/
neigh2d_kern.cl
744 lines (624 loc) · 26.9 KB
/
neigh2d_kern.cl
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/* Copyright 2013-19. Triad National Security, LLC. This material was produced
* under U.S. Government contract 89233218CNA000001 for Los Alamos National
* Laboratory (LANL), which is operated by Triad National Security, LLC
* for the U.S. Department of Energy. The U.S. Government has rights to use,
* reproduce, and distribute this software. NEITHER THE GOVERNMENT NOR
* TRIAD NATIONAL SECURITY, LLC MAKES ANY WARRANTY, EXPRESS OR IMPLIED, OR
* ASSUMES ANY LIABILITY FOR THE USE OF THIS SOFTWARE. If software is modified
* to produce derivative works, such modified software should be clearly marked,
* so as not to confuse it with the version available from LANL.
*
* Licensed under the Apache License, Version 2.0 (the "License"); you may not
* use this file except in compliance with the License. You may obtain a copy
* of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software distributed
* under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR
* CONDITIONS OF ANY KIND, either express or implied. See the License for the
* specific language governing permissions and limitations under the License.
*
* Under this license, it is required to include a reference to this work. We
* request that each derivative work contain a reference to LANL Copyright
* Disclosure C14043/LA-CC-14-003 so that this work's impact can be roughly
* measured.
*
* This is LANL Copyright Disclosure C14043/LA-CC-14-003
*/
/*
* Authors: Bob Robey XCP-2 brobey@lanl.gov
* Peter Ahrens XCP-2 peter.ahrens@lanl.gov, ptrahrens@gmail.com
* Sara Hartse XCP-2 sara@lanl.gov,
* Rebecka Tumblin rtumblin@lanl.gov, rebeckatumblin@gmail.com
*/
/* neigh2d_kern.cl */
#ifndef __HAVE_CL_DOUBLE_DEFINED__
#define __HAVE_CL_DOUBLE_DEFINED__
#ifdef HAVE_CL_DOUBLE
#pragma OPENCL EXTENSION cl_khr_fp64 : enable
typedef double real;
#else
typedef float real;
#endif
#endif
struct neighbor2d {
int left;
int right;
int bottom;
int top;
};
__kernel void init_kern(const uint size,
__global int *temp) {
const uint idx = get_global_id(0);
if (idx >= size) return;
temp[idx] = -1;
}
__kernel void hash_kern(const real min_val,
const real min_diff,
const uint length,
__global const real *arr,
__global int *temp){
const uint idx = get_global_id(0);
if(idx >= length) return;
temp[(uint)((arr[idx]-min_val)/min_diff)] = idx;
}
#define hashval(j,i) hash[(j)*imaxsize+(i)]
#define MIN(a,b) ((a)>(b)?(b):(a))
#define MAX(a,b) ((a)<(b)?(b):(a))
__kernel void neighbors2d_hashwrite_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global int *hash) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
int levdiff = levmx - lev;
int iimin = ii *levtable[levdiff];
int iimax = (ii+1)*levtable[levdiff];
int jjmin = jj *levtable[levdiff];
int jjmax = (jj+1)*levtable[levdiff];
for ( int jjj = jjmin; jjj < jjmax; jjj++) {
for (int iii = iimin; iii < iimax; iii++) {
hashval(jjj, iii) = giX;
}
}
}
__kernel void neighbors2d_hashwrite_opt_1_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global int *hash){
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
int levdiff = levmx - lev;
int iimin = ii *levtable[levdiff];
int iimax = (ii+1)*levtable[levdiff];
int jjmin = jj *levtable[levdiff];
int jjmax = (jj+1)*levtable[levdiff];
for (int iii = iimin; iii < iimax; iii++) {
hashval(jjmin, iii) = giX;
hashval(jjmax-1, iii) = giX;
}
for (int jjj = jjmin+1; jjj < jjmax-1; jjj++) {
hashval(jjj, iimin) = giX;
hashval(jjj, iimax-1) = giX;
}
}
__kernel void neighbors2d_hashwrite_opt_2_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global int *hash) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
//int levdiff = levmx - lev;
