = pack $ unlines $ fmap ("\t" <>) $ lines $ ppShow ev logEffect :: HasLogFunc e => Lenient Ef -> RIO e () logEffect ef = logDebug $ display $ "[EFFECT]\n" <> pretty ef where pretty :: Lenient Ef -> Text pretty = \case GoodParse e -> pack $ unlines $ fmap ("\t" <>) $ lines $ ppShow e FailParse n -> pack $ unlines $ fmap ("\t" <>) $ lines $ ppShow n runCompute :: ∀e. HasLogFunc e => Serf e -> SerfState -> STM Ev -> STM () -> STM () -> (Maybe Text -> STM ()) -> STM () -> ((Job, FX) -> STM ()) -> RAcquire e (Async ()) runCompute serf ss getEvent getSaveSignal getShutdownSignal showSpinner hideSpinner putResult = mkRAcquire (async (go ss)) cancel where go :: SerfState -> RIO e () go ss = do cr <- atomically $ CRShutdown <$> getShutdownSignal <|> CRSave <$> getSaveSignal <|> CREvent <$> getEvent case cr of CREvent ev -> do logEvent ev wen <- io Time.now eId <- pure (ssNextEv ss) mug <- pure (ssLastMug ss) atomically $ showSpinner (getSpinnerNameForEvent ev) (job', ss', fx) <- doJob serf $ DoWork $ Work eId mug wen ev atomically $ hideSpinner atomically (putResult (job', fx)) go ss' CRSave () -> do logDebug $ "Taking periodic snapshot" Serf.snapshot serf ss go ss CRShutdown () -> do -- When shutting down, we first request a snapshot, and then we -- just exit this recursive processing, which will cause the serf -- to exit from its RAcquire. logDebug $ "Shutting down compute system..." Serf.snapshot serf ss pure () -- Persist Thread -------------------------------------------------------------- data PersistExn = BadEventId EventId EventId deriving Show instance Exception PersistExn where displayException (BadEventId expected got) = unlines [ "Out-of-order event id send to persist thread." , "\tExpected " <> show expected <> " but got " <> show got ] runPersist :: ∀e. (HasPierConfig e, HasLogFunc e) => EventLog -> TQueue (Job, FX) -> (FX -> STM ()) -> RAcquire e (Async ()) runPersist log inpQ out = mkRAcquire runThread cancel where runThread :: RIO e (Async ()) runThread = asyncBound $ do dryRun <- view dryRunL forever $ do writs <- atomically getBatchFromQueue unless dryRun $ do events <- validateJobsAndGetBytes (toNullable writs) Log.appendEvents log events atomically $ for_ writs $ \(_,fx) -> out fx validateJobsAndGetBytes :: [(Job, FX)] -> RIO e (Vector ByteString) validateJobsAndGetBytes writs = do expect <- Log.nextEv log fmap fromList $ for (zip [expect..] writs) $ \(expectedId, (j, fx)) -> do unless (expectedId == jobId j) $ throwIO (BadEventId expectedId (jobId j)) case j of RunNok _ -> error "This shouldn't happen here!" DoWork (Work eId mug wen ev) -> pure $ jamBS $ toNoun (mug, wen, ev) getBatchFromQueue :: STM (NonNull [(Job, FX)]) getBatchFromQueue = readTQueue inpQ >>= go . singleton where go acc = tryReadTQueue inpQ >>= \case Nothing -> pure (reverse acc) Just item -> go (item <| acc)