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1 The Portland Group, Inc. Brent Leback brent.leback@pgroup.com www.pgroup.com HPC User Forum, Broomfield, CO September 2009
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2 High Level Languages for Clusters Many failures in this area, academically and commercially Lack of Supply? Lack of Standards? Bad/Buggy Implementations? Lack of Generality? Lack of Performance? CAF is headed for the Fortran Standard (?) (!) Is it a good idea? Is it mature enough to standardize? Will anyone in attendance use it? Given our experience with HPF, PGI will be conservative on this front
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3 Performance Across Platforms: PGI Unified Binary PGI Unified Binary has been available since 2005 A single X64 binary including optimized code sequences for multiple target processor cores. -tp switch to specify target processor type, a number of AMD and Intel processor families currently supported. Especially important to ISVs AVX support is in progress Now PGI Unified Binary supports accelerated/non-accelerated binaries A single X64 binary recognizes the existence of a GPU and runs PGI accelerated versions there if available. -ta switch to specify target accelerator, currently only –ta=nvidia is supported. Use –ta=nvidia,host to generate code for both cases Target processor and Target Accelerator switches can be used together. Today, Intel64, AMD64, + NVIDIA is the full gamut.
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4 The “ Full Gamut ” Isn ’ t Very Full
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5 SUBROUTINE SAXPY (A,X,Y,N) INTEGER N REAL A,X(N),Y(N) !$ACC REGION DO I = 1, N X(I) = A*X(I) + Y(I) ENDDO !$ACC END REGION END saxpy_: … movl (%rbx), %eax movl %eax, -4(%rbp) call __pgi_cu_init... call __pgi_cu_function … call __pgi_cu_alloc … call __pgi_cu_upload … call __pgi_cu_call … call __pgi_cu_download … saxpy_: … movl (%rbx), %eax movl %eax, -4(%rbp) call __pgi_cu_init... call __pgi_cu_function … call __pgi_cu_alloc … call __pgi_cu_upload … call __pgi_cu_call … call __pgi_cu_download … Host x64 asm File Auto-generated GPU code typedef struct dim3{ unsigned int x,y,z; }dim3; typedef struct uint3{ unsigned int x,y,z; }uint3; extern uint3 const threadIdx, blockIdx; extern dim3 const blockDim, gridDim; static __attribute__((__global__)) void pgicuda( __attribute__((__shared__)) int tc, __attribute__((__shared__)) int i1, __attribute__((__shared__)) int i2, __attribute__((__shared__)) int _n, __attribute__((__shared__)) float* _c, __attribute__((__shared__)) float* _b, __attribute__((__shared__)) float* _a ) { int i; int p1; int _i; i = blockIdx.x * 64 + threadIdx.x; if( i < tc ){ _a[i+i2-1] = ((_c[i+i2-1]+_c[i+i2-1])+_b[i+i2-1]); _b[i+i2-1] = _c[i+i2]; _i = (_i+1); p1 = (p1-1); } } + Unified a.out compile link execute … no change to existing makefiles, scripts, IDEs, programming environment, etc. PGI Accelerator Compilers
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6 Supporting Heterogeneous Cores: PGI Accelerator Model Minimal changes to the language – directives/pragmas, in the same vein as vector or OpenMP parallel directives. As simple as !$ACC REGION !$ACC END REGION Minimal library calls – usually none Standard x64 toolchain – no changes to makefiles, linkers, build process, standard libraries, other tools Not a “platform” – binaries will execute on any compatible x64+GPU hardware system Performance feedback – learn from and leverage the success of vectorizing compilers in the 1970s and 1980s Incremental program migration – put migration decisions in the hands of developers PGI Unified Binary Technology – ensures continued portability to non GPU-enabled targets
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7 Programmer Productivity: Compiler-to-Programmer Feedback HPC Code PGI Compiler x64 CCFF Trace PGPROF HPC User Acc + Directives, Options, RESTRUCTURING CCFF provides: how/when a function was compiled, IPA optimizations, profile feedback runtime values, info on vectorization and parallelization, compute intensity, and missed opportunities Performance
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8 Supporting Third-Parties PGI 9.0 supports OpenMP 3.0 for Fortran, C/C++. OpenMP 3.0 Tasks supported in all languages OpenMP runtime overhead as measured by the EPCC benchmark is lower than our competition PGI is currently working with the OpenMP committee to investigate the support of an accelerator programming model as part of OpenMP and/or other standards body. Michael Wolfe is our OpenMP representative IMSL and NAG are already supported with PGI compilers; we're enabling them to migrate incrementally to heterogeneous manycore.
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9 Availability and Additional Information PGI Accelerator Programming Model – is supported for x64+NVIDIA Linux targets in the PGI 9.0 Fortran and C compilers, available now PGI CUDA Fortran – supporting explicit programming of x64+NVIDIA targets will be available in a production release of the PGI Fortran 95/03 compiler currently scheduled for release in November, 2009 Other GPU and Accelerator Targets – are being studied by PGI, and may be supported in the future as the necessary low-level software infrastructure (e.g. OpenCL) becomes more widely available Further Information – see www.pgroup.com/accelerate for a detailed specification of the PGI Accelerator model, an FAQ, and related articles and white paperswww.pgroup.com/accelerate CCFF – The Common Compiler Feedback Format, is described at www.pgroup.com/resources/ccff.htm www.pgroup.com/resources/ccff.htm
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