int levmult = levtable[levmx - lev];
//int iimin = ii *levtable[levdiff];
//int iimax = (ii+1)*levtable[levdiff];
//int jjmin = jj *levtable[levdiff];
//int jjmax = (jj+1)*levtable[levdiff];
if(lev == (int)levmx) {
hashval(jj,ii) = giX;
return;
}
jj *= levmult;
ii *= levmult;
hashval(jj,ii) = giX;
ii += levmult/2;
hashval(jj,ii) = giX;
if(levmult > 2) {
ii += levmult/2 - 1;
hashval(jj,ii) = giX;
ii -= levmult/2 - 1;
}
ii -= levmult/2;
jj += levmult/2;
hashval(jj,ii) = giX;
ii += levmult - 1;
hashval(jj,ii) = giX;
if(levmult > 2) {
ii -= levmult - 1;
jj += levmult/2 - 1;
hashval(jj,ii) = giX;
ii += levmult/2;
hashval(jj,ii) = giX;
}
}
__kernel void neighbors2d_hashwrite_opt_3_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global int *hash) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
//int levdiff = levmx - lev;
int levmult = levtable[levmx - lev];
//int iimin = ii *levtable[levdiff];
//int iimax = (ii+1)*levtable[levdiff];
//int jjmin = jj *levtable[levdiff];
//int jjmax = (jj+1)*levtable[levdiff];
jj *= levmult;
ii *= levmult;
hashval(jj,ii) = giX;
}
__kernel void neighbors2d_hasholdlibwrite_opt_3_kern(const int isize,
const int levmx,
const int imaxsize,
const int hash_method,
const ulong hash_table_size,
const ulong AA,
const ulong BB,
__global const int *levtable,
__global const int *level,
__global const int *i,
__global const int *j,
__global int *hash){
const uint giX = get_global_id(0);
if ((int)giX >= isize) return;
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
int levmult = levtable[levmx - lev];
jj *= levmult;
ii *= levmult;
write_hash(hash_method, hash_table_size, AA, BB, giX, jj*imaxsize+ii, hash);
}
__kernel void neighbors2d_hashread_kern(const int isize,
const uint mesh_size,
const int levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global const int *hash,
__global struct neighbor2d *neigh2d) {
const uint giX = get_global_id(0);
if ((int)giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int jmaxsize = mesh_size*levtable[levmx];
int ii = i[giX];
int jj = j[giX];
int lev = level[giX];
int levmult = levtable[levmx-lev];
int nlftval = hashval( jj *levmult , MAX( ii *levmult-1, 0 ));
int nrhtval = hashval( jj *levmult , MIN( (ii+1)*levmult, imaxsize-1));
int nbotval = hashval(MAX( jj *levmult-1, 0) , ii *levmult );
int ntopval = hashval(MIN( (jj+1)*levmult, jmaxsize-1), ii *levmult );
neigh2d[giX].left = nlftval;
neigh2d[giX].right = nrhtval;
neigh2d[giX].bottom = nbotval;
neigh2d[giX].top = ntopval;
}
__kernel void neighbors2d_hashread_opt_3_kern(const int isize,
const uint mesh_size,
const int levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global const int *hash,
__global struct neighbor2d *neigh2d) {
const uint giX = get_global_id(0);
if ((int)giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int jmaxsize = mesh_size*levtable[levmx];
int imax = mesh_size;
int jmax = mesh_size;
int ii = i[giX];
int jj = j[giX];
int lev = level[giX];
int levmult = levtable[levmx-lev];
int iicur = ii*levmult;
int iilft = MAX( (ii-1)*levmult, 0 );
int iirht = MIN( (ii+1)*levmult, imaxsize-1);
int jjcur = jj*levmult;
int jjbot = MAX( (jj-1)*levmult, 0 );
int jjtop = MIN( (jj+1)*levmult, jmaxsize-1);
int nlftval = -1;
int nrhtval = -1;
int nbotval = -1;
int ntopval = -1;
// Taking care of boundary cells
// Force each boundary cell to point to itself on its boundary direction
if (iicur < 1 ) nlftval = giX;
if (jjcur < 1 ) nbotval = giX;
if ((ii + 1)*levmult >(imax)*levtable[levmx]-1) nrhtval = giX;
if ((jj + 1)*levmult >(jmax)*levtable[levmx]-1) ntopval = giX;
// Need to check for finer neighbor first
// Right and top neighbor don't change for finer, so drop through to same size
// Left and bottom need to be half of same size index for finer test
