Partitioned global address space

In computer science, a partitioned global address space (PGAS) is a parallel programming model. It assumes a global memory address space that is logically partitioned and a portion of it is local to each process or thread.^[1] The novelty of PGAS is that the portions of the shared memory space may have an affinity for a particular process, thereby exploiting locality of reference. The PGAS model is the basis of Unified Parallel C, Coarray Fortran, Fortress, Chapel, X10, Global Arrays and SHMEM. In standard Fortran, this model is now an integrated part of the language (as of Fortran 2008). PGAS attempts to combine the advantages of a SPMD programming style for distributed memory systems (as employed by MPI) with the data referencing semantics of shared memory systems. This is more realistic than the traditional shared memory approach of one flat address space, because hardware-specific data locality can be modeled in the partitioning of the address space.

A variant of the PGAS model, asynchronous partitioned global address space (APGAS) permits both local and remote asynchronous task creation.^[2] Two programming languages that use this model are Chapel and X10.

References

↑ Cristian Coarfӑ; Yuri Dotsenko; John Mellor-Crummey, "An Evaluation of Global Address Space Languages: Co-Array Fortran and Uniﬁed Parallel C"
↑ Tim Stitt, "An Introduction to the Partitioned Global Address Space (PGAS) Programming Model"

External links

Official website
An Introduction to the Partitioned Global Address Space Model
Programming in the Partitioned Global Address Space Model (2003)
GASNet Communication System - provides a software infrastructure for PGAS languages over high-performance networks

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[1] Cristian Coarfӑ; Yuri Dotsenko; John Mellor-Crummey, "An Evaluation of Global Address Space Languages: Co-Array Fortran and Uniﬁed Parallel C"

[2] Tim Stitt, "An Introduction to the Partitioned Global Address Space (PGAS) Programming Model"

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[2]

v t e Parallel computing
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Levels	Bit Instruction Task Data Memory
Multithreading	Temporal Simultaneous Preemptive Cooperative
Theory	PRAM model Analysis of parallel algorithms Amdahl's law Gustafson's law Cost efficiency Karp–Flatt metric Slowdown Speedup
Elements	Process Thread Fiber Instruction window
Coordination	Multiprocessing Memory coherency Cache coherency Cache invalidation Barrier Synchronization Application checkpointing
Programming	Models Implicit parallelism Explicit parallelism Concurrency Non-blocking algorithm
Hardware	Flynn's taxonomy SISD SIMD MISD MIMD Pipelined processor Superscalar processor Vector processor Multiprocessor symmetric asymmetric Memory shared distributed distributed shared UMA NUMA COMA Massively parallel computer Computer cluster Grid computer
APIs	POSIX Threads OpenMP OpenCL OpenHMPP OpenACC MPI PVM UPC TBB Boost.Thread Global Arrays Ateji PX Charm++ Cilk Coarray Fortran CUDA Dryad C++ AMP PLINQ TPL
Problems	Embarrassingly parallel Software lockout Scalability Race condition Deadlock Livelock Starvation Deterministic algorithm Parallel slowdown
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Partitioned global address space

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