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349 lines
11 KiB
Plaintext
349 lines
11 KiB
Plaintext
/* Copyright (c) 2019, 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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/**
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* Matrix multiplication: C = A * B.
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* Host code.
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*
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* This sample implements matrix multiplication which makes use of shared memory
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* to ensure data reuse, the matrix multiplication is done using tiling approach.
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* It has been written for clarity of exposition to illustrate various CUDA programming
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* principles, not with the goal of providing the most performant generic kernel for matrix multiplication.
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* See also:
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* V. Volkov and J. Demmel, "Benchmarking GPUs to tune dense linear algebra,"
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* in Proc. 2008 ACM/IEEE Conf. on Supercomputing (SC '08),
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* Piscataway, NJ: IEEE Press, 2008, pp. Art. 31:1-11.
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*/
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// System includes
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#include <stdio.h>
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#include <assert.h>
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// CUDA runtime
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#include <cuda_runtime.h>
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// Helper functions and utilities to work with CUDA
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#include <helper_functions.h>
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#include <helper_cuda.h>
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/**
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* Matrix multiplication (CUDA Kernel) on the device: C = A * B
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* wA is A's width and wB is B's width
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*/
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template <int BLOCK_SIZE> __global__ void MatrixMulCUDA(float *C, float *A,
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float *B, int wA,
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int wB) {
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// Block index
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int bx = blockIdx.x;
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int by = blockIdx.y;
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// Thread index
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int tx = threadIdx.x;
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int ty = threadIdx.y;
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// Index of the first sub-matrix of A processed by the block
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int aBegin = wA * BLOCK_SIZE * by;
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// Index of the last sub-matrix of A processed by the block
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int aEnd = aBegin + wA - 1;
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// Step size used to iterate through the sub-matrices of A
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int aStep = BLOCK_SIZE;
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// Index of the first sub-matrix of B processed by the block
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int bBegin = BLOCK_SIZE * bx;
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// Step size used to iterate through the sub-matrices of B
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int bStep = BLOCK_SIZE * wB;
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// Csub is used to store the element of the block sub-matrix
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// that is computed by the thread
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float Csub = 0;
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// Loop over all the sub-matrices of A and B
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// required to compute the block sub-matrix
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for (int a = aBegin, b = bBegin;
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a <= aEnd;
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a += aStep, b += bStep) {
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// Declaration of the shared memory array As used to
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// store the sub-matrix of A
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__shared__ float As[BLOCK_SIZE][BLOCK_SIZE];
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// Declaration of the shared memory array Bs used to
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// store the sub-matrix of B
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__shared__ float Bs[BLOCK_SIZE][BLOCK_SIZE];
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// Load the matrices from device memory
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// to shared memory; each thread loads
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// one element of each matrix
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As[ty][tx] = A[a + wA * ty + tx];
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Bs[ty][tx] = B[b + wB * ty + tx];
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// Synchronize to make sure the matrices are loaded
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__syncthreads();
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// Multiply the two matrices together;
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// each thread computes one element
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// of the block sub-matrix
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#pragma unroll
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for (int k = 0; k < BLOCK_SIZE; ++k) {
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Csub += As[ty][k] * Bs[k][tx];
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}
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// Synchronize to make sure that the preceding
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// computation is done before loading two new
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// sub-matrices of A and B in the next iteration
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__syncthreads();
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}
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// Write the block sub-matrix to device memory;
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// each thread writes one element
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int c = wB * BLOCK_SIZE * by + BLOCK_SIZE * bx;
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C[c + wB * ty + tx] = Csub;
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}
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void ConstantInit(float *data, int size, float val) {