if (lev != levmx) {
int iilftfiner = iicur-(iicur-iilft)/2;
int jjbotfiner = jjcur-(jjcur-jjbot)/2;
if (nlftval < 0) nlftval = hashval(jjcur, iilftfiner);
if (nbotval < 0) nbotval = hashval(jjbotfiner,iicur);
}
// same size neighbor
if (nlftval < 0) nlftval = hashval(jjcur,iilft);
if (nrhtval < 0) nrhtval = hashval(jjcur,iirht);
if (nbotval < 0) nbotval = hashval(jjbot,iicur);
if (ntopval < 0) ntopval = hashval(jjtop,iicur);
// coarser neighbor
if (lev != 0){
if (nlftval < 0) {
iilft -= iicur-iilft;
int jjlft = (jj/2)*2*levmult;
nlftval = hashval(jjlft,iilft);
}
if (nrhtval < 0) {
int jjrht = (jj/2)*2*levmult;
nrhtval = hashval(jjrht,iirht);
}
if (nbotval < 0) {
jjbot -= jjcur-jjbot;
int iibot = (ii/2)*2*levmult;
nbotval = hashval(jjbot,iibot);
}
if (ntopval < 0) {
int iitop = (ii/2)*2*levmult;
ntopval = hashval(jjtop,iitop);
}
}
neigh2d[giX].left = nlftval;
neigh2d[giX].right = nrhtval;
neigh2d[giX].bottom = nbotval;
neigh2d[giX].top = ntopval;
}
__kernel void neighbors2d_hasholdlibread_opt_3_kern(const int isize,
const uint mesh_size,
const int levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global const int *hash,
__global struct neighbor2d *neigh2d,
const int hash_method,
const ulong hash_table_size,
const ulong AA,
const ulong BB) {
const uint giX = get_global_id(0);
if ((int)giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int jmaxsize = mesh_size*levtable[levmx];
int imax = mesh_size;
int jmax = mesh_size;
int ii = i[giX];
int jj = j[giX];
int lev = level[giX];
int levmult = levtable[levmx-lev];
int iicur = ii*levmult;
int iilft = MAX( (ii-1)*levmult, 0 );
int iirht = MIN( (ii+1)*levmult, imaxsize-1);
int jjcur = jj*levmult;
int jjbot = MAX( (jj-1)*levmult, 0 );
int jjtop = MIN( (jj+1)*levmult, jmaxsize-1);
int nlftval = -1;
int nrhtval = -1;
int nbotval = -1;
int ntopval = -1;
// Taking care of boundary cells
// Force each boundary cell to point to itself on its boundary direction
if (iicur < 1 ) nlftval = giX;
if (jjcur < 1 ) nbotval = giX;
if ((ii + 1)*levmult >(imax)*levtable[levmx]-1) nrhtval = giX;
if ((jj + 1)*levmult >(jmax)*levtable[levmx]-1) ntopval = giX;
// Need to check for finer neighbor first
// Right and top neighbor don't change for finer, so drop through to same size
// Left and bottom need to be half of same size index for finer test
if (lev != levmx) {
int iilftfiner = iicur-(iicur-iilft)/2;
int jjbotfiner = jjcur-(jjcur-jjbot)/2;
if (nlftval < 0) nlftval = read_hash(hash_method, hash_table_size, AA, BB, jjcur *imaxsize+iilftfiner, hash);
if (nbotval < 0) nbotval = read_hash(hash_method, hash_table_size, AA, BB, jjbotfiner*imaxsize+iicur, hash);
}
// same size neighbor
if (nlftval < 0) nlftval = read_hash(hash_method, hash_table_size, AA, BB, jjcur*imaxsize+iilft, hash);
if (nrhtval < 0) nrhtval = read_hash(hash_method, hash_table_size, AA, BB, jjcur*imaxsize+iirht, hash);
if (nbotval < 0) nbotval = read_hash(hash_method, hash_table_size, AA, BB, jjbot*imaxsize+iicur, hash);
if (ntopval < 0) ntopval = read_hash(hash_method, hash_table_size, AA, BB, jjtop*imaxsize+iicur, hash);
// coarser neighbor
if (lev != 0){
if (nlftval < 0) {
iilft -= iicur-iilft;
int jjlft = (jj/2)*2*levmult;
nlftval = read_hash(hash_method, hash_table_size, AA, BB, jjlft*imaxsize+iilft, hash);
}
if (nrhtval < 0) {
int jjrht = (jj/2)*2*levmult;
nrhtval = read_hash(hash_method, hash_table_size, AA, BB, jjrht*imaxsize+iirht, hash);
}
if (nbotval < 0) {
jjbot -= jjcur-jjbot;
int iibot = (ii/2)*2*levmult;
nbotval = read_hash(hash_method, hash_table_size, AA, BB, jjbot*imaxsize+iibot, hash);
}
if (ntopval < 0) {
int iitop = (ii/2)*2*levmult;
ntopval = read_hash(hash_method, hash_table_size, AA, BB, jjtop*imaxsize+iitop, hash);
