module System.Concurrency %default total -- At the moment this is pretty fundamentally tied to the Scheme RTS. -- Given that different back ends will have entirely different threading -- models, it might be unavoidable, but we might want to think about possible -- primitives that back ends should support. -- Thread mailboxes %foreign "scheme:blodwen-set-thread-data" prim__setThreadData : {a : Type} -> a -> PrimIO () %foreign "scheme:blodwen-get-thread-data" prim__getThreadData : (a : Type) -> PrimIO a export setThreadData : HasIO io => {a : Type} -> a -> io () setThreadData val = primIO (prim__setThreadData val) export getThreadData : HasIO io => (a : Type) -> io a getThreadData a = primIO (prim__getThreadData a) -- Mutexes export data Mutex : Type where [external] %foreign "scheme:blodwen-make-mutex" prim__makeMutex : PrimIO Mutex %foreign "scheme:blodwen-mutex-acquire" prim__mutexAcquire : Mutex -> PrimIO () %foreign "scheme:blodwen-mutex-release" prim__mutexRelease : Mutex -> PrimIO () ||| Creates and returns a new mutex. export makeMutex : HasIO io => io Mutex makeMutex = primIO prim__makeMutex ||| Acquires the mutex identified by `mutex`. The thread blocks until the mutex ||| has been acquired. ||| ||| Mutexes are recursive in Posix threads terminology, which means that the ||| calling thread can use mutex-acquire to (re)acquire a mutex it already has. ||| In this case, an equal number of mutex-release calls is necessary to release ||| the mutex. export mutexAcquire : HasIO io => Mutex -> io () mutexAcquire m = primIO (prim__mutexAcquire m) ||| Releases the mutex identified by `mutex`. Unpredictable behavior results if ||| the mutex is not owned by the calling thread. export mutexRelease : HasIO io => Mutex -> io () mutexRelease m = primIO (prim__mutexRelease m) -- Condition variables export data Condition : Type where [external] %foreign "scheme,racket:blodwen-make-cv" "scheme,chez:blodwen-make-condition" prim__makeCondition : PrimIO Condition %foreign "scheme,racket:blodwen-cv-wait" "scheme,chez:blodwen-condition-wait" prim__conditionWait : Condition -> Mutex -> PrimIO () %foreign "scheme,chez:blodwen-condition-wait-timeout" -- "scheme,racket:blodwen-cv-wait-timeout" prim__conditionWaitTimeout : Condition -> Mutex -> Int -> PrimIO () %foreign "scheme,racket:blodwen-cv-signal" "scheme,chez:blodwen-condition-signal" prim__conditionSignal : Condition -> PrimIO () %foreign "scheme,racket:blodwen-cv-broadcast" "scheme,chez:blodwen-condition-broadcast" prim__conditionBroadcast : Condition -> PrimIO () ||| Creates and returns a new condition variable. export makeCondition : HasIO io => io Condition makeCondition = primIO prim__makeCondition ||| Waits up to the specified timeout for the condition identified by the ||| condition variable `cond`. The calling thread must have acquired the mutex ||| identified by `mutex` at the time `conditionWait` is called. The mutex is ||| released as a side effect of the call to `conditionWait`. When a thread is ||| later released from the condition variable by one of the procedures ||| described below, the mutex is reacquired and `conditionWait` returns. export conditionWait : HasIO io => Condition -> Mutex -> io () conditionWait cond mutex = primIO (prim__conditionWait cond mutex) ||| Variant of `conditionWait` with a timeout in microseconds. ||| When the timeout expires, the thread is released, `mutex` is reacquired, and ||| `conditionWaitTimeout` returns. export conditionWaitTimeout : HasIO io => Condition -> Mutex -> Int -> io () conditionWaitTimeout cond mutex timeout = primIO (prim__conditionWaitTimeout cond mutex timeout) ||| Releases one of the threads waiting for the condition identified by `cond`. export conditionSignal : HasIO io => Condition -> io () conditionSignal c = primIO (prim__conditionSignal c) ||| Releases all of the threads waiting for the condition identified by `cond`. export conditionBroadcast : HasIO io => Condition -> io () conditionBroadcast c = primIO (prim__conditionBroadcast c) -- Semaphores export data Semaphore : Type where [external] %foreign "scheme:blodwen-make-semaphore" prim__makeSemaphore : Int -> PrimIO Semaphore %foreign "scheme:blodwen-semaphore-post" prim__semaphorePost : Semaphore -> PrimIO () %foreign "scheme:blodwen-semaphore-wait" prim__semaphoreWait : Semaphore -> PrimIO () ||| Creates and returns a new semaphore with the counter initially set to `init`. export makeSemaphore : HasIO io => Int -> io Semaphore makeSemaphore init = primIO (prim__makeSemaphore init) ||| Increments the semaphore's internal counter. export semaphorePost : HasIO io => Semaphore -> io () semaphorePost sema = primIO (prim__semaphorePost sema) ||| Blocks until the internal counter for semaphore sema is non-zero. When the ||| counter is non-zero, it is decremented and `semaphoreWait` returns. export semaphoreWait : HasIO io => Semaphore -> io () semaphoreWait sema = primIO (prim__semaphoreWait sema) -- Barriers ||| A barrier enables multiple threads to synchronize the beginning of some ||| computation. export data Barrier : Type where [external] %foreign "scheme:blodwen-make-barrier" prim__makeBarrier : Int -> PrimIO Barrier %foreign "scheme:blodwen-barrier-wait" prim__barrierWait : Barrier -> PrimIO () ||| Creates a new barrier that can block a given number of threads. export makeBarrier : HasIO io => Int -> io Barrier makeBarrier numThreads = primIO (prim__makeBarrier numThreads) ||| Blocks the current thread until all threads have rendezvoused here. export barrierWait : HasIO io => Barrier -> io () barrierWait barrier = primIO (prim__barrierWait barrier) -- Channels export data Channel : Type -> Type where [external] %foreign "scheme:blodwen-make-channel" prim__makeChannel : PrimIO (Channel a) %foreign "scheme:blodwen-channel-get" prim__channelGet : Channel a -> PrimIO a %foreign "scheme:blodwen-channel-put" prim__channelPut : Channel a -> a -> PrimIO () ||| Creates and returns a new channel. The channel can be used with channelGet ||| to receive a value through the channel. The channel can be used with ||| channelPut to send a value through the channel. export makeChannel : HasIO io => io (Channel a) makeChannel = primIO prim__makeChannel ||| Blocks until a sender is ready to provide a value through `chan`. The result ||| is the sent value. export channelGet : HasIO io => Channel a -> io a channelGet chan = primIO (prim__channelGet chan) ||| Blocks until a receiver is ready to accept the value `val` through `chan`. export channelPut : HasIO io => Channel a -> a -> io () channelPut chan val = primIO (prim__channelPut chan val)