Introduction to the CUDA Toolkit for Building Applications

Transcript

1. Introduction to the CUDA Toolkit for Building Applications Adam DeConinck

   HPC Systems Engineer, NVIDIA

2. Copyright © NVIDIA Corporation What this talk will cover: The

   CUDA 5 Toolkit as a toolchain for HPC applications, focused on the needs of sysadmins and application packagers Review GPU Computing concepts CUDA C/C++ with nvcc compiler Example application build processes OpenACC compilers Common libraries What this talk won’t cover: Developing software for GPUs General sysadmin of a GPU cluster Earlier versions of CUDA (mostly) Anything to do with Windows

3. Copyright © NVIDIA Corporation GPU CPU CPU vs GPU Latency

   Processor + Throughput processor

4. Copyright © NVIDIA Corporation Low Latency or High Throughput? CPU

   Optimized for low-latency access to cached data sets Control logic for out-of-order and speculative execution GPU Optimized for data-parallel, throughput computation Architecture tolerant of memory latency More transistors dedicated to computation

5. Copyright © NVIDIA Corporation Processing Flow 1. Copy input data

   from CPU memory to GPU memory PCIe Bus

6. Copyright © NVIDIA Corporation Processing Flow 1. Copy input data

   from CPU memory to GPU memory 2. Load GPU program and execute, caching data on chip for performance PCIe Bus

7. Copyright © NVIDIA Corporation Processing Flow 1. Copy input data

   from CPU memory to GPU memory 2. Load GPU program and execute, caching data on chip for performance 3. Copy results from GPU memory to CPU memory PCIe Bus

8. Copyright © NVIDIA Corporation Anatomy of a CUDA Application Serial

   code executes in a Host (CPU) thread Parallel code executes in many Device (GPU) threads across multiple processing elements CUDA Application Serial code Serial code Parallel code Parallel code Device = GPU … Host = CPU Device = GPU ... Host = CPU

9. Copyright © NVIDIA Corporation void saxpy_serial(int n, float a, float

   *x, float *y) { for (int i = 0; i < n; ++i) y[i] = a*x[i] + y[i]; } // Perform SAXPY on 1M elements saxpy_serial(4096*256, 2.0, x, y); __global__ void saxpy_parallel(int n, float a, float *x, float *y) { int i = blockIdx.x*blockDim.x + threadIdx.x; if (i < n) y[i] = a*x[i] + y[i]; } // Perform SAXPY on 1M elements saxpy_parallel<<<4096,256>>>(n,2.0,x,y); CUDA C Standard C Code Parallel C Code

10. Copyright © NVIDIA Corporation 3 Ways to Accelerate Applications Applications

    Libraries “Drop-in” Acceleration Programming Languages Most common: CUDA C Also CUDA Fortran, PyCUDA, Matlab, … OpenACC Directives Compiler directives (Like OpenMP)

11. Copyright © NVIDIA Corporation 3 Ways to Accelerate Applications Applications

    Libraries “Drop-in” Acceleration Programming Languages Most common: CUDA C Also CUDA Fortran, PyCUDA, Matlab, … OpenACC Directives Like OpenMP Most of the talk will focus on CUDA Toolkit (CUDA C) Will hit OpenACC and common libraries at the end of the talk

12. Copyright © NVIDIA Corporation Working with the CUDA Toolkit

13. Copyright © NVIDIA Corporation CUDA Toolkit Free developer tools for

    building applications with CUDA C/C++ and the CUDA Runtime API Includes (on Linux): nvcc compiler Debugging and profiling tools Nsight Eclipse Edition IDE NVIDIA Visual Profiler A collection of libraries (CUBLAS, CUFFT, Thrust, etc) Currently the most common tool for building NVIDIA GPU applications

14. Copyright © NVIDIA Corporation CUDA Toolkit environment module #%Module module-whatis

    “CUDA Toolkit 5.0” set root /opt/cuda-5.0 set CUDA_HOME $root prepend-path PATH $root/bin prepend-path PATH $root/open64/bin prepend-path CPATH $root/include prepend-path LD_LIBRARY_PATH $root/lib64

