void update_halo_kernel2_yvel_minus_4_a_c_wrapper(double *p_a0, double *p_a1,
int *p_a2, int x_size,
int y_size) {
#ifdef OPS_GPU
#pragma acc parallel deviceptr(p_a0, p_a1, p_a2)
#pragma acc loop
#endif
for (int n_y = 0; n_y < y_size; n_y++) {
#ifdef OPS_GPU
#pragma acc loop
#endif
for (int n_x = 0; n_x < x_size; n_x++) {
update_halo_kernel2_yvel_minus_4_a(
p_a0 + n_x * 1 * 1 +
n_y * xdim0_update_halo_kernel2_yvel_minus_4_a * 1 * 1,
p_a1 + n_x * 1 * 1 +
n_y * xdim1_update_halo_kernel2_yvel_minus_4_a * 1 * 1,
p_a2);
}
}
}
// host stub function
void ops_par_loop_update_halo_kernel2_yvel_minus_4_a(char const *name, ops_block block, int dim, int* range,
ops_arg arg0, ops_arg arg1, ops_arg arg2) {
//Timing
double t1,t2,c1,c2;
ops_timers_core(&c1,&t1);
int offs[3][2];
ops_arg args[3] = { arg0, arg1, arg2};
#ifdef CHECKPOINTING
if (!ops_checkpointing_before(args,3,range,59)) return;
#endif
ops_timing_realloc(59,"update_halo_kernel2_yvel_minus_4_a");
OPS_kernels[59].count++;
//compute locally allocated range for the sub-block
int start[2];
int end[2];
#ifdef OPS_MPI
sub_block_list sb = OPS_sub_block_list[block->index];
if (!sb->owned) return;
for ( int n=0; n<2; n++ ){
start[n] = sb->decomp_disp[n];end[n] = sb->decomp_disp[n]+sb->decomp_size[n];
if (start[n] >= range[2*n]) {
start[n] = 0;
}
else {
start[n] = range[2*n] - start[n];
}
if (sb->id_m[n]==MPI_PROC_NULL && range[2*n] < 0) start[n] = range[2*n];
if (end[n] >= range[2*n+1]) {
end[n] = range[2*n+1] - sb->decomp_disp[n];
}
else {
end[n] = sb->decomp_size[n];
}
if (sb->id_p[n]==MPI_PROC_NULL && (range[2*n+1] > sb->decomp_disp[n]+sb->decomp_size[n]))
end[n] += (range[2*n+1]-sb->decomp_disp[n]-sb->decomp_size[n]);
}
#else //OPS_MPI
for ( int n=0; n<2; n++ ){
start[n] = range[2*n];end[n] = range[2*n+1];
}
#endif //OPS_MPI
#ifdef OPS_DEBUG
ops_register_args(args, "update_halo_kernel2_yvel_minus_4_a");
#endif
offs[0][0] = args[0].stencil->stride[0]*1; //unit step in x dimension
offs[0][1] = off2D(1, &start[0],
&end[0],args[0].dat->size, args[0].stencil->stride) - offs[0][0];
offs[1][0] = args[1].stencil->stride[0]*1; //unit step in x dimension
offs[1][1] = off2D(1, &start[0],
&end[0],args[1].dat->size, args[1].stencil->stride) - offs[1][0];
int off0_0 = offs[0][0];
int off0_1 = offs[0][1];
int dat0 = args[0].dat->elem_size;
int off1_0 = offs[1][0];
int off1_1 = offs[1][1];
int dat1 = args[1].dat->elem_size;
#ifdef _OPENMP
int nthreads = omp_get_max_threads( );
#else
int nthreads = 1;
#endif
xdim0 = args[0].dat->size[0]*args[0].dat->dim;
xdim1 = args[1].dat->size[0]*args[1].dat->dim;
ops_H_D_exchanges_host(args, 3);
//Halo Exchanges
ops_halo_exchanges(args,3,range);
ops_timers_core(&c2,&t2);
