212 lines
5.9 KiB
Plaintext
212 lines
5.9 KiB
Plaintext
#include "mat_mul.h"
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#include "util.h"
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#include <cstdio>
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#include <cuda_runtime.h>
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#define CUDA_CALL(f) \
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{ \
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cudaError_t err = (f); \
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if (err != cudaSuccess) { \
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fprintf(stderr, "CUDA error at [%s:%d] %d %s\n", __FILE__, __LINE__, \
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err, cudaGetErrorString(err)); \
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exit(1); \
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} \
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}
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#define TS 32
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#define WPT 16
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#define RTS (TS/WPT)
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#define MAX_NUM_GPU 4
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int num_devices = 0;
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__global__ void sgemm(float *A, float *B, float *C, int M, int N, int K) {
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const int row = threadIdx.x; // Local row ID (max: TS/WIDTH)
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const int col = threadIdx.y; // Local col ID (max: TS)
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const int globalRow = blockDim.x * WPT * blockIdx.x + row;
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const int globalCol = blockDim.y * blockIdx.y + col; // 0..N
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if (globalRow >= M || globalCol >= N) return;
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// Local memory to fit a tile of TS*TS elements of A and B
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__shared__ float Asub[TS][TS];
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__shared__ float Bsub[TS][TS];
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const int numTiles = K/TS;
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float sum[WPT];
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for (int w=0; w<WPT; w++) {
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sum[w] = 0.0f;
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}
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for (int t=0; t<numTiles; t++) {
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const int tiledRow = TS*t + row;
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const int tiledCol = TS*t + col;
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for (int w=0; w<WPT; w++) {
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Asub[row + w*RTS][col] = A[(globalRow + w*RTS) * K + tiledCol];
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Bsub[row + w*RTS][col] = B[(tiledRow + w*RTS) * N + globalCol];
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}
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// Synchronise to make sure the tile is loaded
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__syncthreads();
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// Perform the computation for a single tile
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for (int k=0; k<TS; k++) {
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for (int w=0; w<WPT; w++) {
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sum[w] += Asub[row + w*RTS][k] * Bsub[k][col];
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}
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}
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// Synchronise before loading the next tile
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__syncthreads();
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}
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// Store the final results in C
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for (int w=0; w<WPT; w++) {
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C[(globalRow + w*RTS) * N + globalCol] = sum[w];
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}
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}
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// Array of device (GPU) pointers
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static float *a_d[MAX_NUM_GPU];
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static float *b_d[MAX_NUM_GPU];
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static float *c_d[MAX_NUM_GPU];
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static int M, N, K;
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static int Mbegin[MAX_NUM_GPU], Mend[MAX_NUM_GPU];
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static float *A, *B, *C;
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static int CopyBuf = 0;
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void mat_mul(float *_A, float *_B, float *_C, int _M, int _N, int _K) {
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// Launch kernel on every GPU
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for (int i = 0; i < num_devices; i++) {
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dim3 blockDim(TS/WPT, TS, 1);
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dim3 gridDim(((Mend[i] - Mbegin[i]+TS-1)/TS), (N+TS-1)/TS, 1);
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CUDA_CALL( cudaSetDevice(i) );
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sgemm<<<gridDim, blockDim>>>(a_d[i], b_d[i], c_d[i], Mend[i] - Mbegin[i], N, K);
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}
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// DO NOT REMOVE; NEEDED FOR TIME MEASURE
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for (int i = 0; i < num_devices; i++) {
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CUDA_CALL( cudaDeviceSynchronize() );
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}
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}
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void mat_mul_init(float *_A, float *_B, float *_C, int _M, int _N, int _K) {
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// M = _M, N = _N, K = _K;
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M = (_M & (TS-1))? _M + (TS - (_M & (TS-1))) : _M;
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N = (_N & (TS-1))? _N + (TS - (_N & (TS-1))) : _N;
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K = (_K & (TS-1))? _K + (TS - (_K & (TS-1))) : _K;
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CopyBuf = 0;
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if(M == _M && K == _K){
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A = _A;
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}
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else{
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alloc_mat(&A, M, K);
