-- |This module can execute events at specified time. It uses a two thread
-- system that allows the STM adding and deleting of new threads without
-- requiring later IO actions. An ability to place arbitrary event preprocessing
-- when adding each event exists, but in a course grained manner. This
-- feature can be expanded on request.
--
-- This is very like control-timeout, but was developed separately internal
-- operation is similar with a thread sleeping via threadDelay and EventIds
-- being based in part on expire time. It differs in that control-event is:
-- * More complex
-- * Requires initilization
-- * Allows pure STM adding and removing of events (no post STM IO action)
-- * Allows user control over event systems (can have more than one)
-- * Allows events to run in event handler thread
-- (advisable if thread spark is too expensive / computation is cheap)
-- * No possible duplication of EventId (theoretical! no real advantage)
--
-- On the other hand, a shim could be made to provide the
-- control-timeout API with Control.Event running under the hood.
module Control.Event (
EventId
,EventSystem
,noEvent
,initEventSystem
,addEvent
,addEventSTM
,cancelEvent
,cancelEventSTM
,evtSystemSize
) where
import Prelude hiding (lookup)
import Control.Concurrent (forkIO, myThreadId, ThreadId, threadDelay)
import Control.Concurrent.STM
import Control.Exception (throwDynTo, catchDyn, block, unblock)
import Control.Monad (forever)
import Data.Dynamic
import Data.List (partition, deleteBy)
import Data.Map (Map, empty, findMin, deleteFindMin, insertLookupWithKey, adjust, size, singleton, toList, insert, updateLookupWithKey, delete, lookup, fold)
import System.Time (TimeDiff(..), ClockTime(..), diffClockTimes, getClockTime)
import GHC.Conc
type EventNumber = Int
type EventSet = (EventNumber, Map EventNumber (IO ()))
singletonSet :: (IO ()) -> EventSet
singletonSet a = (1, singleton 0 a)
-- |IDs the program can use to cancel previously scheduled events.
data EventId = EvtId ClockTime EventNumber deriving (Eq, Ord, Show)
-- |A value indicating there is no such event.
noEvent = EvtId (TOD (-1) (-1)) (-1)
-- |The event system can either be initilized and passed as state or a global
-- system can be declared using gEvtSys = unsafePeformIO initEventSystem
data EventSystem = EvtSys {
esEvents :: TVar (Map ClockTime EventSet), -- Pending Events
esThread :: TVar (Maybe ThreadId), -- Id of thread for TimerReset exceptions
esAlarm :: TVar ClockTime, -- Time of soonest event
esNewAlarm :: TVar Bool, -- An event w/ earlier expiration was added
esExpired :: TVar [[EventSet]]
}
-- |The only way to get an event system is to initilize one, which sets internal TVars
-- and sparks two threads (one to expire events, one to look if you've added an
-- event expiring before the current alarm).
initEventSystem :: IO EventSystem
initEventSystem = do
evts <- newTVarIO empty
tid <- newTVarIO Nothing
alm <- newTVarIO (TOD (-1) (-1))
new <- newTVarIO False
exp <- newTVarIO []
let evtSys = EvtSys evts tid alm new exp
forkIO $ forever $ trackAlarm evtSys
forkIO $ forever $ monitorExpiredQueue exp
forkIO $ expireEvents evtSys
return evtSys
-- |Main thread that delays till the alarm time then executes any expired events.
-- Asynchronous 'TimerReset' exceptions might occur to indicate a new, earlier, alarm time.
expireEvents :: EventSystem -> IO ()
expireEvents es = do
block (do
tid <- myThreadId
forever $ catchDyn (unblock (setTID (Just tid) es >> expireEvents' es))
(\TimerReset -> return ()) )
where
setTID i es = atomically (writeTVar (esThread es) i)
-- |Worker function for expireEvents - the parent simply catches the exceptions
expireEvents' :: EventSystem -> IO ()
expireEvents' evtSys = do
usDelay <- determineDelay
threadDelay usDelay
runExpire evtSys
where
determineDelay :: IO Int
determineDelay = do
alm <- atomically (do
evts <- readTVar (esEvents evtSys)
case findMinM evts of
Nothing -> retry
Just (c,_) -> return c )
now <- getClockTime
return $ timeDiffToMicroSec $ diffClockTimes alm now
findMinM :: Map ClockTime EventSet -> Maybe (ClockTime,EventSet)
findMinM m | size m == 0 = Nothing
| otherwise = Just $ findMin m
-- |Determines which events are expired, running all their actions
runExpire :: EventSystem -> IO ()
runExpire evtSys = do
now <- getClockTime
atomically (do evts <- readTVar (esEvents evtSys)
let (exp, newMap) = getEarlierKeys now evts
newAlarm = getAlarm newMap
writeTVar (esAlarm evtSys) newAlarm
writeTVar (esEvents evtSys) newMap
if (fold (\(_,m) n -> size m + n) 0 newMap) + sum (map (\(_,m) -> size m) exp) /= (fold (\(_,m) n -> size m + n) 0 evts)
then unsafeIOToSTM $ putStrLn "Expire is dropping events."
