1 / 35

Using Open64 for High Performance Computing on a GPU

Using Open64 for High Performance Computing on a GPU. by Mike Murphy, Gautam Chakrabarti, and Xiangyun Kong. Using Open64 for High Performance Computing on a GPU. Background and Overview Functionality Work Performance Work Concluding Thoughts. Why Use a GPU?.

stacia
Download Presentation

Using Open64 for High Performance Computing on a GPU

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Using Open64 for High Performance Computing on a GPU by Mike Murphy, Gautam Chakrabarti, and Xiangyun Kong

  2. Using Open64 for High Performance Computing on a GPU • Background and Overview • Functionality Work • Performance Work • Concluding Thoughts

  3. Why Use a GPU? • Sequential processors have hit a wall • GPU is efficient parallel processor • lots of big ALUs • multithreading can hide latency • context switching is basically free • all threads run same sequential program • SIMT (Single Instruction Multiple Thread)

  4. GPU for Compute • CUDA (Compute Unified Device Architecture) • augment C/C++ with minimal abstraction • divide into sequential host and parallel device code • let programmers focus on parallel algorithms

  5. CUDA Example // Compute vector sum C = A+B // Each thread performs one pair-wise addition __global__ void vecAdd(float* A, float* B, float* C, int n) { int i = threadIdx.x + blockDim.x * blockIdx.x; if(i<n) C[i] = A[i] + B[i]; } int main() { // Run N/256 blocks of 256 threads each vecAdd<<< N/256, 256>>>(d_A, d_B, d_C, n); } Host Code

  6. CUDA Successes • Nebulae computer uses NVIDIA GPU • #4 on Green500 list (MFLOPS/Watt) • #2 on Top500 list • DARPA “exascale supercomputer” grant just announced • Thousands of applications. e.g. • AMBER (scientific) • Numerix (financial) • Adobe Premiere Pro (video) • Physx (game collision physics)

  7. CUDA Accelerating Computation 146X 36X 19X 17X 100X Interactive visualization of volumetric white matter connectivity Ionic placement for molecular dynamics simulation on GPU Transcoding HD video stream to H.264 Simulation in Matlab using .mex file CUDA function Astrophysics N-body simulation 149X 47X 20X 24X 30X Financial simulation of LIBOR model with swaptions GLAME@lab: An M-script API for linear Algebra operations on GPU Ultrasound medical imaging for cancer diagnostics Highly optimized object oriented molecular dynamics Cmatch exact string matching to find similar proteins and gene sequences

  8. Why Open64? • Previously, GPU’s were hard to program • Used optimizing assembler on short shaders • Did scheduling, register allocation and peephole opts • For CUDA want ability to code in C/C++ • Needed high-level optimizing compiler • Open64 was open-source and good optimizer

  9. Where Open64? device code host code executable

  10. What Open64? • no Fortran • no IPA • no LNO • minimal CG ptxas does register allocation, scheduling and peephole optimizations

  11. How Open64? • Functional enhancements • Performance enhancements

  12. Windows Host • Hosted on 32 and 64bit linux, mac, and windows • Windows build uses MINGW, so need cygwin to build, but can run without cygwin. • Can also build with visual studio from cygwin. • No dso’s or dll’s: combine be, wopt, cg and target into one executable.

  13. PTX Target • Unlimited virtual registers of different sizes • Explicit memory spaces (e.g. ld.global) • Strongly typed instructions • No stack • Abstracted call syntax • Vector memory accesses

  14. Handling Virtual Registers • PTX has unlimited virtual registers of different sizes • by default, targ_info and cg use static arrays of registers. • compile problems when 100,000 registers. • most info is same so use sparse arrays, hash maps, or just no array (recalculate).

  15. PTX Target – no stack • Try to store all local variables in registers • even for –g (limited local memory space) • keep small structs and unions in registers • enhancements in VHO and CGEXP • use local memory if cannot put in reg (e.g. address taken) • Abstracted call syntax • use param space in PTX • ptxas will utilize param registers and stack

  16. How Open64? • Functional enhancements • Performance enhancements

  17. Vectorizing Memory Accesses • Vector memory accesses save memory latency. • We optimize on scalars then in CG we coalesce loads and stores into vectors. • ld.f32 f1, [arr+4]; • S1; • ld.f32 f2, [arr+0]; • can be vectorized to: • ld.v2.f32 {f2,f1}, [arr+0]; • S1; • if arr is 8-byte aligned and S1 does not use f2

  18. Rematerialization • Rematerialize across basic blocks to reduce register pressure. • Some instructions like shared memory loads can be folded in final object code. • Use dominator info to find last reaching def • find defs in BB_dom, the def that dominates others is last reaching def. • can rematerialize def if no intervening def, alias, or barrier.