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for (int i = 0; i < size; ++i) {
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data[i] = val;
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}
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}
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/**
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* Run a simple test of matrix multiplication using CUDA
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*/
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int MatrixMultiply(int argc, char **argv,
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int block_size, const dim3 &dimsA,
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const dim3 &dimsB) {
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// Allocate host memory for matrices A and B
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unsigned int size_A = dimsA.x * dimsA.y;
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unsigned int mem_size_A = sizeof(float) * size_A;
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float *h_A = reinterpret_cast<float *>(malloc(mem_size_A));
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unsigned int size_B = dimsB.x * dimsB.y;
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unsigned int mem_size_B = sizeof(float) * size_B;
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float *h_B = reinterpret_cast<float *>(malloc(mem_size_B));
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// Initialize host memory
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const float valB = 0.01f;
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ConstantInit(h_A, size_A, 1.0f);
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ConstantInit(h_B, size_B, valB);
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// Allocate device memory
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float *d_A, *d_B, *d_C;
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// Allocate host matrix C
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dim3 dimsC(dimsB.x, dimsA.y, 1);
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unsigned int mem_size_C = dimsC.x * dimsC.y * sizeof(float);
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float *h_C = reinterpret_cast<float *>(malloc(mem_size_C));
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if (h_C == NULL) {
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fprintf(stderr, "Failed to allocate host matrix C!\n");
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exit(EXIT_FAILURE);
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}
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checkCudaErrors(cudaMalloc(reinterpret_cast<void **>(&d_A), mem_size_A));
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checkCudaErrors(cudaMalloc(reinterpret_cast<void **>(&d_B), mem_size_B));
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checkCudaErrors(cudaMalloc(reinterpret_cast<void **>(&d_C), mem_size_C));
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// copy host memory to device
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checkCudaErrors(cudaMemcpy(d_A, h_A, mem_size_A, cudaMemcpyHostToDevice));
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checkCudaErrors(cudaMemcpy(d_B, h_B, mem_size_B, cudaMemcpyHostToDevice));
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// Setup execution parameters
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dim3 threads(block_size, block_size);
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dim3 grid(dimsB.x / threads.x, dimsA.y / threads.y);
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// Create and start timer
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printf("Computing result using CUDA Kernel...\n");
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// Performs warmup operation using matrixMul CUDA kernel
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if (block_size == 16) {
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MatrixMulCUDA<16> <<< grid, threads >>>(d_C, d_A, d_B,
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dimsA.x, dimsB.x);
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} else {
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MatrixMulCUDA<32> <<< grid, threads >>>(d_C, d_A, d_B,
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dimsA.x, dimsB.x);
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}
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printf("done\n");
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cudaDeviceSynchronize();
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// Allocate CUDA events that we'll use for timing
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cudaEvent_t start;
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checkCudaErrors(cudaEventCreate(&start));
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cudaEvent_t stop;
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checkCudaErrors(cudaEventCreate(&stop));
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// Record the start event
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checkCudaErrors(cudaEventRecord(start, NULL));
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// Execute the kernel
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int nIter = 300;
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for (int j = 0; j < nIter; j++) {
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if (block_size == 16) {
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MatrixMulCUDA<16> <<< grid, threads >>>(d_C, d_A, d_B,
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dimsA.x, dimsB.x);
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} else {
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MatrixMulCUDA<32> <<< grid, threads >>>(d_C, d_A, d_B,
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dimsA.x, dimsB.x);
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}
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}
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// Record the stop event
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checkCudaErrors(cudaEventRecord(stop, NULL));
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// Wait for the stop event to complete
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checkCudaErrors(cudaEventSynchronize(stop));
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float msecTotal = 0.0f;
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checkCudaErrors(cudaEventElapsedTime(&msecTotal, start, stop));
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// Compute and print the performance
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float msecPerMatrixMul = msecTotal / nIter;
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double flopsPerMatrixMul = 2.0 * static_cast<double>(dimsA.x) *
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static_cast<double>(dimsA.y) *
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static_cast<double>(dimsB.x);
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double gigaFlops = (flopsPerMatrixMul * 1.0e-9f) /
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(msecPerMatrixMul / 1000.0f);
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printf(
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"Performance= %.2f GFlop/s, Time= %.3f msec, Size= %.0f Ops," \
