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transpose-soln.c
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transpose-soln.c
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#include "timing.h"
#include "cl-helper.h"
int main(int argc, char **argv)
{
if (argc != 3)
{
fprintf(stderr, "need two arguments!\n");
abort();
}
const cl_long n = atol(argv[1]);
const cl_long size = n*n;
const int ntrips = atoi(argv[2]);
cl_context ctx;
cl_command_queue queue;
create_context_on("NVIDIA", "590", 0, &ctx, &queue, 0);
// --------------------------------------------------------------------------
// load kernels
// --------------------------------------------------------------------------
char *knl_text = read_file("transpose-soln.cl");
cl_kernel knl = kernel_from_string(ctx, knl_text, "transpose", NULL);
free(knl_text);
// --------------------------------------------------------------------------
// allocate and initialize CPU memory
// --------------------------------------------------------------------------
double *a = (double *) malloc(sizeof(double) * size);
if (!a) { perror("alloc x"); abort(); }
double *b = (double *) malloc(sizeof(double) * size);
if (!b) { perror("alloc y"); abort(); }
for (size_t j = 0; j < n; ++j)
for (size_t i = 0; i < n; ++i)
a[i + j*n] = i + j*n;
// --------------------------------------------------------------------------
// allocate device memory
// --------------------------------------------------------------------------
cl_int status;
cl_mem buf_a = clCreateBuffer(ctx, CL_MEM_READ_WRITE,
sizeof(double) * size, 0, &status);
CHECK_CL_ERROR(status, "clCreateBuffer");
cl_mem buf_b = clCreateBuffer(ctx, CL_MEM_READ_WRITE,
sizeof(double) * size, 0, &status);
CHECK_CL_ERROR(status, "clCreateBuffer");
// --------------------------------------------------------------------------
// transfer to device
// --------------------------------------------------------------------------
CALL_CL_GUARDED(clEnqueueWriteBuffer, (
queue, buf_a, /*blocking*/ CL_FALSE, /*offset*/ 0,
size * sizeof(double), a,
0, NULL, NULL));
CALL_CL_GUARDED(clEnqueueWriteBuffer, (
queue, buf_b, /*blocking*/ CL_FALSE, /*offset*/ 0,
size * sizeof(double), b,
0, NULL, NULL));
// --------------------------------------------------------------------------
// run code on device
// --------------------------------------------------------------------------
CALL_CL_GUARDED(clFinish, (queue));
timestamp_type time1, time2;
get_timestamp(&time1);
for (int trip = 0; trip < ntrips; ++trip)
{
SET_3_KERNEL_ARGS(knl, buf_a, buf_b, n);
size_t ldim[] = { 16, 16 };
size_t gdim[] = { n, n };
CALL_CL_GUARDED(clEnqueueNDRangeKernel,
(queue, knl,
/*dimensions*/ 2, NULL, gdim, ldim,
0, NULL, NULL));
}
CALL_CL_GUARDED(clFinish, (queue));
get_timestamp(&time2);
double elapsed = timestamp_diff_in_seconds(time1,time2)/ntrips;
printf("%f s\n", elapsed);
printf("%f GB/s\n",
2*size*sizeof(double)/1e9/elapsed);
CALL_CL_GUARDED(clEnqueueReadBuffer, (
queue, buf_b, /*blocking*/ CL_FALSE, /*offset*/ 0,
size * sizeof(double), b,
0, NULL, NULL));
CALL_CL_GUARDED(clFinish, (queue));
for (size_t i = 0; i < n; ++i)
for (size_t j = 0; j < n; ++j)
if (a[i + j*n] != b[j + i*n])
{
printf("bad %zd %zd\n", i, j);
abort();
}
// --------------------------------------------------------------------------
// clean up
// --------------------------------------------------------------------------
CALL_CL_GUARDED(clFinish, (queue));
CALL_CL_GUARDED(clReleaseMemObject, (buf_a));
CALL_CL_GUARDED(clReleaseMemObject, (buf_b));
CALL_CL_GUARDED(clReleaseKernel, (knl));
CALL_CL_GUARDED(clReleaseCommandQueue, (queue));
CALL_CL_GUARDED(clReleaseContext, (ctx));
return 0;
}