15. Copyright © NVIDIA Corporation Building a CUDA app CUDA doesn’t

    impose any specific build process, so most common build processes are represented in apps configure/make/make install cmake/make/make install etc Similar to MPI in that you just have to point to nvcc correctly (like pointing to the right mpicc) But you always have to use the “special” compiler; not just a wrapper like mpicc to command-line options If CUDA support is optional, there’s often a configure option or macro to enable/disable it --enable-cuda … --with-cuda … --enable-nvidia … -DCUDA_ENABLE=1 … No convention on what this option should be

16. Copyright © NVIDIA Corporation Where’s CUDA? Common to install CUDA

    somewhere other than /usr/local/cuda, so where is it? Common: specify location of the CUDA toolkit using an environment variable No convention on the name of this variable, though CUDA_HOME=… is common Also CUDA=, CUDA_PATH=, NVIDIA_CUDA=, … OR a command line argument: --with-cuda-lib=/opt/cuda …. OR just hard-code /usr/local/cuda in the Makefile I see this far too frequently.

17. Copyright © NVIDIA Corporation NVCC Compiler Compiler for CUDA C/C++

    Uses the CUDA Runtime API Resulting binaries link to CUDA Runtime library, libcudart.so Takes a mix of host code and device code as input Uses g++ for host code Builds code for CPU and GPU architectures Generates a binary which combines both types of code

18. Copyright © NVIDIA Corporation Common NVCC Options Environment variable Command-line

    flag Equivalent for gcc Definition INCLUDES --include-path -I CPATH -I Define additional include paths LIBRARIES --library-path -L LD_LIBRARY_PATH -L Define additional library paths --optimize -O -O Optimization level for host code -use_fast_math Apply all device-level math optimizations PTXAS_FLAGS -Xptxas=-v Print GPU resources (shared memory, registers) used per kernel

19. Copyright © NVIDIA Corporation CUDA support in MPI implementations Most

    major MPIs now support addressing CUDA device memory directly Do MPI_Send/MPI_Receive with pointers to device memory; skip cudaMemcpy step in application code GPUDirect: do direct device-to-device transfers (skipping host memory) OpenMPI, mvapich2, Platform MPI, … See NVIDIA DevZone for a full list Support typically has to be included at compile time

20. Copyright © NVIDIA Corporation Example: matrixMul Single CUDA source file

    containing host and device code Single compiler command using nvcc $ nvcc -m64 -I../../common/inc matrixMul.cu $ ./a.out [Matrix Multiply Using CUDA] - Starting... GPU Device 0: "Tesla M2070" with compute capability 2.0 MatrixA(320,320), MatrixB(640,320) Computing result using CUDA Kernel...done ...

21. Copyright © NVIDIA Corporation Example: simpleMPI Simple example combining CUDA

    with MPI Split and scatter an array of random numbers, do computation on GPUs, reduce on host node MPI and CUDA code separated into different source files, simpleMPI.cpp and simpleMPI.cu Works exactly like any other multi-file C++ build Build the CUDA object file, build the C++ object, link them together

22. Copyright © NVIDIA Corporation $ make nvcc -m64 -gencode arch=compute_10,code=sm_10

    -gencode arch=compute_20,code=sm_20 -gencode arch=compute_30,code=sm_30 -o simpleMPI.o -c simpleMPI.cu mpicxx -m64 -o main.o -c simpleMPI.cpp mpicxx -m64 -o simpleMPI simpleMPI.o main.o -L$CUDA/lib64 - lcudart

23. Copyright © NVIDIA Corporation $ make nvcc -m64 -gencode arch=compute_10,code=sm_10

    -gencode arch=compute_20,code=sm_20 -gencode arch=compute_30,code=sm_30 -o simpleMPI.o -c simpleMPI.cu mpicxx -m64 -o main.o -c simpleMPI.cpp mpicxx -m64 -o simpleMPI simpleMPI.o main.o -L$CUDA/lib64 - lcudart (we’ll explain the –gencode bits later)