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" WorkgroupSize= %u threads/block\n",
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gigaFlops,
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msecPerMatrixMul,
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flopsPerMatrixMul,
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threads.x * threads.y);
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// Copy result from device to host
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checkCudaErrors(cudaMemcpy(h_C, d_C, mem_size_C, cudaMemcpyDeviceToHost));
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printf("Checking computed result for correctness: ");
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bool correct = true;
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// test relative error by the formula
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// |<x, y>_cpu - <x,y>_gpu|/<|x|, |y|> < eps
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double eps = 1.e-6; // machine zero
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for (int i = 0; i < static_cast<int>(dimsC.x * dimsC.y); i++) {
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double abs_err = fabs(h_C[i] - (dimsA.x * valB));
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double dot_length = dimsA.x;
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double abs_val = fabs(h_C[i]);
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double rel_err = abs_err / abs_val / dot_length;
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if (rel_err > eps) {
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printf("Error! Matrix[%05d]=%.8f, ref=%.8f error term is > %E\n",
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i, h_C[i], dimsA.x * valB, eps);
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correct = false;
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}
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}
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printf("%s\n", correct ? "Result = PASS" : "Result = FAIL");
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// Clean up memory
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free(h_A);
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free(h_B);
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free(h_C);
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checkCudaErrors(cudaFree(d_A));
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checkCudaErrors(cudaFree(d_B));
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checkCudaErrors(cudaFree(d_C));
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printf("\nNOTE: The CUDA Samples are not meant for performance"\
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"measurements. Results may vary when GPU Boost is enabled.\n");
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if (correct) {
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return EXIT_SUCCESS;
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} else {
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return EXIT_FAILURE;
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}
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}
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/**
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* Program main
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*/
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int main(int argc, char **argv) {
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printf("[Matrix Multiply Using CUDA] - Starting...\n");
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if (checkCmdLineFlag(argc, (const char **)argv, "help") ||
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checkCmdLineFlag(argc, (const char **)argv, "?")) {
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printf("Usage -device=n (n >= 0 for deviceID)\n");
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printf(" -wA=WidthA -hA=HeightA (Width x Height of Matrix A)\n");
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printf(" -wB=WidthB -hB=HeightB (Width x Height of Matrix B)\n");
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printf(" Note: Outer matrix dimensions of A & B matrices" \
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" must be equal.\n");
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exit(EXIT_SUCCESS);
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}
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// This will pick the best possible CUDA capable device, otherwise
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// override the device ID based on input provided at the command line
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int dev = findCudaDevice(argc, (const char **)argv);
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int block_size = 32;
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dim3 dimsA(5 * 2 * block_size, 5 * 2 * block_size, 1);
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dim3 dimsB(5 * 4 * block_size, 5 * 2 * block_size, 1);
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// width of Matrix A
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if (checkCmdLineFlag(argc, (const char **)argv, "wA")) {
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dimsA.x = getCmdLineArgumentInt(argc, (const char **)argv, "wA");
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}
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// height of Matrix A
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if (checkCmdLineFlag(argc, (const char **)argv, "hA")) {
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dimsA.y = getCmdLineArgumentInt(argc, (const char **)argv, "hA");
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}
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// width of Matrix B
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if (checkCmdLineFlag(argc, (const char **)argv, "wB")) {
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dimsB.x = getCmdLineArgumentInt(argc, (const char **)argv, "wB");
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}
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// height of Matrix B
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if (checkCmdLineFlag(argc, (const char **)argv, "hB")) {
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dimsB.y = getCmdLineArgumentInt(argc, (const char **)argv, "hB");
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}
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if (dimsA.x != dimsB.y) {
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printf("Error: outer matrix dimensions must be equal. (%d != %d)\n",
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dimsA.x, dimsB.y);
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exit(EXIT_FAILURE);
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}
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printf("MatrixA(%d,%d), MatrixB(%d,%d)\n", dimsA.x, dimsA.y,
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dimsB.x, dimsB.y);
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int matrix_result = MatrixMultiply(argc, argv, block_size, dimsA, dimsB);
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exit(matrix_result);
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}
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