{- git-annex command-line actions and concurrency - - Copyright 2010-2021 Joey Hess - - Licensed under the GNU AGPL version 3 or higher. -} {-# LANGUAGE CPP, BangPatterns #-} module CmdLine.Action where import Annex.Common import qualified Annex import Annex.Concurrent import Annex.WorkerPool import Types.Command import Types.Concurrency import Annex.Content import Messages.Concurrent import Types.Messages import Types.WorkerPool import Types.ActionItem import Remote.List import Control.Concurrent import Control.Concurrent.Async import Control.Concurrent.STM import GHC.Conc import qualified Data.Map.Strict as M import qualified System.Console.Regions as Regions {- Runs a command, starting with the check stage, and then - the seek stage. Finishes by running the continuation. - - Can exit when there was a problem or when a time or size limit was - reached. Also shows a count of any failures when that is enabled. -} performCommandAction :: Bool -> Command -> CommandSeek -> Annex () -> Annex () performCommandAction canexit (Command { cmdcheck = c, cmdname = name }) seek cont = do mapM_ runCheck c Annex.changeState $ \s -> s { Annex.errcounter = 0 } seek finishCommandActions cont st <- Annex.getState id when canexit $ liftIO $ case (Annex.errcounter st, Annex.reachedlimit st) of (0, False) -> noop (errcnt, False) -> do showerrcount errcnt exitWith $ ExitFailure 1 (0, True) -> exitreachedlimit (errcnt, True) -> do showerrcount errcnt exitreachedlimit where showerrcount cnt = hPutStrLn stderr $ name ++ ": " ++ show cnt ++ " failed" exitreachedlimit = exitWith $ ExitFailure 101 commandActions :: [CommandStart] -> Annex () commandActions = mapM_ commandAction {- Runs one of the actions needed to perform a command. - Individual actions can fail without stopping the whole command, - including by throwing non-async exceptions. - - When concurrency is enabled, a thread is forked off to run the action - in the background, as soon as a free worker slot is available. - This should only be run in the seek stage. -} commandAction :: CommandStart -> Annex () commandAction start = do st <- Annex.getState id case getConcurrency' (Annex.concurrency st) of NonConcurrent -> runnonconcurrent (Annex.sizelimit st) Concurrent n | n > 1 -> runconcurrent (Annex.sizelimit st) (Annex.workers st) | otherwise -> runnonconcurrent (Annex.sizelimit st) ConcurrentPerCpu -> runconcurrent (Annex.sizelimit st) (Annex.workers st) where runnonconcurrent sizelimit = start >>= \case Nothing -> noop Just (startmsg, perform) -> checkSizeLimit sizelimit startmsg $ do showStartMessage startmsg void $ accountCommandAction startmsg $ performCommandAction' startmsg perform runconcurrent sizelimit Nothing = runnonconcurrent sizelimit runconcurrent sizelimit (Just tv) = liftIO (atomically (waitStartWorkerSlot tv)) >>= maybe (runnonconcurrent sizelimit) (runconcurrent' sizelimit tv) runconcurrent' sizelimit tv (workerstrd, workerstage) = do aid <- liftIO $ async $ snd <$> Annex.run workerstrd (concurrentjob sizelimit (fst workerstrd)) liftIO $ atomically $ do pool <- takeTMVar tv let !pool' = addWorkerPool (ActiveWorker aid workerstage) pool putTMVar tv pool' void $ liftIO $ forkIO $ debugLocks $ do -- accountCommandAction will usually catch -- exceptions. Just in case, fall back to the -- original workerstrd. workerstrd' <- either (const workerstrd) id <$> waitCatch aid atomically $ do pool <- takeTMVar tv let !pool' = deactivateWorker pool aid workerstrd' putTMVar tv pool' concurrentjob sizelimit workerst = start >>= \case Nothing -> noop Just (startmsg, perform) -> checkSizeLimit sizelimit startmsg $ concurrentjob' workerst startmsg perform concurrentjob' workerst startmsg perform = case mkActionItem startmsg of OnlyActionOn k _ -> ensureOnlyActionOn k $ -- If another job performed the same action while we -- waited, there may be nothing left to do, so re-run -- the start stage to see if it still wants to do -- something. start >>= \case Just (startmsg', perform') -> case mkActionItem startmsg' of OnlyActionOn k' _ | k' /= k -> concurrentjob' workerst startmsg' perform' _ -> beginjob workerst startmsg' perform' Nothing -> noop _ -> beginjob workerst startmsg perform beginjob workerst startmsg perform = inOwnConsoleRegion (Annex.output workerst) $ do enteringInitialStage void $ accountCommandAction startmsg $ performconcurrent startmsg perform -- Like performCommandAction' but the worker thread's stage -- is changed before starting the cleanup action. performconcurrent startmsg perform = do showStartMessage startmsg perform >>= \case Just cleanup -> enteringStage CleanupStage $ do r <- cleanup showEndMessage startmsg r return r Nothing -> do showEndMessage startmsg False return False {- Waits for all worker threads to finish and merges their AnnexStates - back into the current Annex's state. -} finishCommandActions :: Annex () finishCommandActions = Annex.getState Annex.workers >>= \case Nothing -> noop Just tv -> do Annex.changeState $ \s -> s { Annex.workers = Nothing } vs <- liftIO $ atomically $ do pool <- readTMVar tv if allIdle pool then return (spareVals