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Applications and libraries/Concurrency and parallelism

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== Concurrent and Parallel Programming ==
 
== Concurrent and Parallel Programming ==
   
Haskell has been designed for paralell and concurrent programming, since
+
Haskell has been designed for parallel and concurrent programming, since
 
its inception. In particular, purity greatly simplifies reasoning about
 
its inception. In particular, purity greatly simplifies reasoning about
 
parallel programs. This page lists libraries and extensions for programming
 
parallel programs. This page lists libraries and extensions for programming

Revision as of 11:30, 24 June 2007

Contents

1 Concurrent and Parallel Programming

Haskell has been designed for parallel and concurrent programming, since its inception. In particular, purity greatly simplifies reasoning about parallel programs. This page lists libraries and extensions for programming concurrent and parallel applications in Haskell. See also the research papers on parallel and concurrent Haskell.

1.1 Symmetric multiprocessor Haskell

Multiprocessor GHC
As of GHC 6.5, GHC supports running programs in parallel on an SMP or multicore machine, and has been used successfully on up to 40 cpus.

1.2 Concurrent Haskell

Concurrent Haskell
GHC has supported concurrency via forkIO and MVars for more than a decade.
User-level events and threads
Ultra lightweight, user level threads for GHC Haskell, layered over epoll. Tested with up to 10 million lightweight threads. Experimental.
Wrapped Concurrency
A wrapper around Control.Concurrency and Control.Exception that provides versions of forkIO that have more guarantees.

1.3 Software transactional memory

Software Transactional Memory
Since 2005, GHC has supported a sophisticated version of software transactional memory. Software Transactional Memory (STM) is a new way to coordinate concurrent threads. STM is in GHC 6.4.x, and is described in the paper Composable memory transactions. The paper Lock-free data structures using Software Transactional Memory in Haskell gives further examples of concurrent programming using STM.

1.4 Data Parallel Haskell

Data Parallel Haskell is the codename for an extension to the Glasgow Haskell Compiler and its libraries to support nested data parallelism with a focus to utilise multi-core CPUs.

1.5 Parallel Haskell

GpH: Glasgow Parallel Haskell
A complete, GHC-based implementation of the parallel Haskell extension GpH and of evaluation strategies is available. Extensions of the runtime-system and language to improve performance and support new platforms are under development.

1.6 Distributed Haskell

GdH: Glasgow Distributed Haskell
GdH supports distributed stateful interactions on multiple locations. It is a conservative extension of both Concurrent Haskell and GpH, enabling the distribution of the stateful IO threads of the former on the multiple locations of the latter. The programming model includes forking stateful threads on remote locations, explicit communication over channels, and distributed exception handling.
Mobile Haskell (mHaskell)
Mobile Haskell supports both strong and weak mobility of computations across open networks. The mobility primitives are higher-order polymorphic channels. Mid-level abstractions like remote evaluation, analogous to Java RMI, are readily constructed. High-level mobility skeletons like mobile map and mobile fold encapsulate common patterns of mobile computation.
Eden
Eden extends Haskell with a small set of syntactic constructs for explicit process specification and creation. While providing enough control to implement parallel algorithms efficiently, it frees the programmer from the tedious task of managing low-level details by introducing automatic communication (via head-strict lazy lists), synchronisation, and process handling.

1.7 MPI

hMPI
hMPI is an acronym for HaskellMPI. It is a Haskell binding conforming to MPI (Message Passing Interface) standard 1.1/1.2. The programmer is in full control over the communication between the nodes of a cluster.
The Haskell Ports Library (HPL)
Ports are an abstraction for modelling variables whose values evolve over time without the need to resort to mutable variable, such as IORefs. More precisely, a port represents all values that a time-dependent variable successively takes as a stream, where each element of the stream corresponds to a state change - we can also say that a port represents a time series. Moreover, a port supports concurrent construction of the time series, or stream of values.
HCPN: Haskell-Coloured Petri Nets
Haskell-Coloured Petri Nets (HCPN) are an instance of high-level Petri Nets, in which anonymous tokens are replaced by Haskell data objects (and transitions can operate on that data, in addition to moving it around). This gives us a hybrid graphical/textual modelling formalism for Haskell, especially suited for modelling concurrent and distributed systems.