-- | -- Module : Simulation.Aivika.Activity -- Copyright : Copyright (c) 2009-2014, David Sorokin -- License : BSD3 -- Maintainer : David Sorokin -- Stability : experimental -- Tested with: GHC 7.8.3 -- -- It models an activity that can be utilised. The activity is similar to a 'Server' -- but destined for simulation within 'Net' computation. module Simulation.Aivika.Activity (-- * Activity Activity, ActivityInterruption(..), newActivity, newStateActivity, newInterruptibleActivity, newInterruptibleStateActivity, -- * Processing activityNet, -- * Activity Properties activityInitState, activityState, activityTotalUtilisationTime, activityTotalIdleTime, activityUtilisationTime, activityIdleTime, activityUtilisationFactor, activityIdleFactor, -- * Summary activitySummary, -- * Derived Signals for Properties activityStateChanged, activityStateChanged_, activityTotalUtilisationTimeChanged, activityTotalUtilisationTimeChanged_, activityTotalIdleTimeChanged, activityTotalIdleTimeChanged_, activityUtilisationTimeChanged, activityUtilisationTimeChanged_, activityIdleTimeChanged, activityIdleTimeChanged_, activityUtilisationFactorChanged, activityUtilisationFactorChanged_, activityIdleFactorChanged, activityIdleFactorChanged_, -- * Basic Signals activityUtilising, activityUtilised, activityInterrupted, -- * Overall Signal activityChanged_) where import Data.IORef import Data.Monoid import Control.Monad import Control.Monad.Trans import Control.Arrow import Simulation.Aivika.Simulation import Simulation.Aivika.Dynamics import Simulation.Aivika.Internal.Event import Simulation.Aivika.Internal.Signal import Simulation.Aivika.Resource import Simulation.Aivika.Cont import Simulation.Aivika.Process import Simulation.Aivika.Net import Simulation.Aivika.Server import Simulation.Aivika.Statistics -- | Like 'Server' it models an activity that takes @a@ and provides @b@ having state @s@. -- But unlike the former the activity is destined for simulation within 'Net' computation. data Activity s a b = Activity { activityInitState :: s, -- ^ The initial state of the activity. activityStateRef :: IORef s, -- ^ The current state of the activity. activityProcess :: s -> a -> Process (s, b), -- ^ Provide @b@ by specified @a@. activityProcessInterruptible :: Bool, -- ^ Whether the process is interruptible. activityTotalUtilisationTimeRef :: IORef Double, -- ^ The counted total time of utilising the activity. activityTotalIdleTimeRef :: IORef Double, -- ^ The counted total time, when the activity was idle. activityUtilisationTimeRef :: IORef (SamplingStats Double), -- ^ The statistics for the utilisation time. activityIdleTimeRef :: IORef (SamplingStats Double), -- ^ The statistics for the time, when the activity was idle. activityUtilisingSource :: SignalSource a, -- ^ A signal raised when starting to utilise the activity. activityUtilisedSource :: SignalSource (a, b), -- ^ A signal raised when the activity has been utilised. activityInterruptedSource :: SignalSource (ActivityInterruption a) -- ^ A signal raised when the utilisation was interrupted. } -- | Contains data about the interrupted task. data ActivityInterruption a = ActivityInterruption { activityInterruptedInput :: a, -- ^ The input task that was interrupted. activityStartProcessingTime :: Double, -- ^ The start time of processing the task. activityInterruptionTime :: Double -- ^ The time of interrupting the task. } -- | Create a new activity that can provide output @b@ by input @a@. -- -- By default, it is assumed that the activity utilisation cannot be interrupted, -- because the handling of possible task interruption is rather costly -- operation. newActivity :: (a -> Process b) -- ^ provide an output by the specified input -> Simulation (Activity () a b) newActivity = newInterruptibleActivity False -- | Create a new activity that can provide output @b@ by input @a@ -- starting from state @s@. -- -- By default, it is assumed that the activity utilisation cannot be interrupted, -- because the handling of possible task interruption is rather costly -- operation. newStateActivity :: (s -> a -> Process (s, b)) -- ^ provide a new state and output by the