  19. 32->16bit optimization • C rules promote arithmetic to int (32bits) • But use fewer registers if pack into 16bit • Some 16bit instructions are faster (e.g. multiply) • Pass to analyze 16bit load/store/converts • Propagate info forwards and backwards • Change to 16bit if 16bits are enough

  20. Hierarchy of Memory Spaces Per-thread local memory Per-block shared memory Per-device global memory Generic memory overlays other spaces Thread per-threadlocal memory Block per-blockshared memory . . . Kernel per-deviceglobal memory . . .

  21. Handling Memory Spaces Infer the address space of all memory accesses Use “generic” or “unified” addressing if a memory access cannot be resolved statically Generic address access has more latency than specific memory access Specific memory accesses good for performance Pointer class analysis

  22. Pointer Class Analysis An example __shared__ int sharedvar; __device__ void devicefunction(void) { int *lvar = &sharedvar; = *lvar; // whether to generate generic ld or ld.shared *lvar = ; // whether to generate generic st or st.shared }

  23. Pointer Class Analysis (continued) Another example __shared__ int sharedvar; __device__ void devicefunction(int * input) { int *lvar = &sharedvar; = *lvar + *input; // generate generic ld or ld.shared for lvar? *lvar = ; // generate generic st or st.shared for lvar? } What address space does “input” point to? Inlining may help disambiguate “input”

  24. Pointer Class-based Alias Analysis Memory accesses to different address spaces do not overlap Address space information used to help resolve aliases Pointer class information maintained for each memory access Alias Manager takes pointer class into consideration

  25. Why Pointer Class Analysis ? Generic addressing more expensive than specific addressing Improve Open64’s alias analysis Specific memory accesses help memory disambiguation in ptxas Some optimizations applicable only to certain memory spaces (e.g. LDU) In summary pointer class analysis benefits application performance.

  26. Variance Analysis • CUDA’s execution model: • - At a given time, all participated threads run the same kernel in-parallel • - Each thread has its own registers, thread ID, local memory

  27. Variance Analysis (2) • Though all participated threads execute the same instructions, but different thread may get different results because of thread ID differences • Variance Analysis is to find out instructions which may produce thread-dependent (variant) results

  28. Why Variance Analysis ? • CUDA’s execution model: • if (cond) then S1 else S2 • step 1: all-threads execute cond • step 2: threads-with-true-cond execute S1 • step 3: threads-with-false-cond execute S2

  29. Why Variance Analysis (2)? • If the cond is not variant, only one of the branches is executed. • If the cond is variant, both branches under the condition will be executed ( sequentially ). • - avoid placing code into multiple branches under a variant condition

  30. Why Variance Analysis (3) ? An example, … if (x > 0) S1 else S2 endif S3 if (x > 0) S4 else S5 endif Assuming x is not changed in any of the statements, the following transformation may be desired, … if (x > 0) S1 S3 S4 else S2 S3 S5 endif But if x is variant, therefore x > 0 may be variant, the above transformation may increase run-time, since S3 could be executed twice.

  31. Why Variance Analysis (3) ? Variance Analysis also help explore certain architecture specific properties, - Issue only one Load request if a LOAD loads from a non-Variant address, otherwise, need to issue load request for each thread.

  32. Variance Analysis Algorithm • 1) Build Forward Data-Flow • 2) Collect an initial set of Variant Values • 3) Chasing Forward Data-Flow on Variant Values to Find affected variant Values • 4) Mark Variant Conditions, and collect new Variant Values, and back to 3)

  33. Concluding Thoughts • Open64 has been successfully used for functionality and performance in CUDA.

  34. Concluding Thoughts • What obstacles have we faced in using Open64? • Open64 was originally designed for superscalar CPUs • GPU presents different issues with registers and memory model. • Register pressure is critical issue; some optimizations increase register pressure. • GPL license limits some uses of compiler in embedded space.

  35. Questions?

More Related