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403 lines
13 KiB
ReStructuredText
403 lines
13 KiB
ReStructuredText
Adding a New Primitive
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======================
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Déjà Fu is fairly well written (or so I like to tell myself), so
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adding a new primitive doesn't have to be a great undertaking. Let's
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add this function:
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.. code-block:: haskell
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-- | Atomically set the value of an @MVar@.
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setMVar :: MonadConc m => MVar m a -> Maybe a -> m ()
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Before we get started, take a moment to look at the existing ``MVar``
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functions and convince yourself that this really is a new primitive.
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Specifically, if the ``MVar`` already contains a value, there's no way
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to atomically clear it and put the new value in. The best we can do
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is something like this:
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.. code-block:: haskell
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setMVar :: MonadConc m => MVar m a -> Maybe a -> m ()
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setMVar mvar (Just a) = go where
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go = do
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tryTakeMVar mvar
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flag <- tryPutMVar mvar a
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unless flag go
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setMVar mvar Nothing = void (tryTakeMVar mvar)
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We can't actually implement this for ``IO``, but as the point of this
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exercise is to learn the internals of the dejafu library, this is
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fine.
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Normally it's a bad idea to add primitives which only work when
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testing, as they can't be used in ``IO`` code.
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Trace elements
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--------------
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Every primitive has a corresponding constructor in the
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``ThreadAction`` and ``Lookahead`` types, which appear in execution
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traces.
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These types live in ``Test.DejaFu.Common``:
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.. code-block:: haskell
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data ThreadAction =
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Fork ThreadId
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-- ^ Start a new thread.
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| MyThreadId
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-- ^ Get the 'ThreadId' of the current thread.
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| GetNumCapabilities Int
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-- ^ Get the number of Haskell threads that can run simultaneously.
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| SetNumCapabilities Int
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-- ^ Set the number of Haskell threads that can run simultaneously.
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| Yield
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-- ^ Yield the current thread.
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| NewMVar MVarId
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-- ^ Create a new 'MVar'.
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| PutMVar MVarId [ThreadId]
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-- ^ Put into a 'MVar', possibly waking up some threads.
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| BlockedPutMVar MVarId
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-- ^ Get blocked on a put.
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| TryPutMVar MVarId Bool [ThreadId]
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-- ^ Try to put into a 'MVar', possibly waking up some threads.
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| ReadMVar MVarId
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-- ^ Read from a 'MVar'.
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| TryReadMVar MVarId Bool
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-- ^ Try to read from a 'MVar'.
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| BlockedReadMVar MVarId
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-- ^ Get blocked on a read.
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| TakeMVar MVarId [ThreadId]
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-- ^ Take from a 'MVar', possibly waking up some threads.
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| BlockedTakeMVar MVarId
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-- ^ Get blocked on a take.
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| TryTakeMVar MVarId Bool [ThreadId]
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-- ^ Try to take from a 'MVar', possibly waking up some threads.
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| NewCRef CRefId
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-- ^ Create a new 'CRef'.
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| ReadCRef CRefId
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-- ^ Read from a 'CRef'.
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| ReadCRefCas CRefId
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-- ^ Read from a 'CRef' for a future compare-and-swap.
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| ModCRef CRefId
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-- ^ Modify a 'CRef'.
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| ModCRefCas CRefId
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-- ^ Modify a 'CRef' using a compare-and-swap.
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| WriteCRef CRefId
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-- ^ Write to a 'CRef' without synchronising.
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| CasCRef CRefId Bool
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-- ^ Attempt to to a 'CRef' using a compare-and-swap, synchronising
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-- it.
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| CommitCRef ThreadId CRefId
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-- ^ Commit the last write to the given 'CRef' by the given thread,
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-- so that all threads can see the updated value.
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| STM TTrace [ThreadId]
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-- ^ An STM transaction was executed, possibly waking up some
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-- threads.
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| BlockedSTM TTrace
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-- ^ Got blocked in an STM transaction.
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| Catching
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-- ^ Register a new exception handler
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| PopCatching
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-- ^ Pop the innermost exception handler from the stack.
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| Throw
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-- ^ Throw an exception.
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| ThrowTo ThreadId
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-- ^ Throw an exception to a thread.
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| BlockedThrowTo ThreadId
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-- ^ Get blocked on a 'throwTo'.
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| Killed
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-- ^ Killed by an uncaught exception.
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| SetMasking Bool MaskingState
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-- ^ Set the masking state. If 'True', this is being used to set the
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-- masking state to the original state in the argument passed to a
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-- 'mask'ed function.
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| ResetMasking Bool MaskingState
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-- ^ Return to an earlier masking state. If 'True', this is being
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-- used to return to the state of the masked block in the argument
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-- passed to a 'mask'ed function.
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| LiftIO
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-- ^ Lift an IO action. Note that this can only happen with
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-- 'ConcIO'.
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| Return
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-- ^ A 'return' or 'pure' action was executed.