else return ()
exps <- readTVar (esExpired evtSys)
writeTVar (esExpired evtSys) (exp:exps) )
where
getEarlierKeys :: ClockTime -> Map ClockTime EventSet -> ([EventSet], Map ClockTime EventSet)
getEarlierKeys clk m =
case deleteFindMinM m of
Just ((k,es), m') ->
if k < clk
then let (exp, lastMap) = getEarlierKeys clk m'
in (es:exp, lastMap)
else ([], m)
Nothing -> ([], m)
getAlarm m | size m == 0 = TOD (-1) (-1)
| otherwise = fst $ findMin m
deleteFindMinM :: Map k a -> Maybe ((k, a), Map k a)
deleteFindMinM m = if size m == 0 then Nothing else Just (deleteFindMin m)
-- |Execute expired events
monitorExpiredQueue :: TVar [[EventSet]] -> IO ()
monitorExpiredQueue exp = do
exp <- atomically (do
e <- readTVar exp
case e of
(a:as) -> writeTVar exp [] >> return e
_ -> retry )
mapM_ (mapM_ runEvents) exp
-- |Runs all provided events (which must have expired)
runEvents :: EventSet -> IO ()
runEvents (_,set) = do
let actions = map snd (toList set)
-- mapM_ forkIO actions
sequence_ actions -- FIXME why does this line work and not the top!
-- |Add an *action* to be performed at *time* by *system*, returning a unique id.
addEvent :: EventSystem -> ClockTime -> IO () -> IO EventId
addEvent sys clk act = atomically (addEventSTM sys clk act)
-- |Atomically add an action to be performed at specified time and returning a unique id.
addEventSTM :: EventSystem -> ClockTime -> IO () -> STM EventId
addEventSTM sys clk act = do
evts <- readTVar (esEvents sys)
let (old, newMap) = insertLookupWithKey (\_ _ o -> insertEvent o) clk (singletonSet act) evts
num = case old of
Nothing -> 0
Just (n,_) -> n
eid = EvtId clk num
writeTVar (esEvents sys) newMap
alm <- readTVar (esAlarm sys)
if clk < alm || alm == (TOD (-1) (-1))
then writeTVar (esAlarm sys) clk >> writeTVar (esNewAlarm sys) True
else return ()
if fold (\(_,m) n -> n + size m) 0 newMap /= fold (\(_,m) n -> n + size m) 1 evts
then unsafeIOToSTM $ putStrLn "Event mapping has not grown!"
else return ()
return eid
where
insertEvent :: EventSet -> EventSet
insertEvent (num,set) | num == maxBound = error "maxBound events at given time, something is broken."
| otherwise =
(num+1, insert num act set)
-- |Cancel an event from the system, returning True on success.
cancelEvent :: EventSystem -> EventId -> IO Bool
cancelEvent sys eid = atomically (cancelEventSTM sys eid)
-- |Atomically cancel an event from the system, returning True on success.
cancelEventSTM :: EventSystem -> EventId -> STM Bool
cancelEventSTM sys eid@(EvtId clk num) = do
evts <- readTVar (esEvents sys)
let newMap :: Map ClockTime EventSet
prev :: Maybe EventSet
(prev,newMap) = updateLookupWithKey (\_ (num, old) -> Just (num,delete num old)) clk evts
ret = case prev of
Nothing -> False -- error "Canceling an event that never existed."
Just (_,p) -> case lookup clk newMap of
Nothing -> False
Just (_,m) -> (size p /= size m)
writeTVar (esEvents sys) newMap
return ret
evtSystemSize :: EventSystem -> STM Int
evtSystemSize sys = do
evts <- readTVar (esEvents sys)
return $ fold (\(_,m) n -> n + size m) 0 evts
-- |Tracks the alarm time and the earliest event. If an earlier event is added
-- the alarm time is updated and TimerReset is thrown to the expireEvent thread
trackAlarm :: EventSystem -> IO ()
trackAlarm sys = do
tid <- atomically (do
newAlm <- readTVar (esNewAlarm sys)
if newAlm then writeTVar (esNewAlarm sys) False else retry
tid <- readTVar (esThread sys)
i <- case tid of
Just i -> return i
Nothing -> retry
return i )
throwDynTo tid TimerReset
-- |Returns the time difference in microseconds (potentially returning maxBound <= the real difference)
timeDiffToMicroSec :: TimeDiff -> Int
timeDiffToMicroSec (TimeDiff _ _ _ _ _ sec picosec) =
if realTime > fromIntegral (maxBound :: Int)
then maxBound
else fromIntegral realTime
where
realTime :: Integer
realTime = (fromIntegral sec) * (10^6) + fromIntegral (picosec `div` (10^6))
data TimerReset = TimerReset deriving (Eq, Ord, Show, Typeable)