File size: 5,675 Bytes
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* gemm.cu: This file is part of the PolyBench/GPU 1.0 test suite.
*
*
* Contact: Scott Grauer-Gray <sgrauerg@gmail.com>
* Louis-Noel Pouchet <pouchet@cse.ohio-state.edu>
* Web address: http://www.cse.ohio-state.edu/~pouchet/software/polybench/GPU
*/
#include <unistd.h>
#include <stdio.h>
#include <time.h>
#include <sys/time.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include <cuda.h>
#include "../../../common/cupti_add.h"
#include "../../../common/cpu_timestamps.h"
#include <cooperative_groups.h>
#include <cooperative_groups/memcpy_async.h>
using namespace nvcuda::experimental;
#define PREFETCH_COUNT 2
#define SMALL_FLOAT_VAL 0.00000001f
double rtclock()
{
struct timezone Tzp;
struct timeval Tp;
uint64_t stat;
stat = gettimeofday(&Tp, &Tzp);
if (stat != 0)
printf("Error return from gettimeofday: %d", stat);
return (Tp.tv_sec + Tp.tv_usec * 1.0e-6);
}
float absVal(float a)
{
if (a < 0)
{
return (a * -1);
}
else
{
return a;
}
}
float percentDiff(double val1, double val2)
{
if ((absVal(val1) < 0.01) && (absVal(val2) < 0.01))
{
return 0.0f;
}
else
{
return 100.0f * (absVal(absVal(val1 - val2) / absVal(val1 + SMALL_FLOAT_VAL)));
}
}
//define the error threshold for the results "not matching"
#define PERCENT_DIFF_ERROR_THRESHOLD 0.005
/* Problem size */
#define SIZE 1073741824
#define ITER 100
uint64_t NI;
/* Thread block dimensions */
#ifndef DIM_THREAD_BLOCK
#define DIM_THREAD_BLOCK 256
#endif
#ifndef BATCH_SIZE
#define BATCH_SIZE 16
#endif
#ifndef NBLOCKS
#define NBLOCKS 64
#endif
#define LCG_A 1.1f
#define LCG_B 1.1f
/* Can switch DATA_TYPE between float and double */
typedef float DATA_TYPE;
// typedef uint64_t DATA_TYPE;
void saxpy(DATA_TYPE *A, uint64_t iterations)
{
for (uint64_t i = 0; i < NI; i++) {
for (uint64_t iter = 0; iter < iterations; iter++) {
A[i] = LCG_A * A[i] + LCG_B;
}
}
}
void init(DATA_TYPE *A, DATA_TYPE *A_ref)
{
for (uint64_t i = 0; i < NI; i++) {
A[i] = ((DATA_TYPE) i) / NI;
A_ref[i] = ((DATA_TYPE) i) / NI;
}
}
void compareResults(DATA_TYPE* A, DATA_TYPE* A_outputFromGpu)
{
uint64_t fail = 0;
// Compare C1 and C2
for (uint64_t i = 0; i < NI; i++) {
// printf("%lld, GPU is %f, CPU is %f.\n", i, A[i], A_outputFromGpu[i]);
if (percentDiff(A[i], A_outputFromGpu[i]) > PERCENT_DIFF_ERROR_THRESHOLD) {
fail++;
printf("%lld, GPU is %f, CPU is %f.\n", i, A[i], A_outputFromGpu[i]);
}
}
// Print results
printf("Non-Matching CPU-GPU Outputs Beyond Error Threshold of %4.2f Percent: %d\n", PERCENT_DIFF_ERROR_THRESHOLD, fail);
}
__global__ void vector_seq_kernel(DATA_TYPE *a, uint64_t NI, uint64_t iterations, uint64_t block_size)
{
// Compute each thread's global row and column index
const uint64_t mem_size = DIM_THREAD_BLOCK * BATCH_SIZE;