24. Copyright © NVIDIA Corporation Example: OpenMPI Popular MPI implementation Includes

    CUDA support for sending/receiving CUDA device pointers directly, without explicitly staging through host memory Either does implicit cudaMemcpy calls, or does direct transfers if GPUDirect support Configure options: --with-cuda=$CUDA_HOME --with-cuda-libdir=/usr/lib64 (or wherever libcuda.so is)

25. Copyright © NVIDIA Corporation Example: GROMACS Popular molecular dynamics application

    with CUDA support (mostly simulating biomolecules) Version 4.5: CUDA support via OpenMM library, only single-GPU support Version 4.6: CUDA supported directly, multi-GPU support Requires Compute Capability >= 2.0 (Fermi or Kepler)

26. Copyright © NVIDIA Corporation Example: GROMACS wget ftp://ftp.gromacs.org/pub/gromacs/gromacs-4.6.tar.gz tar xzf

    gromacs-4.6.tar.gz mkdir gromacs-build module load cmake cuda gcc/4.6.3 fftw openmpi CC=mpicc CXX=mpiCC cmake ./gromacs-4.6 -DGMX_OPENMP=ON -DGMX_GPU=ON -DGMX_MPI=ON -DGMX_PREFER_STATIC_LIBS=ON - DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=./gromacs-build make install

27. Copyright © NVIDIA Corporation Example: GROMACS (cmake) cmake defines a

    number of environment variables for controlling nvcc compiler GROMACS default value for CUDA_NVCC_FLAGS: -gencode;arch=compute_20,code=sm_20;-gencode;arch=compute_20,code=sm_21;- gencode;arch=compute_30,code=sm_30;- gencode;arch=compute_30,code=compute_30;-use_fast_math; Environment variables Meaning CUDA_HOST_COMPILER Specify which host-code compiler to use (i.e. which gcc) CUDA_HOST_COMPILER_OPTIONS Options passed to the host compiler CUDA_NVCC_FLAGS Options passed to nvcc

28. Copyright © NVIDIA Corporation CUDA C Build Process

29. Copyright © NVIDIA Corporation What actually gets built by nvcc?

    NVCC generates three types of code: Host object code (compiled with g++) Device object code Device assembly code (PTX) Compiler produces a “fat binary” which includes all three types of code Breaking changes in both NVIDIA object code and in PTX assembly can occur with each new GPU release PTX is forward-compatible, object code is not

30. Copyright © NVIDIA Corporation Fat binaries When a CUDA “fat

    binary” is run on a given GPU, a few different things can happen: If the fat binary includes object code compiled for the device architecture, that code is run directly. If the fat binary includes PTX assembly which the GPU understands, that code is Just-In-Time compiled and run on the GPU. (results in slight startup lag) If neither version are compatible with the GPU, the application doesn’t run. Always uses the correct object code, or the newest compatible PTX

31. Copyright © NVIDIA Corporation Why do we care? A given

    CUDA binary is not guaranteed to run on an arbitrary GPU And if it does run, not guaranteed to get best performance JIT startup time Your GPU may support newer PTX or object code features than are compiled in Mix of hardware you have in your cluster determines what options to include in your fat binaries

32. Copyright © NVIDIA Corporation NVCC Build Process (simplified) nvcc Input

    Files Host code Device code gcc nvopencc ptxas PTX (device assembly) fatbinary PTX and/or CUBIN gcc Host object code Combined object code

33. Copyright © NVIDIA Corporation Options to different stages Environment variables

    Command-line options Meaning -Xcompiler Pass options directly to the (host) compiler/preprocessor (i.e. gcc) -Xlinker Pass options directly to the linker -Xcudafe Pass options directly to cudafe (pre-processor/splitter) OPENCC_FLAGS -Xopencc Pass options directly to nvopencc, typically for steering device code optimization PTXAS_FLAGS -Xptxas Pass options directly to the ptx optimizing compiler

34. Copyright © NVIDIA Corporation Compute Capability Defines the computing features

    supported by a given GPU generation Language features (i.e. double precision floats, various functions) Device features (size of shared memory, max thread block size, etc) Newer GPUs can run older PTX assembly code. GPU Architecture Binary code is architecture- specific, and changes with each GPU generation Version of the object code. Different architectures use different optimizations, etc. Binary code from one architecture can’t run on another Compute capability and device architecture

