{-# LANGUAGE RecordWildCards, GeneralizedNewtypeDeriving, ScopedTypeVariables, PatternGuards #-} {-# LANGUAGE ExistentialQuantification, MultiParamTypeClasses #-} {-# LANGUAGE CPP #-} #if __GLASGOW_HASKELL__ >= 704 {-# LANGUAGE ConstraintKinds #-} #endif module Development.Shake.Core( run, #if __GLASGOW_HASKELL__ >= 704 ShakeValue, #endif Rule(..), Rules, rule, action, withoutActions, alternatives, priority, Action, actionOnException, actionFinally, apply, apply1, traced, getShakeOptions, trackUse, trackChange, trackAllow, getVerbosity, putLoud, putNormal, putQuiet, withVerbosity, quietly, Resource, newResource, newResourceIO, withResource, withResources, newThrottle, newThrottleIO, newCache, newCacheIO, unsafeExtraThread, -- Internal stuff rulesIO, runAfter ) where import Control.Exception as E import Control.Applicative import Control.Arrow import Control.Concurrent import Control.Monad import Control.Monad.IO.Class import Control.Monad.Trans.Writer.Strict import Data.Typeable import Data.Function import Data.List import qualified Data.HashMap.Strict as Map import Data.Maybe import Data.Monoid import Data.IORef import System.Directory import System.IO import Development.Shake.Classes import Development.Shake.Pool import Development.Shake.Database import Development.Shake.Resource import Development.Shake.Value import Development.Shake.Report import Development.Shake.Types import Development.Shake.Errors import General.Timing import General.Base import General.String import General.RAW --------------------------------------------------------------------- -- RULES #if __GLASGOW_HASKELL__ >= 704 -- | Define an alias for the six type classes required for things involved in Shake 'Development.Shake.Rule's. -- This alias is only available in GHC 7.4 and above, and requires the @ConstraintKinds@ extension. -- -- To define your own values meeting the necessary constraints it is convenient to use the extensions -- @GeneralizedNewtypeDeriving@ and @DeriveDataTypeable@ to write: -- -- > newtype MyType = MyType (String, Bool) deriving (Show,Typeable,Eq,Hashable,Binary,NFData) type ShakeValue a = (Show a, Typeable a, Eq a, Hashable a, Binary a, NFData a) #endif -- | Define a pair of types that can be used by Shake rules. -- To import all the type classes required see "Development.Shake.Classes". class ( #if __GLASGOW_HASKELL__ >= 704 ShakeValue key, ShakeValue value #else Show key, Typeable key, Eq key, Hashable key, Binary key, NFData key, Show value, Typeable value, Eq value, Hashable value, Binary value, NFData value #endif ) => Rule key value where -- | /[Required]/ Retrieve the @value@ associated with a @key@, if available. -- -- As an example for filenames/timestamps, if the file exists you should return 'Just' -- the timestamp, but otherwise return 'Nothing'. For rules whose values are not -- stored externally, 'storedValue' should return 'Nothing'. storedValue :: ShakeOptions -> key -> IO (Maybe value) -- | /[Optional]/ Equality check, with a notion of how expensive the check was. equalValue :: ShakeOptions -> key -> value -> value -> EqualCost equalValue _ _ v1 v2 = if v1 == v2 then EqualCheap else NotEqual data ARule m = forall key value . Rule key value => ARule (key -> Maybe (m value)) ruleKey :: Rule key value => (key -> Maybe (m value)) -> key ruleKey = err "ruleKey" ruleValue :: Rule key value => (key -> Maybe (m value)) -> value ruleValue = err "ruleValue" -- | Define a set of rules. Rules can be created with calls to functions such as 'Development.Shake.