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9.7 KiB
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261 lines
9.7 KiB
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===================================
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Compiling CUDA C/C++ with LLVM
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===================================
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.. contents::
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:local:
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Introduction
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============
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This document contains the user guides and the internals of compiling CUDA
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C/C++ with LLVM. It is aimed at both users who want to compile CUDA with LLVM
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and developers who want to improve LLVM for GPUs. This document assumes a basic
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familiarity with CUDA. Information about CUDA programming can be found in the
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`CUDA programming guide
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<http://docs.nvidia.com/cuda/cuda-c-programming-guide/index.html>`_.
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How to Build LLVM with CUDA Support
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===================================
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CUDA support is still in development and works the best in the trunk version
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of LLVM. Below is a quick summary of downloading and building the trunk
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version. Consult the `Getting Started
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<http://llvm.org/docs/GettingStarted.html>`_ page for more details on setting
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up LLVM.
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#. Checkout LLVM
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.. code-block:: console
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$ cd where-you-want-llvm-to-live
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$ svn co http://llvm.org/svn/llvm-project/llvm/trunk llvm
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#. Checkout Clang
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.. code-block:: console
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$ cd where-you-want-llvm-to-live
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$ cd llvm/tools
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$ svn co http://llvm.org/svn/llvm-project/cfe/trunk clang
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#. Configure and build LLVM and Clang
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.. code-block:: console
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$ cd where-you-want-llvm-to-live
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$ mkdir build
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$ cd build
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$ cmake [options] ..
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$ make
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How to Compile CUDA C/C++ with LLVM
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===================================
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We assume you have installed the CUDA driver and runtime. Consult the `NVIDIA
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CUDA installation guide
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<https://docs.nvidia.com/cuda/cuda-installation-guide-linux/index.html>`_ if
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you have not.
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Suppose you want to compile and run the following CUDA program (``axpy.cu``)
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which multiplies a ``float`` array by a ``float`` scalar (AXPY).
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.. code-block:: c++
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#include <iostream>
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__global__ void axpy(float a, float* x, float* y) {
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y[threadIdx.x] = a * x[threadIdx.x];
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}
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int main(int argc, char* argv[]) {
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const int kDataLen = 4;
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float a = 2.0f;
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float host_x[kDataLen] = {1.0f, 2.0f, 3.0f, 4.0f};
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float host_y[kDataLen];
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// Copy input data to device.
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float* device_x;
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float* device_y;
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cudaMalloc(&device_x, kDataLen * sizeof(float));
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cudaMalloc(&device_y, kDataLen * sizeof(float));
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cudaMemcpy(device_x, host_x, kDataLen * sizeof(float),
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cudaMemcpyHostToDevice);
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// Launch the kernel.
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axpy<<<1, kDataLen>>>(a, device_x, device_y);
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// Copy output data to host.
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cudaDeviceSynchronize();
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cudaMemcpy(host_y, device_y, kDataLen * sizeof(float),
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cudaMemcpyDeviceToHost);
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// Print the results.
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for (int i = 0; i < kDataLen; ++i) {
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std::cout << "y[" << i << "] = " << host_y[i] << "\n";
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}
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cudaDeviceReset();
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return 0;
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}
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The command line for compilation is similar to what you would use for C++.
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.. code-block:: console
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$ clang++ axpy.cu -o axpy --cuda-gpu-arch=<GPU arch> \
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-L<CUDA install path>/<lib64 or lib> \
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-lcudart_static -ldl -lrt -pthread
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$ ./axpy
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y[0] = 2
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y[1] = 4
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y[2] = 6
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y[3] = 8
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``<CUDA install path>`` is the root directory where you installed CUDA SDK,
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typically ``/usr/local/cuda``. ``<GPU arch>`` is `the compute capability of
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your GPU <https://developer.nvidia.com/cuda-gpus>`_. For example, if you want
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to run your program on a GPU with compute capability of 3.5, you should specify
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``--cuda-gpu-arch=sm_35``.
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Detecting clang vs NVCC
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=======================
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Although clang's CUDA implementation is largely compatible with NVCC's, you may
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still want to detect when you're compiling CUDA code specifically with clang.
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This is tricky, because NVCC may invoke clang as part of its own compilation
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process! For example, NVCC uses the host compiler's preprocessor when
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compiling for device code, and that host compiler may in fact be clang.
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When clang is actually compiling CUDA code -- rather than being used as a
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subtool of NVCC's -- it defines the ``__CUDA__`` macro. ``__CUDA_ARCH__`` is
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defined only in device mode (but will be defined if NVCC is using clang as a
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preprocessor). So you can use the following incantations to detect clang CUDA
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compilation, in host and device modes:
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.. code-block:: c++
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#if defined(__clang__) && defined(__CUDA__) && !defined(__CUDA_ARCH__)
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// clang compiling CUDA code, host mode.
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#endif
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#if defined(__clang__) && defined(__CUDA__) && defined(__CUDA_ARCH__)
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// clang compiling CUDA code, device mode.
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#endif
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Both clang and nvcc define ``__CUDACC__`` during CUDA compilation. You can
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detect NVCC specifically by looking for ``__NVCC__``.
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Flags that control numerical code
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=================================
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If you're using GPUs, you probably care about making numerical code run fast.