35. Copyright © NVIDIA Corporation NVCC Build Process (simplified) nvcc Input

    Files Host code Device code gcc nvopencc ptxas PTX (device assembly) fatbinary PTX and/or CUBIN gcc Host object code Combined object code nvopencc generates PTX assembly according to the compute capability ptxas generates device binaries according to the device architecture fatbinary packages them together

36. Copyright © NVIDIA Corporation Compute capability and device architecture When

    you compile code with NVCC, you can specify Compute capabilities, which describe version of CUDA language & PTX. Compute capability named as compute_XX. (XX=version number) Device architectures, which describe version of CUDA object code. Device architecture named as sm_XX. You can generate multiple versions of both the PTX and the object code to be included. nvcc -m64 -gencode arch=compute_10,code=sm_10 -gencode arch=compute_20,code=sm_20 -gencode arch=compute_30,code=sm_30 -o simpleMPI.o -c simpleMPI.cu

37. Copyright © NVIDIA Corporation GROMACS revisited Default flags in GROMACS:

    CUDA_NVCC_FLAGS= -gencode;arch=compute_20,code=sm_20;- gencode;arch=compute_20,code=sm_21;- gencode;arch=compute_30,code=sm_30;- gencode;arch=compute_30,code=compute_30;-use_fast_math; Generates code for compute versions 2.0 (Tesla M2050/M2070), compute version 2.1 (Quadro 600, various GeForce) and 3.0 (Tesla K10) To generate optimized code for Tesla K20, you’d add compute capability 3.5: -gencode arch=compute_35,code=sm_35

38. Copyright © NVIDIA Corporation Common build strategies “Lowest common denominator”

    I can get away with Compute Capability 1.3, so that’s what I’ll use -gencode arch=compute_13,code=compute_13 –gencode arch=compute_13,code=sm_13 Newer GPUs must JIT from PTX code “Everything under the sun!” Compile for everything released when I wrote the Makefile -gencode arch=compute_10,code=sm_10 –gencode arch=compute_13,code=sm_13 –gencode arch=compute_20,code=sm_20 –gencode arch=compute_30,code=sm_30 –gencode arch=compute_35,code=sm_35 “Newest features only” Target the GPU I just bought, ignore earlier ones -gencode arch=compute_30,code=compute_30 –gencode arch=compute_30,code=sm_30

39. Copyright © NVIDIA Corporation Command line options for specifying arch

    Long option Short option Meaning --gpu-architecture <arch> -arch Specify the GPU architecture to compile for. This specifies what capabilities the code can use (features, etc). Default value: compute_10 --gpu-code <gpu> -code Specify the GPU(s) to generate code for, i.e. what PTX assembly and/or binary code to generate. Default value: compute_10,sm_10 --generate-code -gencode Generalize -arch and -code into a single option with keywords for convenience. -gencode arch=… code=…

40. Copyright © NVIDIA Corporation Host compiler compatibility Host compiler in

    NVCC is g++ (uses first one in PATH) If you want to use a different compiler with CUDA (Intel, PGI, etc), need to be able to link against GCC ABI Best practice: Minimize performance-critical host code in files processed by nvcc Link with objects produced by your compiler of choice Common pattern: build shared library containing all CUDA code, link to it from your larger application

41. Copyright © NVIDIA Corporation Other ways to build CUDA apps

42. Copyright © NVIDIA Corporation GPU Accelerated Libraries “Drop-in” Acceleration for

    your Applications NVIDIA cuBLAS NVIDIA cuRAND NVIDIA cuSPARSE NVIDIA NPP Vector Signal Image Processing Matrix Algebra on GPU and Multicore NVIDIA cuFFT C++ Templated Parallel Algorithms Sparse Linear Algebra IMSL Library GPU Accelerated Linear Algebra Building-block Algorithms

43. Copyright © NVIDIA Corporation GPU Accelerated Libraries “Drop-in” Acceleration for

    your Applications NVIDIA cuBLAS NVIDIA cuRAND NVIDIA cuSPARSE NVIDIA NPP Vector Signal Image Processing Matrix Algebra on GPU and Multicore NVIDIA cuFFT C++ Templated Parallel Algorithms Sparse Linear Algebra IMSL Library GPU Accelerated Linear Algebra Building-block Algorithms Included in CUDA Toolkit

