Massively parallel accelerators such as GPGPUs, manycores and FPGAs represent
a powerful and affordable tool for scientists who look to speed up simulations
of complex systems. However, porting code to such devices requires a detailed
understanding of heterogeneous programming tools and effective strategies for
parallelization. In this paper we present a source to source compilation
approach with whole-program analysis to automatically transform single-threaded
FORTRAN 77 legacy code into OpenCL-accelerated programs with parallelized
kernels.
The main contributions of our work are: (1) whole-source refactoring to allow
any subroutine in the code to be offloaded to an accelerator. (2) Minimization
of the data transfer between the host and the accelerator by eliminating
redundant transfers. (3) Pragmatic auto-parallelization of the code to be
offloaded to the accelerator by identification of parallelizable maps and
reductions.
We have validated the code transformation performance of the compiler on the
NIST FORTRAN 78 test suite and several real-world codes: the Large Eddy
Simulator for Urban Flows, a high-resolution turbulent flow model; the shallow
water component of the ocean model Gmodel; the Linear Baroclinic Model, an
atmospheric climate model and Flexpart-WRF, a particle dispersion simulator.
The automatic parallelization component has been tested on as 2-D Shallow
Water model (2DSW) and on the Large Eddy Simulator for Urban Flows (UFLES) and
produces a complete OpenCL-enabled code base. The fully OpenCL-accelerated
versions of the 2DSW and the UFLES are resp. 9x and 20x faster on GPU than the
original code on CPU, in both cases this is the same performance as manually
ported code.Comment: 12 pages, 5 figures, submitted to "Computers and Fluids" as full
paper from ParCFD conference entr