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for (int i = 0; i < M; i++) {
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for (int j = 0; j < K; j++) {
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if(i<_M && j<_K)
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A[i * K + j] = _A[i * _K + j];
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else
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A[i * K + j] = 0;
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}
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}
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CopyBuf = 1;
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}
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if(K == _K && N == _N){
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B = _B;
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}
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else{
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alloc_mat(&B, K, N);
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for (int i = 0; i < K; i++) {
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for (int j = 0; j < N; j++) {
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if(i<_K && j<_N)
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B[i * N + j] = _B[i * _N + j];
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else
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B[i * N + j] = 0;
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}
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}
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CopyBuf = 1;
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}
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if(M == _M && N == _N){
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C = _C;
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}
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else{
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alloc_mat(&C, M, N);
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zero_mat(C, M, N);
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CopyBuf = 1;
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}
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/////////////////////////
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CUDA_CALL( cudaGetDeviceCount(&num_devices) );
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if(num_devices > MAX_NUM_GPU) num_devices = MAX_NUM_GPU;
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printf("Using %d devices\n", num_devices);
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for (int i = 0; i < num_devices; i++) {
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cudaDeviceProp prop;
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CUDA_CALL( cudaGetDeviceProperties(&prop, i) );
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// Try printing more detailed information here
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printf("[GPU %d] %s\n", i, prop.name);
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}
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if (num_devices <= 0) {
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printf("No CUDA device found. Aborting\n");
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exit(1);
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}
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// Setup problem size for each GPU
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for (int i = 0; i < num_devices; i++) {
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Mbegin[i] = (M / num_devices) * i;
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Mend[i] = (M / num_devices) * (i + 1);
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}
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Mend[num_devices - 1] = M;
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// Allocate device memory for each GPU
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for (int i = 0; i < num_devices; i++) {
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CUDA_CALL( cudaSetDevice(i) );
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CUDA_CALL( cudaMalloc(&a_d[i], (Mend[i] - Mbegin[i]) * K * sizeof(float)) );
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CUDA_CALL( cudaMalloc(&b_d[i], K * N * sizeof(float)) );
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CUDA_CALL( cudaMalloc(&c_d[i], (Mend[i] - Mbegin[i]) * N * sizeof(float)) );
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}
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// Upload A and B matrix to every GPU
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for (int i = 0; i < num_devices; i++) {
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CUDA_CALL( cudaMemcpy(a_d[i], A + Mbegin[i] * K,
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(Mend[i] - Mbegin[i]) * K * sizeof(float),
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cudaMemcpyHostToDevice) );
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CUDA_CALL( cudaMemcpy(b_d[i], B, K * N * sizeof(float), cudaMemcpyHostToDevice) );
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}
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// DO NOT REMOVE; NEEDED FOR TIME MEASURE
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for (int i = 0; i < num_devices; i++) {
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CUDA_CALL( cudaDeviceSynchronize() );
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}
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}
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void mat_mul_final(float *_A, float *_B, float *_C, int _M, int _N, int _K) {
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// Do any post-matmul cleanup work here.
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// Download C matrix from GPUs
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for (int i = 0; i < num_devices; i++) {
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CUDA_CALL( cudaMemcpy(C + Mbegin[i] * N, c_d[i],
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(Mend[i] - Mbegin[i]) * N * sizeof(float),
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cudaMemcpyDeviceToHost) );
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}
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if(CopyBuf == 1){
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for (int i = 0; i < _M; i++) {
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for (int j = 0; j < _N; j++) {
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_C[i * _N + j] = C[i * N + j];
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}
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}
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}
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// DO NOT REMOVE; NEEDED FOR TIME MEASURE
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for (int i = 0; i < num_devices; i++) {
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CUDA_CALL( cudaDeviceSynchronize() );
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}
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}
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