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419 lines
14 KiB
Plaintext
419 lines
14 KiB
Plaintext
/* Copyright (c) 2022, NVIDIA CORPORATION. All rights reserved.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions
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* are met:
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* * Redistributions of source code must retain the above copyright
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* notice, this list of conditions and the following disclaimer.
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* * Redistributions in binary form must reproduce the above copyright
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* notice, this list of conditions and the following disclaimer in the
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* documentation and/or other materials provided with the distribution.
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* * Neither the name of NVIDIA CORPORATION nor the names of its
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* contributors may be used to endorse or promote products derived
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* from this software without specific prior written permission.
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*
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* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS ``AS IS'' AND ANY
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* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
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* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
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* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
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* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
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* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
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* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
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* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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// Shuffle intrinsics CUDA Sample
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// This sample demonstrates the use of the shuffle intrinsic
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// First, a simple example of a prefix sum using the shuffle to
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// perform a scan operation is provided.
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// Secondly, a more involved example of computing an integral image
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// using the shuffle intrinsic is provided, where the shuffle
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// scan operation and shuffle xor operations are used
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#include <stdio.h>
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#include <cuda_runtime.h>
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#include <helper_cuda.h>
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#include <helper_functions.h>
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#include "shfl_integral_image.cuh"
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// Scan using shfl - takes log2(n) steps
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// This function demonstrates basic use of the shuffle intrinsic, __shfl_up,
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// to perform a scan operation across a block.
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// First, it performs a scan (prefix sum in this case) inside a warp
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// Then to continue the scan operation across the block,
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// each warp's sum is placed into shared memory. A single warp
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// then performs a shuffle scan on that shared memory. The results
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// are then uniformly added to each warp's threads.
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// This pyramid type approach is continued by placing each block's
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// final sum in global memory and prefix summing that via another kernel call,
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// then uniformly adding across the input data via the uniform_add<<<>>> kernel.
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__global__ void shfl_scan_test(int *data, int width, int *partial_sums = NULL) {
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extern __shared__ int sums[];
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int id = ((blockIdx.x * blockDim.x) + threadIdx.x);
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int lane_id = id % warpSize;
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// determine a warp_id within a block
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int warp_id = threadIdx.x / warpSize;
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// Below is the basic structure of using a shfl instruction
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// for a scan.
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// Record "value" as a variable - we accumulate it along the way
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int value = data[id];
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// Now accumulate in log steps up the chain
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// compute sums, with another thread's value who is
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// distance delta away (i). Note
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// those threads where the thread 'i' away would have
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// been out of bounds of the warp are unaffected. This
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// creates the scan sum.
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#pragma unroll
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for (int i = 1; i <= width; i *= 2) {
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unsigned int mask = 0xffffffff;
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int n = __shfl_up_sync(mask, value, i, width);
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if (lane_id >= i) value += n;
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}
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// value now holds the scan value for the individual thread
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// next sum the largest values for each warp
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// write the sum of the warp to smem
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if (threadIdx.x % warpSize == warpSize - 1) {
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sums[warp_id] = value;
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}
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__syncthreads();
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//
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// scan sum the warp sums
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// the same shfl scan operation, but performed on warp sums
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//
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if (warp_id == 0 && lane_id < (blockDim.x / warpSize)) {
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int warp_sum = sums[lane_id];
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int mask = (1 << (blockDim.x / warpSize)) - 1;
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for (int i = 1; i <= (blockDim.x / warpSize); i *= 2) {
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int n = __shfl_up_sync(mask, warp_sum, i, (blockDim.x / warpSize));
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if (lane_id >= i) warp_sum += n;
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}
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sums[lane_id] = warp_sum;
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}
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__syncthreads();
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// perform a uniform add across warps in the block
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// read neighbouring warp's sum and add it to threads value
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int blockSum = 0;
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if (warp_id > 0) {
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blockSum = sums[warp_id - 1];
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}
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value += blockSum;
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// Now write out our result
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data[id] = value;
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// last thread has sum, write write out the block's sum
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if (partial_sums != NULL && threadIdx.x == blockDim.x - 1) {
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partial_sums[blockIdx.x] = value;
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}
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}
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// Uniform add: add partial sums array
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__global__ void uniform_add(int *data, int *partial_sums, int len) {
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__shared__ int buf;
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int id = ((blockIdx.x * blockDim.x) + threadIdx.x);
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if (id > len) return;
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if (threadIdx.x == 0) {
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buf = partial_sums[blockIdx.x];
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}
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__syncthreads();
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data[id] += buf;
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}
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static unsigned int iDivUp(unsigned int dividend, unsigned int divisor) {
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return ((dividend % divisor) == 0) ? (dividend / divisor)
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: (dividend / divisor + 1);
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}
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// This function verifies the shuffle scan result, for the simple
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// prefix sum case.