OPS_kernels[59].mpi_time += t2-t1;
#pragma omp parallel for
for ( int thr=0; thr<nthreads; thr++ ){
int y_size = end[1]-start[1];
char *p_a[3];
int start_i = start[1] + ((y_size-1)/nthreads+1)*thr;
int finish_i = start[1] + MIN(((y_size-1)/nthreads+1)*(thr+1),y_size);
//get address per thread
int start0 = start[0];
int start1 = start_i;
//set up initial pointers
int d_m[OPS_MAX_DIM];
#ifdef OPS_MPI
for (int d = 0; d < dim; d++) d_m[d] = args[0].dat->d_m[d] + OPS_sub_dat_list[args[0].dat->index]->d_im[d];
#else //OPS_MPI
for (int d = 0; d < dim; d++) d_m[d] = args[0].dat->d_m[d];
#endif //OPS_MPI
int base0 = dat0 * 1 *
(start0 * args[0].stencil->stride[0] - args[0].dat->base[0] - d_m[0]);
base0 = base0+ dat0 *
args[0].dat->size[0] *
(start1 * args[0].stencil->stride[1] - args[0].dat->base[1] - d_m[1]);
p_a[0] = (char *)args[0].data + base0;
#ifdef OPS_MPI
for (int d = 0; d < dim; d++) d_m[d] = args[1].dat->d_m[d] + OPS_sub_dat_list[args[1].dat->index]->d_im[d];
#else //OPS_MPI
for (int d = 0; d < dim; d++) d_m[d] = args[1].dat->d_m[d];
#endif //OPS_MPI
int base1 = dat1 * 1 *
(start0 * args[1].stencil->stride[0] - args[1].dat->base[0] - d_m[0]);
base1 = base1+ dat1 *
args[1].dat->size[0] *
(start1 * args[1].stencil->stride[1] - args[1].dat->base[1] - d_m[1]);
p_a[1] = (char *)args[1].data + base1;
p_a[2] = (char *)args[2].data;
for ( int n_y=start_i; n_y<finish_i; n_y++ ){
for ( int n_x=start[0]; n_x<start[0]+(end[0]-start[0])/SIMD_VEC; n_x++ ){
//call kernel function, passing in pointers to data -vectorised
#pragma simd
for ( int i=0; i<SIMD_VEC; i++ ){
update_halo_kernel2_yvel_minus_4_a( (double * )p_a[0]+ i*1, (double * )p_a[1]+ i*1, (int * )p_a[2] );
}
//shift pointers to data x direction
p_a[0]= p_a[0] + (dat0 * off0_0)*SIMD_VEC;
p_a[1]= p_a[1] + (dat1 * off1_0)*SIMD_VEC;
}
for ( int n_x=start[0]+((end[0]-start[0])/SIMD_VEC)*SIMD_VEC; n_x<end[0]; n_x++ ){
//call kernel function, passing in pointers to data - remainder
update_halo_kernel2_yvel_minus_4_a( (double * )p_a[0], (double * )p_a[1], (int * )p_a[2] );
//shift pointers to data x direction
p_a[0]= p_a[0] + (dat0 * off0_0);
p_a[1]= p_a[1] + (dat1 * off1_0);
}
//shift pointers to data y direction
p_a[0]= p_a[0] + (dat0 * off0_1);
p_a[1]= p_a[1] + (dat1 * off1_1);
}
}
ops_timers_core(&c1,&t1);
OPS_kernels[59].time += t1-t2;
ops_set_dirtybit_host(args, 3);
ops_set_halo_dirtybit3(&args[0],range);
ops_set_halo_dirtybit3(&args[1],range);
//Update kernel record
ops_timers_core(&c2,&t2);
OPS_kernels[59].mpi_time += t2-t1;
OPS_kernels[59].transfer += ops_compute_transfer(dim, range, &arg0);
OPS_kernels[59].transfer += ops_compute_transfer(dim, range, &arg1);
}
