{-# LANGUAGE BangPatterns , DeriveDataTypeable, CPP #-} module Control.Concurrent.Chan.Unagi.Bounded.Internal ( InChan(..), OutChan(..), ChanEnd(..), StreamSegment, Cell(..), Stream(..) , writerCheckin, unblockWriters, tryWriterCheckin, WriterCheckpoint(..) , NextSegment(..), StreamHead(..) , newChanStarting, writeChan, readChan, readChanOnException , tryWriteChan, tryReadChan , dupChan , estimatedLength ) where -- NOTE: forked from src/Control/Concurrent/Chan/Unagi/Internal.hs 43706b2 -- some commentary not specific to this Bounded variant has been removed. -- See the Unagi source for that. import Control.Concurrent.MVar import Data.IORef import Control.Exception import Control.Monad.Primitive(RealWorld) import Data.Atomics.Counter.Fat import Data.Atomics import qualified Data.Primitive as P import Control.Monad import Control.Applicative import Data.Bits import Data.Maybe(fromMaybe,isJust) import Data.Typeable(Typeable) import GHC.Exts(inline) import Utilities(nextHighestPowerOfTwo) import qualified Control.Concurrent.Chan.Unagi.NoBlocking.Types as UT import Prelude -- | The write end of a channel created with 'newChan'. data InChan a = InChan (IO Int) -- readCounterReader, for tryWriteChan !(Ticket (Cell a)) !(ChanEnd a) deriving Typeable -- | The read end of a channel created with 'newChan'. newtype OutChan a = OutChan (ChanEnd a) deriving Typeable instance Eq (InChan a) where (InChan _ _ (ChanEnd _ _ _ _ headA)) == (InChan _ _ (ChanEnd _ _ _ _ headB)) = headA == headB instance Eq (OutChan a) where (OutChan (ChanEnd _ _ _ _ headA)) == (OutChan (ChanEnd _ _ _ _ headB)) = headA == headB data ChanEnd a = -- For efficient div and mod: ChanEnd !Int -- logBase 2 BOUNDS !Int -- BOUNDS - 1 -- an efficient producer of segments of length BOUNDS: !(SegSource a) -- Both Chan ends must start with the same counter value. !AtomicCounter -- the stream head; this must never point to a segment whose offset -- is greater than the counter value !(IORef (StreamHead a)) -- NOTE [1] deriving Typeable -- [1] For the writers' ChanEnd: the segment that appears in the StreamHead is -- implicitly unlocked for writers (the segment size being equal to the chan -- bounds). See 'writeChan' for notes on how we make sure to keep this -- invariant. data StreamHead a = StreamHead !Int !(Stream a) -- This is always of length BOUNDS type StreamSegment a = P.MutableArray RealWorld (Cell a) data Cell a = Empty | Written a | Blocking !(MVar a) data Stream a = Stream !(StreamSegment a) -- The next segment in the stream; new segments are allocated and -- put here by the reader of index-0 of the previous segment. That -- reader (and the next one or two) also do a tryPutMVar to the MVar -- below, to indicate that any blocked writers may proceed. !(IORef (Maybe (NextSegment a))) -- writers that find Nothing above, must check in with a possibly -- blocking readMVar here before proceeding (the slow path): -- Next segment, installed by either a reader or a writer: data NextSegment a = NextByWriter (Stream a) -- the next stream segment !WriterCheckpoint -- blocking for this segment -- a reader-installed one is implicitly unlocked for writers -- so needs no checkpoint: | NextByReader (Stream a) -- helper accessors TODO consider making records getNextRef :: NextSegment a -> IORef (Maybe (NextSegment a)) getNextRef x = (\(Stream _ nextSegRef)-> nextSegRef) $ getStr x getStr :: NextSegment a -> Stream a getStr (NextByReader str) = str getStr (NextByWriter str _) = str asReader, asWriter :: Bool asReader = True asWriter = False -- WRITER BLOCKING SCHEME OVERVIEW -- ------------------------------- -- We use segments of size equal to the requested bounds. When a reader reads -- index 0 of a segment it tries to pre-allocate the next segment, marking it -- installed by reader (NextByReader), which indicates to writers who read it -- that they may write and return without blocking (and this makes the queue -- loosely bounded between size n and n*2). -- -- Whenever