*>' or 'action'. Rules are combined -- with either the 'Monoid' instance, or (more commonly) the 'Monad' instance and @do@ notation. To define your own -- custom types of rule, see "Development.Shake.Rule". newtype Rules a = Rules (WriterT (SRules Action) IO a) -- All IO must be associative/commutative (e.g. creating IORef/MVars) deriving (Monad, Functor, Applicative) rulesIO :: IO a -> Rules a rulesIO = Rules . liftIO newRules :: SRules Action -> Rules () newRules = Rules . tell modifyRules :: (SRules Action -> SRules Action) -> Rules () -> Rules () modifyRules f (Rules r) = Rules $ censor f r getRules :: Rules () -> IO (SRules Action) getRules (Rules r) = execWriterT r data SRules m = SRules {actions :: [m ()] ,rules :: Map.HashMap TypeRep{-k-} (TypeRep{-k-},TypeRep{-v-},[(Double,ARule m)]) -- higher fst is higher priority } instance Monoid (SRules m) where mempty = SRules [] (Map.fromList []) mappend (SRules x1 x2) (SRules y1 y2) = SRules (x1++y1) (Map.unionWith f x2 y2) where f (k, v1, xs) (_, v2, ys) | v1 == v2 = (k, v1, xs ++ ys) | otherwise = errorIncompatibleRules k v1 v2 instance Monoid a => Monoid (Rules a) where mempty = return mempty mappend = liftA2 mappend -- | Add a rule to build a key, returning an appropriate 'Action'. All rules at a given priority -- must be disjoint. Rules have priority 1 by default, but can be modified with 'priority'. rule :: Rule key value => (key -> Maybe (Action value)) -> Rules () rule r = newRules mempty{rules = Map.singleton k (k, v, [(1,ARule r)])} where k = typeOf $ ruleKey r; v = typeOf $ ruleValue r -- | Change the priority of a given set of rules, where higher priorities take precedence. -- All matching rules at a given priority must be disjoint, or an error is raised. -- All builtin Shake rules have priority between 0 and 1. -- Excessive use of 'priority' is discouraged. As an example: -- -- @ -- 'priority' 4 $ \"hello.*\" *> \\out -> 'writeFile'' out \"hello.*\" -- 'priority' 8 $ \"*.txt\" *> \\out -> 'writeFile'' out \"*.txt\" -- @ -- -- In this example @hello.txt@ will match the second rule, instead of raising an error about ambiguity. priority :: Double -> Rules () -> Rules () priority i = modifyRules $ \s -> s{rules = Map.map (\(a,b,cs) -> (a,b,map (first $ const i) cs)) $ rules s} -- | Change the matching behaviour of rules so rules do not have to be disjoint, but are instead matched -- in order. Only recommended for small blocks containing a handful of rules. -- -- @ -- 'alternatives' $ do -- \"hello.*\" *> \\out -> 'writeFile'' out \"hello.*\" -- \"*.txt\" *> \\out -> 'writeFile'' out \"*.txt\" -- @ -- -- In this example @hello.txt@ will match the first rule, instead of raising an error about ambiguity. alternatives :: Rules () -> Rules () alternatives = modifyRules $ \r -> r{rules = Map.map f $ rules r} where f (k, v, []) = (k, v, []) f (k, v, xs) = let (is,rs) = unzip xs in (k, v, [(maximum is, foldl1' g rs)]) g (ARule a) (ARule b) = ARule $ \x -> a x `mplus` b2 x where b2 = fmap (fmap (fromJust . cast)) . b . fromJust . cast -- | Run an action, usually used for specifying top-level requirements. -- -- @ -- main = 'Development.Shake.shake' 'shakeOptions' $ do -- 'action' $ do -- b <- 'Development.Shake.doesFileExist' \"file.src\" -- when b $ 'Development.Shake.need' [\"file.out\"] -- @ -- -- This 'action' builds @file.out@, but only if @file.src@ exists. The 'action' -- will be run in every build execution (unless 'withoutActions' is used), so only cheap -- operations should be performed. All arguments to 'action' may be run in parallel, in any order. -- -- For the standard requirement of only 'Development.Shake.need'ing a fixed list of files in the 'action', -- see 'Development.Shake.want'. action :: Action a -> Rules () action a = newRules mempty{actions=[void a]} -- | Remove all actions specified in a set of rules, usually used for implementing -- command line specification of what to build. withoutActions :: Rules () -> Rules () withoutActions = modifyRules $ \x -> x{actions=[]} registerWitnesses :: SRules m -> IO () registerWitnesses SRules{..