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GPU hardware allows for more control over numerical operations than most CPUs,
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but this results in more compiler options for you to juggle.
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Flags you may wish to tweak include:
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* ``-ffp-contract={on,off,fast}`` (defaults to ``fast`` on host and device when
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compiling CUDA) Controls whether the compiler emits fused multiply-add
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operations.
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* ``off``: never emit fma operations, and prevent ptxas from fusing multiply
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and add instructions.
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* ``on``: fuse multiplies and adds within a single statement, but never
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across statements (C11 semantics). Prevent ptxas from fusing other
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multiplies and adds.
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* ``fast``: fuse multiplies and adds wherever profitable, even across
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statements. Doesn't prevent ptxas from fusing additional multiplies and
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adds.
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Fused multiply-add instructions can be much faster than the unfused
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equivalents, but because the intermediate result in an fma is not rounded,
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this flag can affect numerical code.
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* ``-fcuda-flush-denormals-to-zero`` (default: off) When this is enabled,
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floating point operations may flush `denormal
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<https://en.wikipedia.org/wiki/Denormal_number>`_ inputs and/or outputs to 0.
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Operations on denormal numbers are often much slower than the same operations
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on normal numbers.
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* ``-fcuda-approx-transcendentals`` (default: off) When this is enabled, the
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compiler may emit calls to faster, approximate versions of transcendental
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functions, instead of using the slower, fully IEEE-compliant versions. For
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example, this flag allows clang to emit the ptx ``sin.approx.f32``
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instruction.
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This is implied by ``-ffast-math``.
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Optimizations
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=============
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CPU and GPU have different design philosophies and architectures. For example, a
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typical CPU has branch prediction, out-of-order execution, and is superscalar,
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whereas a typical GPU has none of these. Due to such differences, an
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optimization pipeline well-tuned for CPUs may be not suitable for GPUs.
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LLVM performs several general and CUDA-specific optimizations for GPUs. The
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list below shows some of the more important optimizations for GPUs. Most of
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them have been upstreamed to ``lib/Transforms/Scalar`` and
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``lib/Target/NVPTX``. A few of them have not been upstreamed due to lack of a
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customizable target-independent optimization pipeline.
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* **Straight-line scalar optimizations**. These optimizations reduce redundancy
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in straight-line code. Details can be found in the `design document for
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straight-line scalar optimizations <https://goo.gl/4Rb9As>`_.
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* **Inferring memory spaces**. `This optimization
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<https://github.com/llvm-mirror/llvm/blob/master/lib/Target/NVPTX/NVPTXInferAddressSpaces.cpp>`_
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infers the memory space of an address so that the backend can emit faster
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special loads and stores from it.
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* **Aggressive loop unrooling and function inlining**. Loop unrolling and
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function inlining need to be more aggressive for GPUs than for CPUs because
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control flow transfer in GPU is more expensive. They also promote other
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optimizations such as constant propagation and SROA which sometimes speed up
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code by over 10x. An empirical inline threshold for GPUs is 1100. This
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configuration has yet to be upstreamed with a target-specific optimization
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pipeline. LLVM also provides `loop unrolling pragmas
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<http://clang.llvm.org/docs/AttributeReference.html#pragma-unroll-pragma-nounroll>`_
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and ``__attribute__((always_inline))`` for programmers to force unrolling and
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inling.
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* **Aggressive speculative execution**. `This transformation
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<http://llvm.org/docs/doxygen/html/SpeculativeExecution_8cpp_source.html>`_ is
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mainly for promoting straight-line scalar optimizations which are most
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effective on code along dominator paths.
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* **Memory-space alias analysis**. `This alias analysis
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<http://reviews.llvm.org/D12414>`_ infers that two pointers in different
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special memory spaces do not alias. It has yet to be integrated to the new
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alias analysis infrastructure; the new infrastructure does not run
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target-specific alias analysis.
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* **Bypassing 64-bit divides**. `An existing optimization
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<http://llvm.org/docs/doxygen/html/BypassSlowDivision_8cpp_source.html>`_
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enabled in the NVPTX backend. 64-bit integer divides are much slower than
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32-bit ones on NVIDIA GPUs due to lack of a divide unit. Many of the 64-bit
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divides in our benchmarks have a divisor and dividend which fit in 32-bits at
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runtime. This optimization provides a fast path for this common case.
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Publication
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===========
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| `gpucc: An Open-Source GPGPU Compiler <http://dl.acm.org/citation.cfm?id=2854041>`_
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| Jingyue Wu, Artem Belevich, Eli Bendersky, Mark Heffernan, Chris Leary, Jacques Pienaar, Bjarke Roune, Rob Springer, Xuetian Weng, Robert Hundt
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| *Proceedings of the 2016 International Symposium on Code Generation and Optimization (CGO 2016)*
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| `Slides for the CGO talk <http://wujingyue.com/docs/gpucc-talk.pdf>`_
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Tutorial
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========
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`CGO 2016 gpucc tutorial <http://wujingyue.com/docs/gpucc-tutorial.pdf>`_
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Obtaining Help
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==============
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To obtain help on LLVM in general and its CUDA support, see `the LLVM
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community <http://llvm.org/docs/#mailing-lists>`_.
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