a reader encounters a segment (in waitingAdvanceStream) installed -- by a writer it unblocks writers and rewrites the NextBy* constructor to -- NextByReader, replacing the installed stream segment. -- -- Writers first make their write available (by writing to the segment) before -- doing any blocking. This is more efficient, lets us handle async exceptions -- in a principled way without changing the semantics. This also means that in -- some cases a writer will install the next segment, marked installed by -- writer, insicating that writers must checkin and block; readers will mark -- these segments as installed by reader to avoid unnecessary overhead when the -- segment becomes unlocked as described in the paragraph above. -- -- The writer StreamHead is only ever updated by a writer that sees that a -- segment is unlocked for writing (either because the writer has returned from -- blocking on that segment, or because it sees that it was installed by a -- reader); in this way a writer knows if its segment is at the StreamHead that -- it is free to write and return without blocking (writerCheckin). newChanStarting :: Int -> Int -> IO (InChan a, OutChan a) {-# INLINE newChanStarting #-} newChanStarting !startingCellOffset !sizeDirty = do let !size = nextHighestPowerOfTwo sizeDirty !logBounds = round $ logBase (2::Float) $ fromIntegral size !boundsMn1 = size - 1 segSource <- newSegmentSource size firstSeg <- segSource -- collect a ticket to save for writer CAS savedEmptyTkt <- readArrayElem firstSeg 0 stream <- Stream firstSeg <$> newIORef Nothing let end = ChanEnd logBounds boundsMn1 segSource <$> newCounter startingCellOffset <*> newIORef (StreamHead startingCellOffset stream) endR@(ChanEnd _ _ _ counterR _) <- end endW <- end assert (size > 0 && (boundsMn1 + 1) == 2 ^ logBounds) $ return ( InChan (readCounter counterR) savedEmptyTkt endW , OutChan endR ) -- | Duplicate a chan: the returned @OutChan@ begins empty, but data written to -- the argument @InChan@ from then on will be available from both the original -- @OutChan@ and the one returned here, creating a kind of broadcast channel. -- -- Writers will be blocked only when the fastest reader falls behind the -- bounds; slower readers of duplicated 'OutChan' may fall arbitrarily behind. dupChan :: InChan a -> IO (OutChan a) {-# INLINE dupChan #-} dupChan (InChan _ _ (ChanEnd logBounds boundsMn1 segSource counter streamHead)) = do hLoc <- readIORef streamHead loadLoadBarrier wCount <- readCounter counter counter' <- newCounter wCount streamHead' <- newIORef hLoc return $ OutChan $ ChanEnd logBounds boundsMn1 segSource counter' streamHead' -- | Write a value to the channel. If the chan is full this will block. -- -- To be precise this /may/ block when the number of elements in the queue -- @>= size@, and will certainly block when @>= size*2@, where @size@ is the -- argument passed to 'newChan', rounded up to the next highest power of two. -- -- /Note re. exceptions/: In the case that an async exception is raised -- while blocking here, the write will nonetheless succeed. When not blocking, -- exceptions are masked. Thus writes always succeed once 'writeChan' is -- entered. writeChan :: InChan a -> a -> IO () {-# INLINE writeChan #-} writeChan c = \a-> writeChanWithBlocking True c a writeChanWithBlocking :: Bool -> InChan a -> a -> IO () {-# INLINE writeChanWithBlocking #-} writeChanWithBlocking canBlock (InChan _ savedEmptyTkt ce) a = mask_ $ do (segIx, nextSeg, updateStreamHeadIfNecessary) <- moveToNextCell asWriter ce let (seg, maybeCheckpt) = case nextSeg of NextByWriter (Stream s _) checkpt -> (s, Just checkpt) -- if installed by reader, no need to check in: NextByReader (Stream s _) -> (s, Nothing) (success,nonEmptyTkt) <- casArrayElem seg segIx savedEmptyTkt (Written a) if success -- NOTE: We must only block AFTER writing to be async exception-safe. then maybe updateStreamHeadIfNecessary -- NOTE [2] (\checkpt-> do segUnlocked <- if canBlock