} = forM_ (Map.elems rules) $ \(_, _, (_,ARule r):_) -> do registerWitness $ ruleKey r registerWitness $ ruleValue r data RuleInfo m = RuleInfo {stored :: Key -> IO (Maybe Value) ,equal :: Key -> Value -> Value -> EqualCost ,execute :: Key -> m Value ,resultType :: TypeRep } createRuleinfo :: ShakeOptions -> SRules Action -> Map.HashMap TypeRep (RuleInfo Action) createRuleinfo opt SRules{..} = flip Map.map rules $ \(_,tv,rs) -> RuleInfo (stored rs) (equal rs) (execute rs) tv where stored ((_,ARule r):_) = fmap (fmap newValue) . f r . fromKey where f :: Rule key value => (key -> Maybe (m value)) -> (key -> IO (Maybe value)) f _ = storedValue opt equal ((_,ARule r):_) = \k v1 v2 -> f r (fromKey k) (fromValue v1) (fromValue v2) where f :: Rule key value => (key -> Maybe (m value)) -> key -> value -> value -> EqualCost f _ = equalValue opt execute rs = \k -> case filter (not . null) $ map (mapMaybe ($ k)) rs2 of [r]:_ -> r rs -> errorMultipleRulesMatch (typeKey k) (show k) (length rs) where rs2 = sets [(i, \k -> fmap (fmap newValue) $ r (fromKey k)) | (i,ARule r) <- rs] sets :: Ord a => [(a, b)] -> [[b]] -- highest to lowest sets = map (map snd) . reverse . groupBy ((==) `on` fst) . sortBy (compare `on` fst) runStored :: Map.HashMap TypeRep (RuleInfo m) -> Key -> IO (Maybe Value) runStored mp k = case Map.lookup (typeKey k) mp of Nothing -> return Nothing Just RuleInfo{..} -> stored k runEqual :: Map.HashMap TypeRep (RuleInfo m) -> Key -> Value -> Value -> EqualCost runEqual mp k v1 v2 = case Map.lookup (typeKey k) mp of Nothing -> NotEqual Just RuleInfo{..} -> equal k v1 v2 runExecute :: Map.HashMap TypeRep (RuleInfo m) -> Key -> m Value runExecute mp k = let tk = typeKey k in case Map.lookup tk mp of Nothing -> errorNoRuleToBuildType tk (Just $ show k) Nothing -- Not sure if this is even possible, but best be safe Just RuleInfo{..} -> execute k --------------------------------------------------------------------- -- MAKE -- global constants of Action data Global = Global {globalDatabase :: Database ,globalPool :: Pool ,globalTimestamp :: IO Time ,globalRules :: Map.HashMap TypeRep (RuleInfo Action) ,globalOutput :: Verbosity -> String -> IO () ,globalOptions :: ShakeOptions ,globalDiagnostic :: String -> IO () ,globalLint :: String -> IO () ,globalAfter :: IORef [IO ()] ,globalTrackAbsent :: IORef [(Key, Key)] -- in rule fst, snd must be absent } -- local variables of Action data Local = Local -- constants {localStack :: Stack -- stack scoped local variables ,localVerbosity :: Verbosity ,localBlockApply :: Maybe String -- reason to block apply, or Nothing to allow -- mutable local variables ,localDepends :: [Depends] -- built up in reverse ,localDiscount :: !Duration ,localTraces :: [Trace] -- in reverse ,localTrackAllows :: [Key -> Bool] ,localTrackUsed :: [Key] } -- | The 'Action' monad, use 'liftIO' to raise 'IO' actions into it, and 'Development.Shake.need' to execute files. -- Action values are used by 'rule' and 'action'. The 'Action' monad tracks the dependencies of a 'Rule'. newtype Action a = Action {fromAction :: RAW Global Local a} deriving (Functor, Applicative, Monad, MonadIO) -- | If an exception is raised by the 'Action', perform some 'IO'. actionOnException :: Action a -> IO b -> Action a actionOnException act clean = Action $ catchRAW (fromAction act) (\(e :: SomeException) -> liftIO clean >> throwRAW e) -- | After an 'Action', perform some 'IO', even if there is an exception. actionFinally :: Action a -> IO b -> Action a actionFinally act clean = do res <- actionOnException act clean liftIO clean return res -- | Internal main function (not exported publicly) run :: ShakeOptions -> Rules () -> IO () run opts@ShakeOptions{..