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bool CPUverify(int *h_data, int *h_result, int n_elements) {
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// cpu verify
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for (int i = 0; i < n_elements - 1; i++) {
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h_data[i + 1] = h_data[i] + h_data[i + 1];
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}
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int diff = 0;
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for (int i = 0; i < n_elements; i++) {
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diff += h_data[i] - h_result[i];
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}
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printf("CPU verify result diff (GPUvsCPU) = %d\n", diff);
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bool bTestResult = false;
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if (diff == 0) bTestResult = true;
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StopWatchInterface *hTimer = NULL;
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sdkCreateTimer(&hTimer);
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sdkResetTimer(&hTimer);
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sdkStartTimer(&hTimer);
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for (int j = 0; j < 100; j++)
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for (int i = 0; i < n_elements - 1; i++) {
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h_data[i + 1] = h_data[i] + h_data[i + 1];
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}
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sdkStopTimer(&hTimer);
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double cput = sdkGetTimerValue(&hTimer);
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printf("CPU sum (naive) took %f ms\n", cput / 100);
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return bTestResult;
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}
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// this verifies the row scan result for synthetic data of all 1's
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unsigned int verifyDataRowSums(unsigned int *h_image, int w, int h) {
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unsigned int diff = 0;
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for (int j = 0; j < h; j++) {
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for (int i = 0; i < w; i++) {
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int gold = i + 1;
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diff +=
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abs(static_cast<int>(gold) - static_cast<int>(h_image[j * w + i]));
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}
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}
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return diff;
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}
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bool shuffle_simple_test(int argc, char **argv) {
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int *h_data, *h_partial_sums, *h_result;
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int *d_data, *d_partial_sums;
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const int n_elements = 65536;
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int sz = sizeof(int) * n_elements;
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int cuda_device = 0;
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printf("Starting shfl_scan\n");
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// use command-line specified CUDA device, otherwise use device with highest
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// Gflops/s
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cuda_device = findCudaDevice(argc, (const char **)argv);
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cudaDeviceProp deviceProp;
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checkCudaErrors(cudaGetDevice(&cuda_device));
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checkCudaErrors(cudaGetDeviceProperties(&deviceProp, cuda_device));
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printf("> Detected Compute SM %d.%d hardware with %d multi-processors\n",
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deviceProp.major, deviceProp.minor, deviceProp.multiProcessorCount);
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// __shfl intrinsic needs SM 3.0 or higher
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if (deviceProp.major < 3) {
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printf("> __shfl() intrinsic requires device SM 3.0+\n");
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printf("> Waiving test.\n");
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exit(EXIT_WAIVED);
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}
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checkCudaErrors(cudaMallocHost(reinterpret_cast<void **>(&h_data),
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sizeof(int) * n_elements));
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checkCudaErrors(cudaMallocHost(reinterpret_cast<void **>(&h_result),
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sizeof(int) * n_elements));
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// initialize data:
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printf("Computing Simple Sum test\n");
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printf("---------------------------------------------------\n");
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printf("Initialize test data [1, 1, 1...]\n");
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for (int i = 0; i < n_elements; i++) {
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h_data[i] = 1;
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}
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int blockSize = 256;
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int gridSize = n_elements / blockSize;
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int nWarps = blockSize / 32;
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int shmem_sz = nWarps * sizeof(int);
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int n_partialSums = n_elements / blockSize;
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int partial_sz = n_partialSums * sizeof(int);
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printf("Scan summation for %d elements, %d partial sums\n", n_elements,
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n_elements / blockSize);
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int p_blockSize = min(n_partialSums, blockSize);
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int p_gridSize = iDivUp(n_partialSums, p_blockSize);
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printf("Partial summing %d elements with %d blocks of size %d\n",
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n_partialSums, p_gridSize, p_blockSize);
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// initialize a timer
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cudaEvent_t start, stop;
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checkCudaErrors(cudaEventCreate(&start));
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checkCudaErrors(cudaEventCreate(&stop));
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float et = 0;
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float inc = 0;
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checkCudaErrors(cudaMalloc(reinterpret_cast<void **>(&d_data), sz));
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checkCudaErrors(
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cudaMalloc(reinterpret_cast<void **>(&d_partial_sums), partial_sz));
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checkCudaErrors(cudaMemset(d_partial_sums, 0, partial_sz));
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checkCudaErrors(
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cudaMallocHost(reinterpret_cast<void **>(&h_partial_sums), partial_sz));
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checkCudaErrors(cudaMemcpy(d_data, h_data, sz, cudaMemcpyHostToDevice));
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checkCudaErrors(cudaEventRecord(start, 0));
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shfl_scan_test<<<gridSize, blockSize, shmem_sz>>>(d_data, 32, d_partial_sums);
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shfl_scan_test<<<p_gridSize, p_blockSize, shmem_sz>>>(d_partial_sums, 32);
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uniform_add<<<gridSize - 1, blockSize>>>(d_data + blockSize, d_partial_sums,
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n_elements);
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checkCudaErrors(cudaEventRecord(stop, 0));
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checkCudaErrors(cudaEventSynchronize(stop));
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checkCudaErrors(cudaEventElapsedTime(&inc, start, stop));
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et += inc;
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checkCudaErrors(cudaMemcpy(h_result, d_data, sz, cudaMemcpyDeviceToHost));
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checkCudaErrors(cudaMemcpy(h_partial_sums, d_partial_sums, partial_sz,
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cudaMemcpyDeviceToHost));
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printf("Test Sum: %d\n", h_partial_sums[n_partialSums - 1]);
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printf("Time (ms): %f\n", et);
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printf("%d elements scanned in %f ms -> %f MegaElements/s\n", n_elements, et,
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n_elements / (et / 1000.0f) / 1000000.0f);
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bool bTestResult = CPUverify(h_data, h_result, n_elements);
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checkCudaErrors(cudaFreeHost(h_data));
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checkCudaErrors(cudaFreeHost(h_result));
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checkCudaErrors(cudaFreeHost(h_partial_sums));
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checkCudaErrors(cudaFree(d_data));
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checkCudaErrors(cudaFree(d_partial_sums));
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return bTestResult;
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}
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// This function tests creation of an integral image using
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// synthetic data, of size 1920x1080 pixels greyscale.