then True <$ writerCheckin checkpt else tryWriterCheckin checkpt when segUnlocked $ updateStreamHeadIfNecessary ) -- NOTE [1/2] maybeCheckpt -- If CAS failed then a reader beat us, so we know we're not out of -- bounds and don't need to writerCheckin else case peekTicket nonEmptyTkt of Blocking v -> do putMVar v a updateStreamHeadIfNecessary -- NOTE [1] Empty -> error "Stored Empty Ticket went stale!" Written _ -> error "Nearly Impossible! Expected Blocking" -- [1] At this point we know that 'seg' is unlocked for writers because a -- reader unblocked us, so it's safe to update the StreamHead with this -- segment (if we moved to a new segment). This way we maintain the invariant -- that the StreamHead segment is always known "unlocked" to writers. -- -- [2] Similarly when in tryWriteChan we only update the stream head when -- we see that it was installed by reader, or we see that it was unlocked, -- but for the latter we check without blocking. -- | Try to write a value to the channel, aborting if the write is likely to -- exceed the bounds, returning a @Bool@ indicating whether the write was -- successful. -- -- This function never blocks, but may occasionally write successfully to a -- queue that is already "full". Unlike 'writeChan' this function treats the -- requested bounds (raised to nearest power of two) strictly, rather than -- using the @n .. n*2@ range. The more concurrent writes and reads that are -- happening, the more inaccurate the estimate of the chan's size is likely to -- be. tryWriteChan :: InChan a -> a -> IO Bool {-# INLINE tryWriteChan #-} tryWriteChan c@(InChan _ _ (ChanEnd _ boundsMn1 _ _ _)) = \a-> do -- Similar caveats w/r/t counter overflow correctness as elsewhere apply -- here: where this would lap and give incorrect results we have already -- died with OOM: len <- estimatedLength c if len > boundsMn1 then return False else writeChanWithBlocking False c a >> return True -- | Return the estimated length of a bounded queue -- -- The more concurrent writes and reads that are happening, the more inaccurate -- the estimate of the chan's size is likely to be. estimatedLength :: InChan a -> IO Int {-# INLINE estimatedLength #-} estimatedLength (InChan readCounterReader _ (ChanEnd _ _ _ counter _)) = do ixR <- readCounterReader ixW <- readCounter counter return $ ixW - ixR -- The core of our 'read' operations, with exception handler: readSegIxUnmasked :: (IO a -> IO a) -> (StreamSegment a, Int) -> IO a {-# INLINE readSegIxUnmasked #-} readSegIxUnmasked h = \(seg,segIx)-> do cellTkt <- readArrayElem seg segIx case peekTicket cellTkt of Written a -> return a Empty -> do v <- newEmptyMVar (success,elseWrittenCell) <- casArrayElem seg segIx cellTkt (Blocking v) if success then readBlocking v else case peekTicket elseWrittenCell of -- In the meantime a writer has written. Good! Written a -> return a -- ...or a dupChan reader initiated blocking: Blocking v2 -> readBlocking v2 _ -> error "Impossible! Expecting Written or Blocking" Blocking v -> readBlocking v -- N.B. must use `readMVar` here to support `dupChan`: where readBlocking v = inline h $ readMVar v -- factored out for `tryReadChan` below: startReadChan :: OutChan a -> IO (StreamSegment a, Int) {-# INLINE startReadChan #-} startReadChan (OutChan ce@(ChanEnd _ _ segSource _ _)) = do (segIx, nextSeg, updateStreamHeadIfNecessary) <- moveToNextCell asReader ce let (seg,next) = case nextSeg of NextByReader (Stream s n) -> (s,n) _ -> error "moveToNextCell returned a non-reader-installed next segment to readSegIxUnmasked" -- try to pre-allocate next segment: when (segIx == 0) $ void $ waitingAdvanceStream asReader next segSource 0 updateStreamHeadIfNecessary return (seg,segIx) -- | Returns immediately with: -- -- - an @'UT.Element' a@ future, which returns one unique element when it -- becomes available via 'UT.tryRead'. -- -- - a blocking @IO@ action that returns the element when it becomes available. -- -- /Note/: This is a destructive