} rs = (if shakeLineBuffering then lineBuffering else id) $ do start <- offsetTime rs <- getRules rs registerWitnesses rs outputLocked <- do lock <- newLock return $ \v msg -> withLock lock $ shakeOutput v msg let diagnostic = if shakeVerbosity >= Diagnostic then outputLocked Diagnostic . ("% "++) else const $ return () let output v = outputLocked v . abbreviate shakeAbbreviations except <- newIORef (Nothing :: Maybe (String, SomeException)) let staunch act | not shakeStaunch = void act | otherwise = do res <- try act case res of Left err -> do let named = maybe "unknown rule" shakeExceptionTarget . cast atomicModifyIORef except $ \v -> (Just $ fromMaybe (named err, err) v, ()) let msg = show err ++ "Continuing due to staunch mode, this error will be repeated later" when (shakeVerbosity >= Quiet) $ output Quiet msg Right _ -> return () lint <- if isNothing shakeLint then return $ const $ return () else do dir <- getCurrentDirectory return $ \msg -> do now <- getCurrentDirectory when (dir /= now) $ errorStructured "Lint checking error - current directory has changed" [("When", Just msg) ,("Wanted",Just dir) ,("Got",Just now)] "" progressThread <- newIORef Nothing after <- newIORef [] absent <- newIORef [] let cleanup = do flip whenJust killThread =<< readIORef progressThread when shakeTimings printTimings resetTimings -- so we don't leak memory shakeThreads <- if shakeThreads == 0 then getProcessorCount else return shakeThreads flip finally cleanup $ withCapabilities shakeThreads $ do withDatabase opts diagnostic $ \database -> do tid <- forkIO $ shakeProgress $ do failure <- fmap (fmap fst) $ readIORef except stats <- progress database return stats{isFailure=failure} writeIORef progressThread $ Just tid let ruleinfo = createRuleinfo opts rs addTiming "Running rules" runPool (shakeThreads == 1) shakeThreads $ \pool -> do let s0 = Global database pool start ruleinfo output opts diagnostic lint after absent let s1 = Local emptyStack shakeVerbosity Nothing [] 0 [] [] [] mapM_ (addPool pool . staunch . runAction s0 s1) (actions rs) when (isJust shakeLint) $ do addTiming "Lint checking" absent <- readIORef absent checkValid database (runStored ruleinfo) (runEqual ruleinfo) absent when (shakeVerbosity >= Loud) $ output Loud "Lint checking succeeded" when (shakeReport /= []) $ do addTiming "Profile report" report <- toReport database forM_ shakeReport $ \file -> do when (shakeVerbosity >= Normal) $ output Normal $ "Writing report to " ++ file buildReport file report maybe (return ()) (throwIO . snd) =<< readIORef except sequence_ . reverse =<< readIORef after lineBuffering :: IO a -> IO a lineBuffering = withBufferMode stdout LineBuffering . withBufferMode stderr LineBuffering abbreviate :: [(String,String)] -> String -> String abbreviate [] = id abbreviate abbrev = f where -- order so longer appreviations are preferred ordAbbrev = sortBy (flip (compare `on` length . fst)) abbrev f [] = [] f x | (to,rest):_ <- [(to,rest) | (from,to) <- ordAbbrev, Just rest <- [stripPrefix from x]] = to ++ f rest f (x:xs) = x : f xs wrapStack :: IO [String] -> IO a -> IO a wrapStack stk act = E.catch act $ \(SomeException e) -> case cast e of Just s@ShakeException{} -> throwIO s Nothing -> do stk <- stk if null stk then throwIO e else throwIO $ ShakeException (last stk) stk $ SomeException e runAction :: Global -> Local -> Action a -> IO a runAction g l (Action x) = runRAW g l x runAfter :: IO () -> Action () runAfter op = do Global{..} <- Action getRO liftIO $ atomicModifyIORef globalAfter $ \ops -> (op:ops, ()) -- | Execute a rule, returning the associated values. If possible, the rules will be run in parallel. -- This function requires that appropriate rules have been added with 'rule'. -- All @key@ values passed to 'apply' become dependencies of the 'Action'. apply :: Rule key value => [key] -> Action [value] apply = f -- Don't short-circuit [] as we still want error messages where -- We don't want the forall in the Haddock docs f :: forall key value . Rule key value => [key] -> Action [value] f ks = do let tk = typeOf (err "apply key" :: key) tv = typeOf (err "apply type" :: value) Global{..