specified -- old state and input -> s -- ^ the initial state -> Simulation (Activity s a b) newStateActivity = newInterruptibleStateActivity False -- | Create a new interruptible activity that can provide output @b@ by input @a@. newInterruptibleActivity :: Bool -- ^ whether the activity can be interrupted -> (a -> Process b) -- ^ provide an output by the specified input -> Simulation (Activity () a b) newInterruptibleActivity interruptible provide = flip (newInterruptibleStateActivity interruptible) () $ \s a -> do b <- provide a return (s, b) -- | Create a new activity that can provide output @b@ by input @a@ -- starting from state @s@. newInterruptibleStateActivity :: Bool -- ^ whether the activity can be interrupted -> (s -> a -> Process (s, b)) -- ^ provide a new state and output by the specified -- old state and input -> s -- ^ the initial state -> Simulation (Activity s a b) newInterruptibleStateActivity interruptible provide state = do r0 <- liftIO $ newIORef state r1 <- liftIO $ newIORef 0 r2 <- liftIO $ newIORef 0 r3 <- liftIO $ newIORef emptySamplingStats r4 <- liftIO $ newIORef emptySamplingStats s1 <- newSignalSource s2 <- newSignalSource s3 <- newSignalSource return Activity { activityInitState = state, activityStateRef = r0, activityProcess = provide, activityProcessInterruptible = interruptible, activityTotalUtilisationTimeRef = r1, activityTotalIdleTimeRef = r2, activityUtilisationTimeRef = r3, activityIdleTimeRef = r4, activityUtilisingSource = s1, activityUtilisedSource = s2, activityInterruptedSource = s3 } -- | Return a network computation for the specified activity. -- -- The computation updates the internal state of the activity. The usual case is when -- the computation is applied only once in a chain of data processing. Otherwise; -- every time the computation is used, the state of the activity changes. Sometimes -- it can be indeed useful if you want to aggregate the statistics for different -- activities simultaneously, but it would be more preferable to avoid this. -- -- If you connect different activity computations returned by this function in a chain -- with help of '>>>' or other category combinator then this chain will act as one -- whole, where the first activity will take a new task only after the last activity -- finishes its current task and requests for the next one from the previous activity -- in the chain. This is not always that thing you might need. activityNet :: Activity s a b -> Net a b activityNet act = Net $ loop (activityInitState act) Nothing where loop s r a = do t0 <- liftDynamics time liftEvent $ do case r of Nothing -> return () Just t' -> liftIO $ do modifyIORef' (activityTotalIdleTimeRef act) (+ (t0 - t')) modifyIORef' (activityIdleTimeRef act) $ addSamplingStats (t0 - t') triggerSignal (activityUtilisingSource act) a -- utilise the activity (s', b) <- activityProcess act s a (s', b) <- if activityProcessInterruptible act then activityProcessInterrupting act s a else activityProcess act s a t1 <- liftDynamics time liftEvent $ do liftIO $ do writeIORef (activityStateRef act) $! s' modifyIORef' (activityTotalUtilisationTimeRef act) (+ (t1 - t0)) modifyIORef' (activityUtilisationTimeRef act) $ addSamplingStats (t1 - t0) triggerSignal (activityUtilisedSource act) (a, b) return (b, Net $ loop s' (Just t1)) -- | Process the input with ability to handle a possible interruption. activityProcessInterrupting :: Activity s a b -> s -> a -> Process (s, b) activityProcessInterrupting act s a = do pid <- processId t0 <- liftDynamics time finallyProcess (activityProcess act s a) (liftEvent $ do cancelled <- processCancelled pid when cancelled $ do t1 <- liftDynamics time liftIO $ do modifyIORef' (activityTotalUtilisationTimeRef act) (+ (t1 - t0)) modifyIORef' (activityUtilisationTimeRef act) $ addSamplingStats (t1 - t0) let x = ActivityInterruption a t0 t1 triggerSignal (activityInterruptedSource act) x) -- | Return the current state of the activity. -- -- See also 'activityStateChanged' and 'activityStateChanged_'. activityState :: Activity s a b -> Event s activityState act = Event $ \p -> readIORef (activityStateRef act) -- | Signal when