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| Stop
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-- ^ Cease execution and terminate.
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| Subconcurrency
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-- ^ Start executing an action with @subconcurrency@.
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| StopSubconcurrency
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-- ^ Stop executing an action with @subconcurrency@.
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deriving (Eq, Show)
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We can look at the other ``MVar`` actions to get some idea of what to
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include. How about this?
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.. code-block:: haskell
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| SetMVar MVarId [ThreadId]
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-- ^ Set the value of an 'MVar', possibly waking up some threads.
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We also need a ``Lookahead`` equivalent:
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.. code-block:: haskell
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| WillSetMVar MVarId
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-- ^ Will set the value of a 'MVar', possibly waking up some threads.
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Both ``ThreadAction`` and ``Lookahead`` have ``NFData`` instances,
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don't forget to add the extra cases in those.
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The ``rewind`` function converts between ``ThreadAction`` and
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``Lookahead`` values, so we need to add a case to that as well:
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.. code-block:: haskell
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rewind (SetMVar c _) = Just (WillSetMVar c)
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Finally, we need to make sure the systematic testing will treat our
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new primitive correctly. As setting the value of an ``MVar`` may
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cause previously blocked threads to become runnable, it is a *release*
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action. Furthermore, as it writes to an ``MVar`` it is a
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*synchronised write*:
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.. code-block:: haskell
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willRelease (WillSetMVar _) = True
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...
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simplifyLookahead (WillSetMVar c) = SynchronisedWrite c
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**Summary**:
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* Add a new ``ThreadAction`` constructor, and update the ``NFData``
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instance
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* Add a new ``Lookahead`` constructor, and update the ``NFData``
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instance
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* Add a new case to ``rewind``, connecting the two new values
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* If the action can enable threads, add a case to ``willRelease``
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* if the action enforces a (partial) memory barrier, add a case to
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``simplifyLookahead``
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Actions
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-------
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Now jump to the ``Test.DejaFu.Conc.Internal.Common`` module (yes,
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another "common"). The ``Action`` type defines the actual primitive
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actions which are used to implement all the concurrency primitives.
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An ``Action`` value contains the information needed to perform that
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action and a continuation to call when it is done:
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.. code-block:: haskell
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data Action n r =
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AFork String ((forall b. M n r b -> M n r b) -> Action n r) (ThreadId -> Action n r)
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| AMyTId (ThreadId -> Action n r)
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| AGetNumCapabilities (Int -> Action n r)
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| ASetNumCapabilities Int (Action n r)
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| forall a. ANewMVar String (MVar r a -> Action n r)
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| forall a. APutMVar (MVar r a) a (Action n r)
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| forall a. ATryPutMVar (MVar r a) a (Bool -> Action n r)
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| forall a. AReadMVar (MVar r a) (a -> Action n r)
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| forall a. ATryReadMVar (MVar r a) (Maybe a -> Action n r)
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| forall a. ATakeMVar (MVar r a) (a -> Action n r)
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| forall a. ATryTakeMVar (MVar r a) (Maybe a -> Action n r)
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| forall a. ANewCRef String a (CRef r a -> Action n r)
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| forall a. AReadCRef (CRef r a) (a -> Action n r)
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| forall a. AReadCRefCas (CRef r a) (Ticket a -> Action n r)
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| forall a b. AModCRef (CRef r a) (a -> (a, b)) (b -> Action n r)
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| forall a b. AModCRefCas (CRef r a) (a -> (a, b)) (b -> Action n r)
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| forall a. AWriteCRef (CRef r a) a (Action n r)
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| forall a. ACasCRef (CRef r a) (Ticket a) a ((Bool, Ticket a) -> Action n r)
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| forall e. Exception e => AThrow e
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| forall e. Exception e => AThrowTo ThreadId e (Action n r)
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| forall a e. Exception e => ACatching (e -> M n r a) (M n r a) (a -> Action n r)
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| APopCatching (Action n r)
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| forall a. AMasking MaskingState ((forall b. M n r b -> M n r b) -> M n r a) (a -> Action n r)
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| AResetMask Bool Bool MaskingState (Action n r)
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| forall a. AAtom (STMLike n r a) (a -> Action n r)
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| ALift (n (Action n r))
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| AYield (Action n r)
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| AReturn (Action n r)
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| ACommit ThreadId CRefId
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| AStop (n ())
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| forall a. ASub (M n r a) (Either Failure a -> Action n r)
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| AStopSub (Action n r)
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Again we can look at the existing ``MVar`` actions for inspiration.
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The ``setMVar`` function will need an action very much like
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``APutMVar``, but which takes a ``Maybe`` value instead:
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.. code-block:: haskell
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| forall a. ASetMVar (MVar r a) (Maybe a) (Action n r)
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The only other thing we need to change in this file is the
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``lookahead`` function, which converts between ``Action`` and
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``Lookahead`` values:
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.. code-block:: haskell
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lookahead' (ASetMVar (MVar c _) _ k) = WillSetMVar c : lookahead' k
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**Summary**:
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* Add a new ``Action`` constructor
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* Add a new case to ``lookahead``, connecting the ``Action`` to its
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``Lookahead``
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Implementation
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--------------
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Now we have all that we need to implement the behaviour of the action.