} <- Action getRO block <- Action $ getsRW localBlockApply whenJust block $ errorNoApply tk (fmap show $ listToMaybe ks) case Map.lookup tk globalRules of Nothing -> errorNoRuleToBuildType tk (fmap show $ listToMaybe ks) (Just tv) Just RuleInfo{resultType=tv2} | tv /= tv2 -> errorRuleTypeMismatch tk (fmap show $ listToMaybe ks) tv2 tv _ -> fmap (map fromValue) $ applyKeyValue $ map newKey ks applyKeyValue :: [Key] -> Action [Value] applyKeyValue [] = return [] applyKeyValue ks = do global@Global{..} <- Action getRO let exec stack k = try $ wrapStack (showStack globalDatabase stack) $ do evaluate $ rnf k let s = Local {localVerbosity=shakeVerbosity globalOptions, localDepends=[], localStack=stack, localBlockApply=Nothing ,localDiscount=0, localTraces=[], localTrackAllows=[], localTrackUsed=[]} let top = showTopStack stack globalLint $ "before building " ++ top (dur,(res,Local{..})) <- duration $ runAction global s $ do putWhen Chatty $ "# " ++ show k res <- runExecute globalRules k when (shakeLint globalOptions == Just LintTracker) trackCheckUsed Action $ fmap ((,) res) getRW globalLint $ "after building " ++ top let ans = (res, reverse localDepends, dur - localDiscount, reverse localTraces) evaluate $ rnf ans return ans stack <- Action $ getsRW localStack res <- liftIO $ build globalPool globalDatabase (Ops (runStored globalRules) (runEqual globalRules) exec) stack ks case res of Left err -> throw err Right (dur, dep, vs) -> do Action $ modifyRW $ \s -> s{localDiscount=localDiscount s + dur, localDepends=dep : localDepends s} return vs -- | Apply a single rule, equivalent to calling 'apply' with a singleton list. Where possible, -- use 'apply' to allow parallelism. apply1 :: Rule key value => key -> Action value apply1 = fmap head . apply . return -- | Get the initial 'ShakeOptions', these will not change during the build process. getShakeOptions :: Action ShakeOptions getShakeOptions = Action $ getsRO globalOptions -- | Write an action to the trace list, along with the start/end time of running the IO action. -- The 'Development.Shake.cmd' and 'Development.Shake.command' functions automatically call 'traced'. -- The trace list is used for profile reports (see 'shakeReport'). traced :: String -> IO a -> Action a traced msg act = do Global{..} <- Action getRO stack <- Action $ getsRW localStack start <- liftIO globalTimestamp putNormal $ "# " ++ msg ++ " (for " ++ showTopStack stack ++ ")" res <- liftIO act stop <- liftIO globalTimestamp Action $ modifyRW $ \s -> s{localTraces = Trace (pack msg) start stop : localTraces s} return res putWhen :: Verbosity -> String -> Action () putWhen v msg = do Global{..} <- Action getRO verb <- getVerbosity when (verb >= v) $ liftIO $ globalOutput v msg -- | Write a message to the output when the verbosity ('shakeVerbosity') is appropriate. -- The output will not be interleaved with any other Shake messages -- (other than those generated by system commands). putLoud, putNormal, putQuiet :: String -> Action () putLoud = putWhen Loud putNormal = putWhen Normal putQuiet = putWhen Quiet -- | Get the current verbosity level, originally set by 'shakeVerbosity'. If you -- want to output information to the console, you are recommended to use -- 'putLoud' \/ 'putNormal' \/ 'putQuiet', which ensures multiple messages are -- not interleaved. The verbosity can be modified locally by 'withVerbosity'. getVerbosity :: Action Verbosity getVerbosity = Action $ getsRW localVerbosity -- | Run an action with a particular verbosity level. -- Will not update the 'shakeVerbosity' returned by 'getShakeOptions' and will -- not have any impact on 'Diagnostic' tracing. withVerbosity :: Verbosity -> Action a -> Action a withVerbosity new = Action . unmodifyRW f . fromAction where f s0 = (s0{localVerbosity=new}, \s -> s{localVerbosity=localVerbosity s0}) -- | Run an action