the 'activityState' property value has changed. activityStateChanged :: Activity s a b -> Signal s activityStateChanged act = mapSignalM (const $ activityState act) (activityStateChanged_ act) -- | Signal when the 'activityState' property value has changed. activityStateChanged_ :: Activity s a b -> Signal () activityStateChanged_ act = mapSignal (const ()) (activityUtilised act) -- | Return the counted total time when the activity was utilised. -- -- The value returned changes discretely and it is usually delayed relative -- to the current simulation time. -- -- See also 'activityTotalUtilisationTimeChanged' and 'activityTotalUtilisationTimeChanged_'. activityTotalUtilisationTime :: Activity s a b -> Event Double activityTotalUtilisationTime act = Event $ \p -> readIORef (activityTotalUtilisationTimeRef act) -- | Signal when the 'activityTotalUtilisationTime' property value has changed. activityTotalUtilisationTimeChanged :: Activity s a b -> Signal Double activityTotalUtilisationTimeChanged act = mapSignalM (const $ activityTotalUtilisationTime act) (activityTotalUtilisationTimeChanged_ act) -- | Signal when the 'activityTotalUtilisationTime' property value has changed. activityTotalUtilisationTimeChanged_ :: Activity s a b -> Signal () activityTotalUtilisationTimeChanged_ act = mapSignal (const ()) (activityUtilised act) -- | Return the counted total time when the activity was idle. -- -- The value returned changes discretely and it is usually delayed relative -- to the current simulation time. -- -- See also 'activityTotalIdleTimeChanged' and 'activityTotalIdleTimeChanged_'. activityTotalIdleTime :: Activity s a b -> Event Double activityTotalIdleTime act = Event $ \p -> readIORef (activityTotalIdleTimeRef act) -- | Signal when the 'activityTotalIdleTime' property value has changed. activityTotalIdleTimeChanged :: Activity s a b -> Signal Double activityTotalIdleTimeChanged act = mapSignalM (const $ activityTotalIdleTime act) (activityTotalIdleTimeChanged_ act) -- | Signal when the 'activityTotalIdleTime' property value has changed. activityTotalIdleTimeChanged_ :: Activity s a b -> Signal () activityTotalIdleTimeChanged_ act = mapSignal (const ()) (activityUtilising act) -- | Return the statistics for the time when the activity was utilised. -- -- The value returned changes discretely and it is usually delayed relative -- to the current simulation time. -- -- See also 'activityUtilisationTimeChanged' and 'activityUtilisationTimeChanged_'. activityUtilisationTime :: Activity s a b -> Event (SamplingStats Double) activityUtilisationTime act = Event $ \p -> readIORef (activityUtilisationTimeRef act) -- | Signal when the 'activityUtilisationTime' property value has changed. activityUtilisationTimeChanged :: Activity s a b -> Signal (SamplingStats Double) activityUtilisationTimeChanged act = mapSignalM (const $ activityUtilisationTime act) (activityUtilisationTimeChanged_ act) -- | Signal when the 'activityUtilisationTime' property value has changed. activityUtilisationTimeChanged_ :: Activity s a b -> Signal () activityUtilisationTimeChanged_ act = mapSignal (const ()) (activityUtilised act) -- | Return the statistics for the time when the activity was idle. -- -- The value returned changes discretely and it is usually delayed relative -- to the current simulation time. -- -- See also 'activityIdleTimeChanged' and 'activityIdleTimeChanged_'. activityIdleTime :: Activity s a b -> Event (SamplingStats Double) activityIdleTime act = Event $ \p -> readIORef (activityIdleTimeRef act) -- | Signal when the 'activityIdleTime' property value has changed. activityIdleTimeChanged :: Activity s a b -> Signal (SamplingStats Double) activityIdleTimeChanged act = mapSignalM (const $ activityIdleTime act) (activityIdleTimeChanged_ act) -- | Signal when the 'activityIdleTime' property value has changed. activityIdleTimeChanged_ :: Activity s a b -> Signal () activityIdleTimeChanged_ act = mapSignal (const ()) (activityUtilising act) -- | It returns the factor changing from 0 to 1, which estimates how often -- the activity was utilised. -- -- This factor is calculated as -- -- @ -- totalUtilisationTime \/ (totalUtilisationTime + totalIdleTime) -- @ -- -- As before in this module, the value returned changes discretely and -- it is usually delayed relative to the current simulation time. -- -- See also 'activityUtilisationFactorChanged' and 'activityUtilisationFactorChanged_'. activityUtilisationFactor :: Activity s a b -> Event Double activityUtilisationFactor act = Event $ \p -> do x1 <- readIORef (activityTotalUtilisationTimeRef act) x2 <- readIORef (activityTotalIdleTimeRef act) return (x1 / (x1 + x2)) -- | Signal when the 'activityUtilisationFactor' property value has changed. activityUtilisationFactorChanged :: Activity s a b -> Signal Double activityUtilisationFactorChanged act = mapSignalM (const $ activityUtilisationFactor act) (activityUtilisationFactorChanged_ act) -- | Signal when the 'activityUtilisationFactor' property value has changed. activityUtilisationFactorChanged_ :: Activity s a b -> Signal () activityUtilisationFactorChanged_ act = mapSignal (const ()) (activityUtilising act) <> mapSignal (const ()) (activityUtilised act) -- | It returns the factor changing from 0 to 1, which estimates how often -- the activity was idle. -- -- This factor is calculated as -- -- @ -- totalIdleTime \/ (totalUtilisationTime + totalIdleTime) -- @ -- -- As before in this module, the value returned changes discretely and -- it is usually delayed relative to the current simulation time. -- -- See also 'activityIdleFactorChanged' and 'activityIdleFactorChanged_'. activityIdleFactor :: Activity s a b -> Event Double activityIdleFactor act = Event $ \p -> do x1 <- readIORef (activityTotalUtilisationTimeRef act) x2 <- readIORef (activityTotalIdleTimeRef act) return (x2 / (x1 + x2)) -- | Signal when the 'activityIdleFactor' property value has changed. activityIdleFactorChanged :: Activity s a b -> Signal Double activityIdleFactorChanged act = mapSignalM (const $ activityIdleFactor act) (activityIdleFactorChanged_ act) -- | Signal when the 'activityIdleFactor' property value has changed. activityIdleFactorChanged_ :: Activity s a b -> Signal () activityIdleFactorChanged_ act = mapSignal (const ()) (activityUtilising act) <> mapSignal (const ()) (activityUtilised act) -- | Raised when starting to utilise the activity after a new input task is received. activityUtilising :: Activity s a b -> Signal a activityUtilising = publishSignal . activityUtilisingSource -- | Raised when the activity has been utilised after the current task is processed. activityUtilised :: Activity s a b -> Signal (a, b) activityUtilised = publishSignal . activityUtilisedSource -- | Raised when the task utilisation by the activity was interrupted. activityInterrupted :: Activity s a b -> Signal (ActivityInterruption a) activityInterrupted = publishSignal . activityInterruptedSource -- | Signal whenever any property of the activity changes. activityChanged_ :: Activity s a b -> Signal () activityChanged_ act = mapSignal (const ()) (activityUtilising act) <> mapSignal (const ()) (activityUtilised act) <> mapSignal (const ()) (activityInterrupted act) -- | Return the summary for the activity with desciption of its -- properties using the specified indent. activitySummary :: Activity s a b -> Int -> Event ShowS activitySummary act indent = Event $ \p -> do tx1 <- readIORef (activityTotalUtilisationTimeRef act) tx2 <- readIORef (activityTotalIdleTimeRef act) let xf1 = tx1 / (tx1 + tx2) xf2 = tx2 / (tx1 + tx2) xs1 <- readIORef (activityUtilisationTimeRef act) xs2 <- readIORef (activityIdleTimeRef act) let tab = replicate indent ' ' return $ showString tab . showString "total utilisation time = " . shows tx1 . showString "\n" . showString tab . showString "total idle time = " . shows tx2 . showString "\n" . showString tab . showString "utilisation factor (from 0 to 1) = " . shows xf1 . showString "\n" . showString tab . showString "idle factor (from 0 to 1) = " . shows xf2 . showString "\n" . showString tab . showString "utilisation time (locked while awaiting the input):\n\n" . samplingStatsSummary xs1 (2 + indent) . showString "\n\n" . showString tab . showString "idle time:\n\n" . samplingStatsSummary xs2 (2 + indent)