pool) else retry mapM_ (mergeState . fst) vs {- Waits for all worker threads that have been started so far to finish. -} waitForAllRunningCommandActions :: Annex () waitForAllRunningCommandActions = Annex.getState Annex.workers >>= \case Nothing -> noop Just tv -> liftIO $ atomically $ do pool <- readTMVar tv unless (allIdle pool) retry {- Like commandAction, but without the concurrency. -} includeCommandAction :: CommandStart -> CommandCleanup includeCommandAction start = start >>= \case Nothing -> return True Just (startmsg, perform) -> do showStartMessage startmsg accountCommandAction startmsg $ performCommandAction' startmsg perform accountCommandAction :: StartMessage -> CommandCleanup -> CommandCleanup accountCommandAction startmsg cleanup = tryNonAsync cleanup >>= \case Right True -> return True Right False -> incerr Left err -> case fromException err of Just exitcode -> liftIO $ exitWith exitcode Nothing -> do toplevelWarning True (show err) showEndMessage startmsg False incerr where incerr = do Annex.incError return False {- Runs a single command action through the start, perform and cleanup - stages, without catching errors and without incrementing error counter. - Useful if one command wants to run part of another command. -} callCommandAction :: CommandStart -> CommandCleanup callCommandAction start = start >>= \case Just (startmsg, perform) -> do showStartMessage startmsg performCommandAction' startmsg perform Nothing -> return True performCommandAction' :: StartMessage -> CommandPerform -> CommandCleanup performCommandAction' startmsg perform = perform >>= \case Nothing -> do showEndMessage startmsg False return False Just cleanup -> do r <- cleanup showEndMessage startmsg r return r {- Start concurrency when that has been requested. - Should be run wrapping the seek stage of a command. - - Note that a duplicate of the Annex state is made here, and worker - threads use that state. While the worker threads are not actually - started here, that has the same effect. -} startConcurrency :: UsedStages -> Annex a -> Annex a startConcurrency usedstages a = do fromcmdline <- getConcurrency fromgitcfg <- annexJobs <$> Annex.getGitConfig let usegitcfg = setConcurrency (ConcurrencyGitConfig fromgitcfg) case (fromcmdline, fromgitcfg) of (NonConcurrent, NonConcurrent) -> a (Concurrent n, _) -> goconcurrent n (ConcurrentPerCpu, _) -> goconcurrentpercpu (NonConcurrent, Concurrent n) -> do usegitcfg goconcurrent n (NonConcurrent, ConcurrentPerCpu) -> do usegitcfg goconcurrentpercpu where goconcurrent n = do raisecapabilitiesto n withMessageState $ \s -> case outputType s of NormalOutput -> ifM (liftIO concurrentOutputSupported) ( Regions.displayConsoleRegions $ goconcurrent' n True , goconcurrent' n False ) _ -> goconcurrent' n False goconcurrent' n b = bracket_ (setup n b) cleanup a goconcurrentpercpu = goconcurrent =<< liftIO getNumProcessors setup n b = do setconcurrentoutputenabled b initworkerpool n cleanup = do finishCommandActions setconcurrentoutputenabled False setconcurrentoutputenabled b = Annex.changeState $ \s -> s { Annex.output = (Annex.output s) { concurrentOutputEnabled = b } } raisecapabilitiesto n = do c <- liftIO getNumCapabilities when (n > c) $ liftIO $ setNumCapabilities n initworkerpool n = do tv <- liftIO newEmptyTMVarIO Annex.changeState $ \s -> s { Annex.workers = Just tv } prepDupState st <- dupState rd <- Annex.getRead id liftIO $ atomically $ putTMVar tv $ allocateWorkerPool (st, rd) (max n 1) usedstages -- Make sure that some expensive actions have been done before -- starting threads. This way the state has them already run, -- and each thread won't try to do them. prepDupState :: Annex () prepDupState = do _ <- remoteList return () {- Ensures that only one thread processes a key at a time. - Other threads will block until it's done. - - May be called repeatedly by the same thread without blocking. -} ensureOnlyActionOn :: Key -> Annex a -> Annex a ensureOnlyActionOn k a = debugLocks $ go =<< getConcurrency where go NonConcurrent = a go (Concurrent _) = goconcurrent go ConcurrentPerCpu = goconcurrent goconcurrent = do tv <- Annex.getRead Annex.activekeys bracket (setup tv) id (const a) setup tv = liftIO $ do mytid <- myThreadId atomically $ do m <- readTVar tv case M.lookup k m of Just tid | tid /= mytid -> retry | otherwise -> return $ return () Nothing -> do writeTVar tv $! M.insert k mytid m return $ liftIO $ atomically $ modifyTVar tv $ M.delete k checkSizeLimit :: Maybe (TVar Integer) -> StartMessage -> Annex () -> Annex () checkSizeLimit Nothing _ a = a checkSizeLimit (Just sizelimitvar) startmsg a = case actionItemKey (mkActionItem startmsg) of Just k -> case fromKey keySize k of Just sz -> go sz Nothing -> do fsz <- catchMaybeIO $ withObjectLoc k $ liftIO . getFileSize maybe reachedlimit go fsz Nothing -> a where go sz = do fits <- liftIO $ atomically $ do n <- readTVar sizelimitvar let !n' = n - sz if n' >= 0 then do writeTVar sizelimitvar n' return True else return False if fits then a else reachedlimit reachedlimit = Annex.changeState $ \s -> s { Annex.reachedlimit = True }