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Check out the huge ``stepThread`` function in
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``Test.DejaFu.Conc.Internal``. It has one case for every ``Action``
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so, you guessed it, we're going to add another case which is similar
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to the one for ``APutMVar``.
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Here's the solution:
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.. code-block:: haskell
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-- atomically set the value of an @MVar@.
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ASetMVar cvar@(MVar cvid ref) ma c -> synchronised $ do
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(_, threads', woken) <- case ma of
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Just a -> do
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writeRef ref Nothing
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putIntoMVar cvar a c tid (cThreads ctx)
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Nothing ->
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tryTakeFromMVar cvar (const c) tid (cThreads ctx)
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simple threads' $ SetMVar cvid woken
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Let's break this down a bit.
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.. code-block:: haskell
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-- atomically set the value of an @MVar@.
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ASetMVar cvar@(MVar cvid ref) ma c -> synchronised $ do
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"cvar" means "concurrent variable", and "cvid" means "concurrent
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variable ID", this is a naming convention from the past which I
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haven't updated yet.
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The tricky bit here is ``synchronised``. It means that this action
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imposes a *memory barrier*: any uncommitted ``CRef`` writes get
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flushed when this action is performed. Pretty much everything other
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than a couple of ``CRef`` operations impose a memory barrier.
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Incidentally, this is what the ``SynchronisedWrite`` we mentioned
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above refers to.
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.. code-block:: haskell
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(_, threads', woken) <- case ma of
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Just a -> do
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writeRef ref Nothing
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putIntoMVar cvar a c tid (cThreads ctx)
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Nothing ->
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tryTakeFromMVar cvar (const c) tid (cThreads ctx)
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Now we update the value inside the ``MVar``, using the pre-existing
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functions to do that. We have two cases: (1) if we're setting the
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value in the ``MVar`` to something new; and (2) if we're unsetting it.
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1. In this case, we unconditionally empty the ``MVar``, then we write
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the new value. As each primitive action is executed atomically,
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this is fine.
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2. In this case, we just re-use the ``tryTakeMVar`` logic.
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Both ``putIntoMVar`` and ``tryTakeFromMVar`` are implemented in
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``Test.DejaFu.Conc.Internal.Memory``, in terms of more general
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functions called ``mutMVar`` and ``seeMVar``. They're pretty short,
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so go have a read if you like. Each takes the ``MVar`` to update, the
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continuation to call, the current thread ID, and the collection of
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threads (from the global context object). They return an indicator of
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success, an updated collection of threads, and a list of woken
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threads.
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.. code-block:: haskell
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simple threads' $ SetMVar cvid woken
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Finally, we produce a new context by saying that this is a "simple"
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action (one which only updates the threads), and giving the
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``ThreadAction`` value. This action also updates the relaxed memory
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state, but ``synchronised`` handles that bit.
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Our final task is to actually define the ``setMVar`` function, which
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I'll put in ``Test.DejaFu.Conc``:
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.. code-block:: haskell
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setMVar :: MVar r a -> Maybe a -> ConcT r n ()
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setMVar var a = toConc (\c -> ASetMVar var a (c ()))
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And we're done!
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Testing
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-------
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Now we want to make sure it works. In particular, we want to write a
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test which will fail if we use the non-atomic version from the start,
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but pass with the atomic version. I can think of two such tests:
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.. code-block:: haskell
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-- | An intermediate state shouldn't be observable
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setMVarIntermediate :: Monad n => ConcT r n Bool
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setMVarIntermediate = do
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v <- newMVar 1
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fork (setMVar v (Just 2))
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isNothing <$> tryReadMVar v
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This should never return ``True``.
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.. code-block:: haskell
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-- | It should terminate
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setMVarTerminate :: Monad n => ConcT r n Bool
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setMVarTerminate = do
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v <- newMVar 1
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let loop = putMVar v 2 >> loop
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fork loop
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setMVar v (Just 3)
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This should always terminate.
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Let's just try these in ghci with our new primitive:
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.. code-block:: none
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> let way = systematically defaultBounds { boundPreemp = Nothing }
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> resultsSet way defaultMemType setMVarIntermediate
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fromList [Right False]
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> resultsSet way defaultMemType setMVarTerminate
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fromList [Right ()]
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We're not using ``defaultWay`` because any pre-emption bound would
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prevent an infinite loop caused by thread switching from being
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observed. And now with the non-atomic version:
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.. code-block:: none
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> resultsSet way defaultMemType setMVarIntermediate
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fromList [Right False,Right True]
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> resultsSet way defaultMemType setMVarTerminate
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fromList [Left Abort,Right ()]
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Great! Now that wasn't so bad, was it?
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