with 'Quiet' verbosity, in particular messages produced by 'traced' -- (including from 'Development.Shake.cmd' or 'Development.Shake.command') will not be printed to the screen. -- Will not update the 'shakeVerbosity' returned by 'getShakeOptions' and will -- not turn off any 'Diagnostic' tracing. quietly :: Action a -> Action a quietly = withVerbosity Quiet --------------------------------------------------------------------- -- TRACKING -- | Track that a key has been used by the action preceeding it. trackUse :: #if __GLASGOW_HASKELL__ >= 704 ShakeValue key #else (Show key, Typeable key, Eq key, Hashable key, Binary key, NFData key) #endif => key -> Action () -- One of the following must be true: -- 1) you are the one building this key (e.g. key == topStack) -- 2) you have already been used by apply, and are on the dependency list -- 3) someone explicitly gave you permission with trackAllow -- 4) at the end of the rule, a) you are now on the dependency list, and b) this key itself has no dependencies (is source file) trackUse key = do let k = newKey key Global{..} <- Action getRO l@Local{..} <- Action getRW deps <- liftIO $ concatMapM (listDepends globalDatabase) localDepends let top = topStack localStack if top == Just k then return () -- condition 1 else if k `elem` deps then return () -- condition 2 else if any ($ k) localTrackAllows then return () -- condition 3 else Action $ putRW l{localTrackUsed = k : localTrackUsed} -- condition 4 trackCheckUsed :: Action () trackCheckUsed = do Global{..} <- Action getRO Local{..} <- Action getRW liftIO $ do deps <- concatMapM (listDepends globalDatabase) localDepends -- check 3a bad <- return $ localTrackUsed \\ deps unless (null bad) $ do let n = length bad errorStructured ("Link checking error - " ++ (if n == 1 then "value was" else show n ++ " values were") ++ " used but not depended upon") [("Used", Just $ show x) | x <- bad] "" -- check 3b bad <- flip filterM localTrackUsed $ \k -> fmap (not . null) $ lookupDependencies globalDatabase k unless (null bad) $ do let n = length bad errorStructured ("Link checking error - " ++ (if n == 1 then "value was" else show n ++ " values were") ++ " depended upon after being used") [("Used", Just $ show x) | x <- bad] "" -- | Track that a key has been changed by the action preceeding it. trackChange :: #if __GLASGOW_HASKELL__ >= 704 ShakeValue key #else (Show key, Typeable key, Eq key, Hashable key, Binary key, NFData key) #endif => key -> Action () -- One of the following must be true: -- 1) you are the one building this key (e.g. key == topStack) -- 2) someone explicitly gave you permission with trackAllow -- 3) this file is never known to the build system, at the end it is not in the database trackChange key = do let k = newKey key Global{..} <- Action getRO Local{..} <- Action getRW liftIO $ do let top = topStack localStack if top == Just k then return () -- condition 1 else if any ($ k) localTrackAllows then return () -- condition 2 else -- condition 3 atomicModifyIORef globalTrackAbsent $ \ks -> ((fromMaybe k top, k):ks, ()) -- | Allow any matching key to violate the tracking rules. trackAllow :: #if __GLASGOW_HASKELL__ >= 704 ShakeValue key #else (Show key, Typeable key, Eq key, Hashable key, Binary key, NFData key) #endif => (key -> Bool) -> Action () trackAllow test = Action $ modifyRW $ \s -> s{localTrackAllows = f : localTrackAllows s} where -- We don't want the forall in the Haddock docs arrow1Type :: forall a b . Typeable a => (a -> b) -> TypeRep arrow1Type _ = typeOf (err "trackAllow" :: a) ty = arrow1Type test f k = typeKey k == ty && test (fromKey k) --------------------------------------------------------------------- -- RESOURCES -- | Create a finite resource, given a name (for error messages) and a quantity of the resource that exists. -- Shake will ensure that actions using the same finite resource do not execute in parallel. -- As an example, only one set of calls to the Excel API can occur at one time, therefore -- Excel is a finite resource of quantity 1. You can write: -- -- @ -- 'Development.Shake.shake' 'Development.Shake.shakeOptions'{'Development.Shake.shakeThreads'=2} $ do -- 'Development.Shake.want' [\"a.xls\",\"b.xls\"] -- excel <- 'Development.Shake.newResource' \"Excel\" 1 -- \"*.xls\" 'Development.Shake.