}
}
neigh2d[giX].left = nlftval;
neigh2d[giX].right = nrhtval;
neigh2d[giX].bottom = nbotval;
neigh2d[giX].top = ntopval;
}
__kernel void neighbors2d_hashlibwrite_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global char *hashTableData) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
int levdiff = levmx - lev;
int iimin = ii *levtable[levdiff];
int iimax = (ii+1)*levtable[levdiff];
int jjmin = jj *levtable[levdiff];
int jjmax = (jj+1)*levtable[levdiff];
for ( int jjj = jjmin; jjj < jjmax; jjj++) {
for (int iii = iimin; iii < iimax; iii++) {
intintHash_InsertSingle(hashTableData, jjj*imaxsize+iii, giX);
}
}
}
__kernel void neighbors2d_hashlibwrite_opt_1_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global char *hashTableData) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
int levdiff = levmx - lev;
int iimin = ii *levtable[levdiff];
int iimax = (ii+1)*levtable[levdiff];
int jjmin = jj *levtable[levdiff];
int jjmax = (jj+1)*levtable[levdiff];
if (lev == (int)levmx) {
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
}else{
int width = levtable[levmx-lev] - 1;
for(int x = 0; x < width; x++){
intintHash_InsertSingle(hashTableData, (iimin + x ) + (jjmin ) * imaxsize, giX);
intintHash_InsertSingle(hashTableData, (iimin + x + 1) + (jjmin + width) * imaxsize, giX);
intintHash_InsertSingle(hashTableData, (iimin + width) + (jjmin + x ) * imaxsize, giX);
intintHash_InsertSingle(hashTableData, (iimin ) + (jjmin + x + 1) * imaxsize, giX);
}
}
return;
for (int iii = iimin; iii < iimax; iii++) {
intintHash_InsertSingle(hashTableData, jjmin*imaxsize+iii, giX);
intintHash_InsertSingle(hashTableData, (jjmax-1)*imaxsize+iii, giX);
}
for (int jjj = jjmin+1; jjj < jjmax-1; jjj++) {
intintHash_InsertSingle(hashTableData, jjj*imaxsize+iimin, giX);
intintHash_InsertSingle(hashTableData, jjj*imaxsize+iimax-1, giX);
}
return;
}
__kernel void neighbors2d_hashlibwrite_opt_2_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global char *hashTableData) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
//int levdiff = levmx - lev;
int levmult = levtable[levmx - lev];
//int iimin = ii *levtable[levdiff];
//int iimax = (ii+1)*levtable[levdiff];
//int jjmin = jj *levtable[levdiff];
//int jjmax = (jj+1)*levtable[levdiff];
if(lev == (int)levmx) {
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
return;
}
jj *= levmult;
ii *= levmult;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
ii += levmult/2;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
if(levmult > 2) {
ii += levmult/2 - 1;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
ii -= levmult/2 - 1;
}
ii -= levmult/2;
jj += levmult/2;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
ii += levmult - 1;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
if(levmult > 2) {
ii -= levmult - 1;
jj += levmult/2 - 1;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
ii += levmult/2;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
}
}
__kernel void neighbors2d_hashlibwrite_opt_3_kern(const uint isize,
const uint mesh_size,
const uint levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global char *hashTableData) {
const uint giX = get_global_id(0);
if (giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int lev = level[giX];
int ii = i[giX];
int jj = j[giX];
//int levdiff = levmx - lev;
int levmult = levtable[levmx - lev];
//int iimin = ii *levtable[levdiff];
//int iimax = (ii+1)*levtable[levdiff];
//int jjmin = jj *levtable[levdiff];
//int jjmax = (jj+1)*levtable[levdiff];
jj *= levmult;
ii *= levmult;
intintHash_InsertSingle(hashTableData, jj * imaxsize + ii, giX);
}
__kernel void neighbors2d_hashlibread_opt_3_kern(const int isize,
const uint mesh_size,