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bool shuffle_integral_image_test() {
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char *d_data;
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unsigned int *h_image;
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unsigned int *d_integral_image;
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int w = 1920;
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int h = 1080;
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int n_elements = w * h;
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int sz = sizeof(unsigned int) * n_elements;
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printf("\nComputing Integral Image Test on size %d x %d synthetic data\n", w,
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h);
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printf("---------------------------------------------------\n");
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checkCudaErrors(cudaMallocHost(reinterpret_cast<void **>(&h_image), sz));
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// fill test "image" with synthetic 1's data
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memset(h_image, 0, sz);
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// each thread handles 16 values, use 1 block/row
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int blockSize = iDivUp(w, 16);
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// launch 1 block / row
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int gridSize = h;
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// Create a synthetic image for testing
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checkCudaErrors(cudaMalloc(reinterpret_cast<void **>(&d_data), sz));
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checkCudaErrors(cudaMalloc(reinterpret_cast<void **>(&d_integral_image),
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n_elements * sizeof(int) * 4));
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checkCudaErrors(cudaMemset(d_data, 1, sz));
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checkCudaErrors(cudaMemset(d_integral_image, 0, sz));
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cudaEvent_t start, stop;
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cudaEventCreate(&start);
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cudaEventCreate(&stop);
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float et = 0;
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unsigned int err;
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// Execute scan line prefix sum kernel, and time it
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cudaEventRecord(start);
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shfl_intimage_rows<<<gridSize, blockSize>>>(
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reinterpret_cast<uint4 *>(d_data),
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reinterpret_cast<uint4 *>(d_integral_image));
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cudaEventRecord(stop);
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checkCudaErrors(cudaEventSynchronize(stop));
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checkCudaErrors(cudaEventElapsedTime(&et, start, stop));
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printf("Method: Fast Time (GPU Timer): %f ms ", et);
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// verify the scan line results
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checkCudaErrors(
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cudaMemcpy(h_image, d_integral_image, sz, cudaMemcpyDeviceToHost));
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err = verifyDataRowSums(h_image, w, h);
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printf("Diff = %d\n", err);
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// Execute column prefix sum kernel and time it
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dim3 blockSz(32, 8);
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dim3 testGrid(w / blockSz.x, 1);
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cudaEventRecord(start);
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shfl_vertical_shfl<<<testGrid, blockSz>>>((unsigned int *)d_integral_image, w,
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h);
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cudaEventRecord(stop);
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checkCudaErrors(cudaEventSynchronize(stop));
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checkCudaErrors(cudaEventElapsedTime(&et, start, stop));
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printf("Method: Vertical Scan Time (GPU Timer): %f ms ", et);
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// Verify the column results
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checkCudaErrors(
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cudaMemcpy(h_image, d_integral_image, sz, cudaMemcpyDeviceToHost));
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printf("\n");
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int finalSum = h_image[w * h - 1];
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printf("CheckSum: %d, (expect %dx%d=%d)\n", finalSum, w, h, w * h);
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checkCudaErrors(cudaFree(d_data));
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checkCudaErrors(cudaFree(d_integral_image));
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checkCudaErrors(cudaFreeHost(h_image));
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// verify final sum: if the final value in the corner is the same as the size
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// of the buffer (all 1's) then the integral image was generated successfully
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return (finalSum == w * h) ? true : false;
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}
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int main(int argc, char *argv[]) {
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// Initialization. The shuffle intrinsic is not available on SM < 3.0
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// so waive the test if the hardware is not present.
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int cuda_device = 0;
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printf("Starting shfl_scan\n");
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// use command-line specified CUDA device, otherwise use device with highest
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// Gflops/s
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cuda_device = findCudaDevice(argc, (const char **)argv);
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cudaDeviceProp deviceProp;
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checkCudaErrors(cudaGetDevice(&cuda_device));
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checkCudaErrors(cudaGetDeviceProperties(&deviceProp, cuda_device));
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printf("> Detected Compute SM %d.%d hardware with %d multi-processors\n",
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deviceProp.major, deviceProp.minor, deviceProp.multiProcessorCount);
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// __shfl intrinsic needs SM 3.0 or higher
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if (deviceProp.major < 3) {
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printf("> __shfl() intrinsic requires device SM 3.0+\n");
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printf("> Waiving test.\n");
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exit(EXIT_WAIVED);
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}
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bool bTestResult = true;
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bool simpleTest = shuffle_simple_test(argc, argv);
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bool intTest = shuffle_integral_image_test();
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bTestResult = simpleTest & intTest;
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exit((bTestResult) ? EXIT_SUCCESS : EXIT_FAILURE);
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}
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