// __shared__ DATA_TYPE tmp[mem_size];
extern __shared__ DATA_TYPE tmp[];
uint64_t total_tiles = NI / mem_size;
uint64_t base_tiles = total_tiles / gridDim.x;
uint64_t tiles_this_block = block_size / mem_size;
uint64_t tile = base_tiles * blockIdx.x;
uint64_t end_tile = tile + tiles_this_block;
for (; tile < end_tile; tile += 1)
{
for (uint64_t i = threadIdx.x; i < mem_size; i += blockDim.x)
{
tmp[i] = a[tile * mem_size + i];
}
__syncthreads();
for (uint64_t i = threadIdx.x; i < mem_size; i += blockDim.x)
{
for (uint64_t iter = 0; iter < iterations; iter++)
{
tmp[i] = LCG_A * tmp[i] + LCG_B;
}
}
for (uint64_t i = threadIdx.x; i < mem_size; i += blockDim.x)
{
a[tile * mem_size + i] = tmp[i];
}
}
}
void saxpyCuda(DATA_TYPE *A, DATA_TYPE *A_gpu, uint64_t iterations, uint64_t block_size)
{
double t_start, t_end;
if (block_size <= DIM_THREAD_BLOCK)
block_size = DIM_THREAD_BLOCK;
dim3 block(DIM_THREAD_BLOCK);
dim3 grid(NI / block_size);
int MaxBytesofSharedMemory = DIM_THREAD_BLOCK * BATCH_SIZE * sizeof(DATA_TYPE);
cudaFuncSetAttribute(vector_seq_kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, MaxBytesofSharedMemory);
//t_start = rtclock();
cudaMemcpy(A_gpu, A, NI * sizeof(DATA_TYPE), cudaMemcpyHostToDevice);
vector_seq_kernel<<<grid, block, MaxBytesofSharedMemory>>>(A_gpu, NI, iterations, block_size);
cudaDeviceSynchronize();
cudaMemcpy(A, A_gpu, NI * sizeof(DATA_TYPE), cudaMemcpyDeviceToHost);
//t_end = rtclock();
//fprintf(stdout, "GPU Runtime: %0.6lfs\n", t_end - t_start);
}
int main(int argc, char *argv[])
{
uint64_t start_tsc = rdtsc();
uint64_t start_tsp = rdtsp();
printf("start_tsc %lu start_tsp %lu\n", start_tsc, start_tsp);
uint64_t iterations = ITER;
uint64_t block_size = DIM_THREAD_BLOCK * BATCH_SIZE;
if (argc >= 4) {
NI = atoll(argv[1]);
iterations = atoi(argv[2]);
block_size = atoi(argv[3]);
}
else {
NI = SIZE;
iterations = ITER;
block_size = DIM_THREAD_BLOCK * BATCH_SIZE;
}
int nblocks = NBLOCKS;
block_size = NI / nblocks;
double t_start, t_end;
DATA_TYPE* A;
DATA_TYPE *A_ref;
DATA_TYPE *A_gpu;
A = (DATA_TYPE*)malloc(NI*sizeof(DATA_TYPE));
A_ref = (DATA_TYPE *)malloc(NI*sizeof(DATA_TYPE));
//cudaMallocManaged(&A_gpu, sizeof(DATA_TYPE) * NI * NK);
//cudaMallocManaged(&B_gpu, sizeof(DATA_TYPE) * NK * NJ);
//cudaMallocManaged(&C_gpu, sizeof(DATA_TYPE) * NI * NJ);
init(A, A_ref);
GPU_argv_init();
initTrace();
startCPU();
cudaMalloc(&A_gpu, sizeof(DATA_TYPE) * NI);
saxpyCuda(A, A_gpu, iterations, block_size);
cudaFree(A_gpu);
endCPU();
finiTrace();
// t_start = rtclock();
// saxpy(A_ref, iterations);
// t_end = rtclock();
// fprintf(stdout, "CPU Runtime: %0.6lfs\n", t_end - t_start);
// compareResults(A, A_ref);
free(A);
free(A_ref);
return 0;
}
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