operation. See 'UT.Element' for more details. -- -- /Note re. exceptions/: When an async exception is raised during a @tryReadChan@ -- the message that the read would have returned is likely to be lost, just as -- it would be when raised directly after this function returns. tryReadChan :: OutChan a -> IO (UT.Element a, IO a) {-# INLINE tryReadChan #-} tryReadChan oc = do -- no mask necessary (seg,segIx) <- startReadChan oc return ( UT.Element $ do cell <- P.readArray seg segIx case cell of Written a -> return $ Just a Empty -> return Nothing Blocking v -> tryReadMVar v , readSegIxUnmasked id (seg,segIx) ) -- | Read an element from the chan, blocking if the chan is empty. -- -- /Note re. exceptions/: When an async exception is raised during a @readChan@ -- the message that the read would have returned is likely to be lost, even when -- the read is known to be blocked on an empty queue. If you need to handle -- this scenario, you can use 'readChanOnException'. readChan :: OutChan a -> IO a {-# INLINE readChan #-} readChan = \oc-> startReadChan oc >>= readSegIxUnmasked id -- | Like 'readChan' but allows recovery of the queue element which would have -- been read, in the case that an async exception is raised during the read. To -- be precise exceptions are raised, and the handler run, only when -- @readChanOnException@ is blocking. -- -- The second argument is a handler that takes a blocking IO action returning -- the element, and performs some recovery action. When the handler is called, -- the passed @IO a@ is the only way to access the element. readChanOnException :: OutChan a -> (IO a -> IO ()) -> IO a {-# INLINE readChanOnException #-} readChanOnException oc h = mask_ ( startReadChan oc >>= readSegIxUnmasked (\io-> io `onException` (h io)) ) -- increments counter, finds stream segment of corresponding cell (updating the -- stream head pointer as needed), and returns the stream segment and relative -- index of our cell. moveToNextCell :: Bool -> ChanEnd a -> IO (Int, NextSegment a, IO ()) {-# INLINE moveToNextCell #-} moveToNextCell isReader (ChanEnd logBounds boundsMn1 segSource counter streamHead) = do (StreamHead offset0 str0) <- readIORef streamHead ix <- incrCounter 1 counter let !relIx = ix - offset0 !segsAway = relIx `unsafeShiftR` logBounds -- `div` bounds !segIx = relIx .&. boundsMn1 -- `mod` bounds ~nEW_SEGMENT_WAIT = (boundsMn1 `div` 12) + 25 go 0 nextSeg = return nextSeg go !n nextSeg = waitingAdvanceStream isReader (getNextRef nextSeg) segSource (nEW_SEGMENT_WAIT*segIx) -- NOTE [1] >>= go (n-1) nextSeg <- assert (relIx >= 0) $ -- go segsAway $ NextByReader str0 -- NOTE [2] -- NOTE: this is redundant, since `go` doesn't want to get -- inlined/unrolled if segsAway == 0 then return $ NextByReader str0 else go segsAway $ NextByReader str0 -- NOTE [2] -- writers and readers must perform this continuation at different points: let updateStreamHeadIfNecessary = when (segsAway > 0) $ do let !offsetN = --(segsAway * bounds) offset0 + (segsAway `unsafeShiftL` logBounds) writeIORef streamHead $ StreamHead offsetN $ getStr nextSeg return (segIx, nextSeg, updateStreamHeadIfNecessary) -- [1] All readers or writers needing to work with a not-yet-created segment -- race to create it, but those past index 0 have progressively long waits. -- The constant here is an approximation of the way we calculate it in -- Control.Concurrent.Chan.Unagi.Constants.nEW_SEGMENT_WAIT -- -- [2] We start the loop with 'NextByReader' effectively meaning that the head -- segment was installed by a reader, or really just indicating that the -- writer has no need to check-in for blocking. This is always the case for -- the head stream; see `writeChan` NOTE 1. -- TODO play with inlining and look at core; we'd like the conditionals to disappear -- INVARIANTS: -- - if isReader, after returning, the nextSegRef will be marked NextByReader -- - the 'nextSegRef' is only ever modified from Nothing -> Just (NextBy*) waitingAdvanceStream :: Bool -> IORef (Maybe (NextSegment a)) -> SegSource a -> Int -> IO (NextSegment a) waitingAdvanceStream isReader nextSegRef segSource = go where cas tk = casIORef nextSegRef tk . Just -- extract the installed Just NextSegment from the result of the cas peekInstalled (_, nextSegTk) = fromMaybe (error "Impossible! This should only have been a Just NextBy* segment") $ peekTicket nextSegTk readerUnblockAndReturn nextSeg = assert isReader $ case nextSeg of -- if a writer won, try to set as NextByReader so that every writer -- to this seg doesn't have to check in, and unblockWriters NextByWriter strAlreadyInstalled checkpt -> do unblockWriters checkpt -- idempotent let nextSeg' = NextByReader strAlreadyInstalled writeIORef nextSegRef $ Just nextSeg' return nextSeg' nextByReader -> return nextByReader go wait = assert (wait >= 0) $ do tk <- readForCAS nextSegRef case peekTicket tk of -- Rare, slow path: -- In readers: we outran reader 0 of the previous segment (or it was -- descheduled) who was tasked with setting this up. -- In writers: there are number writer threads > bounds, or reader 0 -- of previous segment was slow or descheduled. Nothing | wait > 0 -> go (wait - 1) -- Create a potential next segment and try to insert it: | otherwise -> do potentialStrNext <- Stream <$> segSource <*> newIORef Nothing if isReader then do -- This may fail because of either a competing reader or -- writer which certainly modified this to a Just value installed <- cas tk $ NextByReader potentialStrNext -- The segment we're reading from (or any *behind* the one -- we're reading from) is always unblocked for writers: readerUnblockAndReturn $ peekInstalled installed else do potentialCheckpt <- WriterCheckpoint <$> newEmptyMVar -- This may fail because of either a competing reader or -- writer which certainly modified this to a Just value peekInstalled <$> (cas tk $ NextByWriter potentialStrNext potentialCheckpt) -- Fast path: Another reader or writer has already advanced the -- stream. Most likely reader 0 of the last segment. Just nextSeg | isReader -> readerUnblockAndReturn nextSeg | otherwise -> return nextSeg type SegSource a = IO (StreamSegment a) newSegmentSource :: Int -> IO (SegSource a) newSegmentSource size = do -- NOTE: evaluate Empty seems to be required here in order to not raise -- "Stored Empty Ticket went stale!" exception when in GHCi. arr <- evaluate Empty >>= P.newArray size return (P.cloneMutableArray arr 0 size) -- This begins empty, but several readers will `put` without coordination, to -- ensure it's filled. Meanwhile writers are blocked on a `readMVar` (see -- writerCheckin) waiting to proceed. newtype WriterCheckpoint = WriterCheckpoint (MVar ()) -- idempotent unblockWriters :: WriterCheckpoint -> IO () unblockWriters (WriterCheckpoint v) = void $ tryPutMVar v () -- A writer knows that it doesn't need to call this when: -- - its segment is in the StreamHead, or... -- - its segment was reached by a NextByReader writerCheckin :: WriterCheckpoint -> IO () writerCheckin (WriterCheckpoint v) = do -- On GHC > 7.8 we have an atomic `readMVar`. On earlier GHC readMVar is -- take+put, creating a race condition; in this case we use take+tryPut -- ensuring the MVar stays full even if a reader's tryPut slips an () in: #if __GLASGOW_HASKELL__ < 708 takeMVar v >>= void . tryPutMVar v #else void $ readMVar v #endif -- returns immediately indicating whether the checkpt is currently unblocked. tryWriterCheckin :: WriterCheckpoint -> IO Bool tryWriterCheckin (WriterCheckpoint v) = -- On GHC > 7.8 we have an atomic `tryReadMVar`. On earlier GHC readMVar is -- take+put, creating a race condition; in this case we use take+tryPut -- ensuring the MVar stays full even if a reader's tryPut slips an () in. -- HOWEVER, tryReadMVar is also buggy in GHC < 7.8.3 -- https://ghc.haskell.org/trac/ghc/ticket/9148 #ifdef TRYREADMVAR isJust <$> tryReadMVar v #else tryTakeMVar v >>= maybe (return False) ((True <$) . tryPutMVar v) #endif