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Parallelism and Concurrency Koen Lindström Claessen Chalmers University Gothenburg, Sweden Ulf Norell.

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Presentation on theme: "Parallelism and Concurrency Koen Lindström Claessen Chalmers University Gothenburg, Sweden Ulf Norell."— Presentation transcript:

1 Parallelism and Concurrency Koen Lindström Claessen Chalmers University Gothenburg, Sweden Ulf Norell

2 Expressing Parallelism In a pure, lazy language  Evaluation is done when needed  Evaluation order does not affect meaning of program  One can do more work than what is needed

3 Two Primitives seq :: a -> b -> b par :: a -> b -> b seq x y: Evaluate x first, and then return y par x y: Evaluate x in parallel, and immediately return y

4 Example f’ x y z = x `par` y `par` z `par` f x y z Idea: Write normal program first, then add parallelism to speed it up

5 QuickSort qsort :: (Ord a) => [a] -> [a] qsort [] = [] qsort [x] = [x] qsort (x:xs) = losort `par` hisort `par` losort ++ (x:hisort) where losort = qsort [y | y <- xs, y < x ] hisort = qsort [y | y = x ]

6 QuickSort (II) qsort :: (Ord a) => [a] -> [a] qsort [] = [] qsort [x] = [x] qsort (x:xs) = force losort `par` force hisort `par` losort ++ (x:hisort) where losort = qsort [y | y <- xs, y < x ] hisort = qsort [y | y = x ] force :: [a] -> () force [] = () force (x:xs) = x `seq` force xs

7 Parallel Map pmap :: (a -> b) -> [a] -> [b] pmap f [] = [] pmap f (x:xs) = fx `par` fxs `par` fx:fxs where fx = f x fxs = pmap f xs

8 Parallel Strategies type Done = () type Strategy a = a -> Done using :: a -> Strategy a -> a a `using` strat = strat a `seq` a

9 Parallel Strategies inSeq, inPar :: a -> Strategy b inSeq x = \y -> x `seq` () inPar x = \y -> x `par` () parList :: Strategy a -> Strategy [a] parList strat [] = () parList strat (x:xs) = strat x `par` parList strat xs

10 Parallel Strategies pmap :: Strategy b -> (a -> b) -> [a] -> [b] pmap strat f xs = map f xs `using` parList strat

11 More... Implemented in GHC  Control.Parallel  Control.Parallel.Strategies Also look at:  Control.Concurrent (-threaded)  Control.Monad.STM

12 Concurrent Programming Processes  Concurrency  Parallelism Shared resources  Communication  Locks  Blocking

13 Concurrent Haskell (v1.0) Control.Concurrent fork :: IO a -> IO Pid kill:: Pid -> IO () type MVar a newEmptyMVar:: IO (MVar a) takeMVar:: MVar a -> IO a putMVar:: MVar a -> a -> IO () starting/killing processes a shared resource blocking actions

14 Concurrent Haskell (v1.0) Control.Concurrent.Chan type Chan a newChan:: IO (Chan a) readChan:: Chan a -> IO a writeChan:: Chan a -> a -> IO () an unbounded channel

15 Typical Concurrent Programming Today Use MVars (or similar concepts) to implement ”locks”  Grab the lock Block if someone else has it  Do your thing  Release the lock

16 Problems With Locking Races  Forgotten lock Deadlock  Grabbing/releasing locks in wrong order Error recovery  Invariants  Locks

17 The Biggest Problem Locks are not compositional ! Compositional = build a working system from working pieces action1 = withdraw a 100action2 = deposit b 100 action3 = do withdraw a 100 deposit b 100 Inconsistent state

18 Solution (?) Expose the locks action3 = do lock a lock b withdraw a 100 deposit b 100 release a release b Danger of deadlock! if a < b then do lock a; lock b else do lock b; lock a

19 More Problems action4 = do... action5 = do... action6 = action4 AND action5 Impossible! Need to keep track of all locks of an action, and compose these

20 Conclusion Programming with locks is  Not compositional  Not scalable  Gives you a head ache  Leads to code with errors ... A new concurrent programming paradigm is sorely needed

21 Idea Borrow ideas from database people  Transactions Add ideas from functional programming  Computations are first-class values  What side-effects can happen where is controlled Et voila!

22 Software Transactional Memory (STM) First ideas in 1993 New developments in 2005  Simon Peyton Jones  Simon Marlow  Tim Harris  Maurice Herlihy

23 Atomic Transactions action3 = atomically { withdraw a 100 deposit b 100 } ”write sequential code, and wrap atomically around it”

24 How Does It Work? Execute body without locks Each memory acces is logged No actual update is performed At the end, we try to commit the log to memory Commit may fail, then we retry the whole atomic block action3 = atomically { withdraw a 100 deposit b 100 }

25 Transactional Memory No locks, so no race conditions No locks, so no deadlocks Error recovery is easy; an exception aborts the whole block and retries Simple code, and scalable

26 Caveats Absolutely forbidden:  To read a transaction variable outside an atomic block  To write to a transaction variable outside an atomic block  To make actual changes inside an atomic block...

27 Simon’s Missile Program action3 = atomically { withdraw a 100 launchNuclearMissiles deposit b 100 } No side effects allowed!

28 STM Haskell Control.Concurrent.STM First (and so far only?) fully-fledged implementation of STM Implementations for C++, Java, C# on the way...  Difficult to solve the problems In Haskell, it is easy!  Controlled side-effects

29 STM Haskell Control.Concurrent.STM type STM a instance Monad STM type TVar a newTVar :: a -> STM (TVar a) readTVar:: TVar a -> STM a writeTVar:: TVar a -> a -> STM () atomically:: STM a -> IO a

30 Example type Resource = TVar Int putR :: Resource -> Int -> STM () putR r i = do v <- readTVar r writeTVar r (v+i) main = do... atomically (putR r 13)...

31 Example retry:: STM a getR :: Resource -> Int -> STM () getR r i = do v <- readTVar r if v < i then retry else writeTVar r (v-i) main = do... atomically (do getR r1 4 putR r2 4)...

32 Retrying An atomic block is retried when  The programmer says so  The commit at the end fails Before retrying, we wait until one of the variables used in the atomic block is changed  Why? Referential transparency!

33 Compositional Choice orElse:: STM a -> STM a -> STM a main = do... atomically (getR r1 4 `orElse` getR r2 4)... m1 `orElse` (m2 `orElse` m3) = (m1 `orElse` m2) `orElse` m3 retry `orElse` m = m m `orElse` retry = m

34 Blocking or not? nonBlockGetR :: Resource -> Int -> STM Bool nonBlockGetR r i = do getR r i return True `orElse` return False Choice of blocking/non- blocking up to the caller, not the method itself

35 Example: MVars MVars can be implemented using TVars type MVar a = TVar (Maybe a)

36 New Things in STM Haskell Safe transactions through type safety  Degenerate monad STM We can only access TVars TVars can only be accessed in STM monad  Referential transparency Explicit retry -- expressiveness Compositional choice -- expressiveness

37 Problems in C++/Java/C# Retry semantics IO in atomic blocks Access of transaction variables outside of atomic blocks Access to regular variables inside of atomic blocks

38 STM Haskell Control.Concurrent.STM type STM a instance Monad STM type TVar a newTVar :: a -> STM (TVar a) readTVar:: TVar a -> STM a writeTVar:: TVar a -> a -> STM () atomically:: STM a -> IO a retry:: STM a orElse:: STM a -> STM a -> STM a

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