44. Copyright © NVIDIA Corporation OpenACC Directives Program myscience ... serial

    code ... !$acc kernels do k = 1,n1 do i = 1,n2 ... parallel code ... enddo enddo !$acc end kernels ... End Program myscience CPU GPU Your original Fortran or C code Simple Compiler hints Compiler Parallelizes code Works on many-core GPUs & multicore CPUs OpenACC Compiler Hint

45. Copyright © NVIDIA Corporation OpenACC Useful way to quickly add

    CUDA support to a program without writing CUDA code directly, especially for legacy apps Uses compiler directives very similar to OpenMP Supports C and Fortran Generally doesn’t produce code as fast as a good CUDA programmer… but often get decent speedups Cross-platform; depending on compiler, supports NVIDIA, AMD, Intel accelerators Compiler support: Cray 8.0+ PGI 12.6+ CAPS HMPP 3.2.1+ http://developer.nvidia.com/openacc

46. Copyright © NVIDIA Corporation OpenACC $ pgcc -acc -Minfo=accel -ta=nvidia

    -o saxpy_acc saxpy.c PGC-W-0095-Type cast required for this conversion (saxpy.c: 13) PGC-W-0155-Pointer value created from a nonlong integral type (saxpy.c: 13) saxpy: 4, Generating present_or_copyin(x[0:n]) Generating present_or_copy(y[0:n]) Generating NVIDIA code Generating compute capability 1.0 binary Generating compute capability 2.0 binary Generating compute capability 3.0 binary 5, Loop is parallelizable Accelerator kernel generated 5, #pragma acc loop gang, vector(128) /* blockIdx.x threadIdx.x */ PGC/x86-64 Linux 13.2-0: compilation completed with warnings

47. Copyright © NVIDIA Corporation OpenACC PGI compiler generates… Object code

    for currently-installed GPU, if supported (auto-detect) PTX assembly for all major versions (1.0, 2.0, 3.0) Depending on the compiler step, there may or may not be a OpenACC->CUDA C translation step before compile (but this intermediate code is usually not accessible)

48. Copyright © NVIDIA Corporation CUDA Fortran Slightly-modified Fortran language which

    uses the CUDA Runtime API Almost 1:1 translation of CUDA C concepts to Fortran 90 Changes mostly to conform to Fortran idioms (“Fortranic”?) Currently supported only by PGI Fortran compiler pgfortran acts like “nvcc for Fortran” with either the –Mcuda option, or if you use the file extension .cuf Compiles to CUDA C as intermediate. Can keep C code with option “-Mcuda=keepgpu”

49. Copyright © NVIDIA Corporation Other GPU Programming Languages OpenACC, CUDA

    Fortran Fortran OpenACC, CUDA C C Thrust, CUDA C++ C++ PyCUDA, Copperhead, Numba Pro Python GPU.NET C# MATLAB, Mathematica, LabVIEW Numerical analytics

50. Copyright © NVIDIA Corporation Other GPU Programming Languages Current version

    of NVCC uses LLVM internally Code to compile LLVM IR to PTX assembly is open source (BSD license), so adding additional language support is easier More information: Compiler SDK https://developer.nvidia.com/cuda- llvm-compiler CUDA C, C++, Fortran LLVM Compiler For CUDA NVIDIA GPUs x86 CPUs New Language Support New Processor Support

51. Copyright © NVIDIA Corporation Other Resources CUDA Toolkit Documentation: http://docs.nvidia.com

    OpenACC: http://www.openacc.org/ CUDA Fortran @ PGI: http://www.pgroup.com/resources/cudafortran.htm GPU Applications Catalog (list of known common apps with GPU support): http://www.nvidia.com/docs/IO/123576/nv-applications-catalog-lowres.pdf Email me! Adam DeConinck, [email protected] …and many other resources available via CUDA Registered Developer program. https://developer.nvidia.com/nvidia-registered-developer-program

52. Copyright © NVIDIA Corporation Questions?