const int levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global char *hashTableData,
__global struct neighbor2d *neigh2d) {
const uint giX = get_global_id(0);
if ((int)giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int jmaxsize = mesh_size*levtable[levmx];
int imax = mesh_size;
int jmax = mesh_size;
int ii = i[giX];
int jj = j[giX];
int lev = level[giX];
int levmult = levtable[levmx-lev];
int iicur = ii*levmult;
int iilft = MAX( (ii-1)*levmult, 0 );
int iirht = MIN( (ii+1)*levmult, imaxsize-1);
int jjcur = jj*levmult;
int jjbot = MAX( (jj-1)*levmult, 0 );
int jjtop = MIN( (jj+1)*levmult, jmaxsize-1);
neigh2d[giX].left = -1;
neigh2d[giX].right = -1;
neigh2d[giX].bottom = -1;
neigh2d[giX].top = -1;
// Taking care of boundary cells
// Force each boundary cell to point to itself on its boundary direction
if (iicur < 1 ) neigh2d[giX].left = giX;
if (jjcur < 1 ) neigh2d[giX].bottom = giX;
if ((ii + 1)*levmult >(imax)*levtable[levmx]-1) neigh2d[giX].right = giX;
if ((jj + 1)*levmult >(jmax)*levtable[levmx]-1) neigh2d[giX].top = giX;
// Need to check for finer neighbor first
// Right and top neighbor don't change for finer, so drop through to same size
// Left and bottom need to be half of same size index for finer test
if (lev != levmx) {
int iilftfiner = iicur-(iicur-iilft)/2;
int jjbotfiner = jjcur-(jjcur-jjbot)/2;
if (neigh2d[giX].left == -1) intintHash_QuerySingle(hashTableData, iilftfiner + jjcur * imaxsize, &neigh2d[giX].left);
if (neigh2d[giX].bottom == -1) intintHash_QuerySingle(hashTableData, iicur + jjbotfiner * imaxsize, &neigh2d[giX].bottom);
}
// same size neighbor
if (neigh2d[giX].left == -1) intintHash_QuerySingle(hashTableData, iilft + jjcur * imaxsize, &neigh2d[giX].left);
if (neigh2d[giX].right == -1) intintHash_QuerySingle(hashTableData, iirht + jjcur * imaxsize, &neigh2d[giX].right);
if (neigh2d[giX].bottom == -1) intintHash_QuerySingle(hashTableData, iicur + jjbot * imaxsize, &neigh2d[giX].bottom);
if (neigh2d[giX].top == -1) intintHash_QuerySingle(hashTableData, iicur + jjtop * imaxsize, &neigh2d[giX].top);
// coarser neighbor
if (lev != 0){
if (neigh2d[giX].left == -1) {
iilft -= iicur-iilft;
int jjlft = (jj/2)*2*levmult;
intintHash_QuerySingle(hashTableData, iilft + jjlft * imaxsize, &neigh2d[giX].left);
}
if (neigh2d[giX].right == -1) {
int jjrht = (jj/2)*2*levmult;
intintHash_QuerySingle(hashTableData, iirht + jjrht * imaxsize, &neigh2d[giX].right);
}
if (neigh2d[giX].bottom == -1) {
jjbot -= jjcur-jjbot;
int iibot = (ii/2)*2*levmult;
intintHash_QuerySingle(hashTableData, iibot + jjbot * imaxsize, &neigh2d[giX].bottom);
}
if (neigh2d[giX].top == -1) {
int iitop = (ii/2)*2*levmult;
intintHash_QuerySingle(hashTableData, iitop + jjtop * imaxsize, &neigh2d[giX].top);
}
}
}
__kernel void neighbors2d_hashlibread_kern(const int isize,
const uint mesh_size,
const int levmx,
__global const int *levtable,
__global const int *i,
__global const int *j,
__global const int *level,
__global char *hashTableData,
__global struct neighbor2d *neigh2d) {
const uint giX = get_global_id(0);
if ((int)giX >= isize) return;
int imaxsize = mesh_size*levtable[levmx];
int jmaxsize = mesh_size*levtable[levmx];
int ii = i[giX];
int jj = j[giX];
int lev = level[giX];
int levmult = levtable[levmx-lev];
intintHash_QuerySingle(hashTableData, (MAX( ii *levmult-1, 0 )) + ( jj *levmult ) * imaxsize, &neigh2d[giX].left);
intintHash_QuerySingle(hashTableData, (MIN( (ii+1)*levmult, imaxsize-1)) + ( jj *levmult ) * imaxsize, &neigh2d[giX].right);
intintHash_QuerySingle(hashTableData, ( ii *levmult ) + (MAX( jj *levmult-1, 0) ) * imaxsize, &neigh2d[giX].bottom);
intintHash_QuerySingle(hashTableData, ( ii *levmult ) + (MIN( (jj+1)*levmult, jmaxsize-1)) * imaxsize, &neigh2d[giX].top);
}