*>' \\out -> -- 'Development.Shake.withResource' excel 1 $ -- 'Development.Shake.cmd' \"excel\" out ... -- @ -- -- Now the two calls to @excel@ will not happen in parallel. -- -- As another example, calls to compilers are usually CPU bound but calls to linkers are usually -- disk bound. Running 8 linkers will often cause an 8 CPU system to grid to a halt. We can limit -- ourselves to 4 linkers with: -- -- @ -- disk <- 'Development.Shake.newResource' \"Disk\" 4 -- 'Development.Shake.want' [show i 'Development.Shake.FilePath.<.>' \"exe\" | i <- [1..100]] -- \"*.exe\" 'Development.Shake.*>' \\out -> -- 'Development.Shake.withResource' disk 1 $ -- 'Development.Shake.cmd' \"ld -o\" [out] ... -- \"*.o\" 'Development.Shake.*>' \\out -> -- 'Development.Shake.cmd' \"cl -o\" [out] ... -- @ newResource :: String -> Int -> Rules Resource newResource name mx = rulesIO $ newResourceIO name mx -- | Create a throttled resource, given a name (for error messages) and a number of resources (the 'Int') that can be -- used per time period (the 'Double' in seconds). Shake will ensure that actions using the same throttled resource -- do not exceed the limits. As an example, let us assume that making more than 1 request every 5 seconds to -- Google results in our client being blacklisted, we can write: -- -- @ -- google <- 'Development.Shake.newThrottle' \"Google\" 1 5 -- \"*.url\" 'Development.Shake.*>' \\out -> do -- 'Development.Shake.withResource' google 1 $ -- 'Development.Shake.cmd' \"wget\" [\"http:\/\/google.com?q=\" ++ 'Development.Shake.FilePath.takeBaseName' out] \"-O\" [out] -- @ -- -- Now we will wait at least 5 seconds after querying Google before performing another query. If Google change the rules to -- allow 12 requests per minute we can instead use @'Development.Shake.newThrottle' \"Google\" 12 60@, which would allow -- greater parallelisation, and avoid throttling entirely if only a small number of requests are necessary. -- -- In the original example we never make a fresh request until 5 seconds after the previous request has /completed/. If we instead -- want to throttle requests since the previous request /started/ we can write: -- -- @ -- google <- 'Development.Shake.newThrottle' \"Google\" 1 5 -- \"*.url\" 'Development.Shake.*>' \\out -> do -- 'Development.Shake.withResource' google 1 $ return () -- 'Development.Shake.cmd' \"wget\" [\"http:\/\/google.com?q=\" ++ 'Development.Shake.FilePath.takeBaseName' out] \"-O\" [out] -- @ -- -- However, the rule may not continue running immediately after 'Development.Shake.withResource' completes, so while -- we will never exceed an average of 1 request every 5 seconds, we may end up running an unbounded number of -- requests simultaneously. If this limitation causes a problem in practice it can be fixed. newThrottle :: String -> Int -> Double -> Rules Resource newThrottle name count period = rulesIO $ newThrottleIO name count period blockApply :: String -> Action a -> Action a blockApply msg = Action . unmodifyRW f . fromAction where f s0 = (s0{localBlockApply=Just msg}, \s -> s{localBlockApply=localBlockApply s0}) -- | Run an action which uses part of a finite resource. For more details see 'Resource'. -- You cannot depend on a rule (e.g. 'need') while a resource is held. withResource :: Resource -> Int -> Action a -> Action a withResource r i act = Action $ do Global{..