Unified Parallel C

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Unified Parallel C (UPC) is an extension of the C programming language designed for high-performance computing on large-scale parallel machines, including those with a common global address space (SMP and NUMA) and those with distributed memory (e. g. clusters). The programmer is presented with a single partitioned global address space; where shared variables may be directly read and written by any processor, but each variable is physically associated with a single processor. UPC uses a single program, multiple data (SPMD) model of computation in which the amount of parallelism is fixed at program startup time, typically with a single thread of execution per processor.

In order to express parallelism, UPC extends ISO C 99 with the following constructs:

• An explicitly parallel execution model
• A shared address space (shared storage qualifier) with thread-local parts (normal variables)
• Synchronization primitives and a memory consistency model
• Explicit communication primitives, e. g. upc_memput
• Memory management primitives

The UPC language evolved from experiences with three other earlier languages that proposed parallel extensions to ISO C 99: AC, Split-C, and Parallel C preprocessor (PCP). UPC is not a superset of these three languages, but rather an attempt to distill the best characteristics of each. UPC combines the programmability advantages of the shared memory programming paradigm and the control over data layout and performance of the message passing programming paradigm.

• Cilk
• Coarray Fortran
• Chapel
• X10
• High Performance Fortran
• OpenMP
• Partitioned global address space
• Parallel programming model
• Software transactional memory

• Official website
• UPC at LBNL
• UPC at GWU Archived 2012-07-08 at the Wayback Machine
• GNU UPC
• UPC Tutorial (2003)