} <- getRO act <- evalRAW $ fromAction $ blockApply ("Within withResource using " ++ show r) act join $ liftIO $ bracket_ (do res <- acquireResource r i case res of Nothing -> globalDiagnostic $ show r ++ " acquired " ++ show i ++ " with no wait" Just wait -> do globalDiagnostic $ show r ++ " waiting to acquire " ++ show i blockPool globalPool $ fmap ((,) False) wait globalDiagnostic $ show r ++ " acquired " ++ show i ++ " after waiting") (do releaseResource r i globalDiagnostic $ show r ++ " released " ++ show i) act -- | Run an action which uses part of several finite resources. Acquires the resources in a stable -- order, to prevent deadlock. If all rules requiring more than one resource acquire those -- resources with a single call to 'withResources', resources will not deadlock. withResources :: [(Resource, Int)] -> Action a -> Action a withResources res act | (r,i):_ <- filter ((< 0) . snd) res = error $ "You cannot acquire a negative quantity of " ++ show r ++ ", requested " ++ show i | otherwise = f $ groupBy ((==) `on` fst) $ sortBy (compare `on` fst) res where f [] = act f (r:rs) = withResource (fst $ head r) (sum $ map snd r) $ f rs -- | A version of 'newCache' that runs in IO, and can be called before calling 'Development.Shake.shake'. -- Most people should use 'newCache' instead. newCacheIO :: (Eq k, Hashable k) => (k -> Action v) -> IO (k -> Action v) newCacheIO act = do var {- :: Var (Map k (Barrier (Either SomeException ([Depends],v)))) -} <- newVar Map.empty return $ \key -> do join $ liftIO $ modifyVar var $ \mp -> case Map.lookup key mp of Just bar -> return $ (,) mp $ do res <- liftIO $ waitBarrierMaybe bar res <- case res of Nothing -> do pool <- Action $ getsRO globalPool; liftIO $ blockPool pool $ fmap ((,) False) $ waitBarrier bar Just res -> return res case res of Left err -> Action $ throwRAW err Right (deps,v) -> do Action $ modifyRW $ \s -> s{localDepends = deps ++ localDepends s} return v Nothing -> do bar <- newBarrier return $ (,) (Map.insert key bar mp) $ do pre <- Action $ getsRW localDepends res <- Action $ tryRAW $ fromAction $ act key case res of Left err -> do liftIO $ signalBarrier bar $ Left (err :: SomeException) Action $ throwRAW err Right v -> do post <- Action $ getsRW localDepends let deps = take (length post - length pre) post liftIO $ signalBarrier bar (Right (deps, v)) return v -- | Given an action on a key, produce a cached version that will execute the action at most once per key. -- Using the cached result will still result include any dependencies that the action requires. -- Each call to 'newCache' creates a separate cache that is independent of all other calls to 'newCache'. -- -- This function is useful when creating files that store intermediate values, -- to avoid the overhead of repeatedly reading from disk, particularly if the file requires expensive parsing. -- As an example: -- -- @ -- digits \<- 'newCache' $ \\file -> do -- src \<- readFile\' file -- return $ length $ filter isDigit src -- \"*.digits\" 'Development.Shake.*>' \\x -> do -- v1 \<- digits ('dropExtension' x) -- v2 \<- digits ('dropExtension' x) -- 'Development.Shake.writeFile'' x $ show (v1,v2) -- @ -- -- To create the result @MyFile.txt.digits@ the file @MyFile.txt@ will be read and counted, but only at most -- once per execution. newCache :: (Eq k, Hashable k) => (k -> Action v) -> Rules (k -> Action v) newCache = rulesIO . newCacheIO -- | Run an action without counting to the thread limit, typically used for actions that execute -- on remote machines using barely any local CPU resources. Unsafe as it allows the 'shakeThreads' limit to be exceeded. -- You cannot depend on a rule (e.g. 'need') while the extra thread is executing. unsafeExtraThread :: Action a -> Action a unsafeExtraThread act = Action $ do Global{..} <- getRO act <- evalRAW $ fromAction act join $ liftIO $ blockPool globalPool $ fmap ((,) False) act