#define STORE_DERIVATIVE_1(INDEX) ATOMIC_ADD(&derivBuffers[offset+(INDEX-1)*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(deriv##INDEX##_1)); #define STORE_DERIVATIVE_2(INDEX) ATOMIC_ADD(&derivBuffers[offset+(INDEX-1)*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(local_deriv##INDEX[tgx])); /** * Compute a force based on pair interactions. */ KERNEL void computeN2Energy( GLOBAL mm_ulong* RESTRICT forceBuffers, GLOBAL mixed* RESTRICT energyBuffer, GLOBAL const real4* RESTRICT posq, GLOBAL const unsigned int* RESTRICT exclusions, GLOBAL const int2* exclusionTiles, int needEnergy, #ifdef USE_CUTOFF GLOBAL const int* RESTRICT tiles, GLOBAL const unsigned int* RESTRICT interactionCount, real4 periodicBoxSize, real4 invPeriodicBoxSize, real4 periodicBoxVecX, real4 periodicBoxVecY, real4 periodicBoxVecZ, unsigned int maxTiles, GLOBAL const real4* RESTRICT blockCenter, GLOBAL const real4* RESTRICT blockSize, GLOBAL const int* RESTRICT interactingAtoms #else unsigned int numTiles #endif PARAMETER_ARGUMENTS) { mixed energy = 0; INIT_PARAM_DERIVS LOCAL real3 local_pos[LOCAL_BUFFER_SIZE]; LOCAL real3 local_force[LOCAL_BUFFER_SIZE]; ATOM_PARAMETER_DATA // First loop: process tiles that contain exclusions. const int firstExclusionTile = FIRST_EXCLUSION_TILE+GROUP_ID*(LAST_EXCLUSION_TILE-FIRST_EXCLUSION_TILE)/NUM_GROUPS; const int lastExclusionTile = FIRST_EXCLUSION_TILE+(GROUP_ID+1)*(LAST_EXCLUSION_TILE-FIRST_EXCLUSION_TILE)/NUM_GROUPS; for (int pos = firstExclusionTile; pos < lastExclusionTile; pos++) { const int2 tileIndices = exclusionTiles[pos]; const unsigned int x = tileIndices.x; const unsigned int y = tileIndices.y; // Load the data for this tile. for (int localAtomIndex = 0; localAtomIndex < TILE_SIZE; localAtomIndex++) { unsigned int j = y*TILE_SIZE + localAtomIndex; local_pos[localAtomIndex] = trimTo3(posq[j]); LOAD_LOCAL_PARAMETERS_FROM_GLOBAL } if (x == y) { // This tile is on the diagonal. for (unsigned int tgx = 0; tgx < TILE_SIZE; tgx++) { #ifdef USE_EXCLUSIONS unsigned int excl = exclusions[pos*TILE_SIZE+tgx]; #endif unsigned int atom1 = x*TILE_SIZE+tgx; real4 force = 0; DECLARE_ATOM1_DERIVATIVES real3 pos1 = trimTo3(posq[atom1]); LOAD_ATOM1_PARAMETERS for (unsigned int j = 0; j < TILE_SIZE; j++) { real3 pos2 = local_pos[j]; real3 delta = make_real3(pos2.x-pos1.x, pos2.y-pos1.y, pos2.z-pos1.z); #ifdef USE_PERIODIC APPLY_PERIODIC_TO_DELTA(delta) #endif real r2 = dot(delta, delta); #ifdef USE_CUTOFF if (r2 < CUTOFF_SQUARED) { #endif real invR = RSQRT(r2); real r = r2*invR; unsigned int atom2 = j; LOAD_ATOM2_PARAMETERS atom2 = y*TILE_SIZE+j; real dEdR = 0; real tempEnergy = 0; const real interactionScale = 0.5f; #ifdef USE_EXCLUSIONS bool isExcluded = !(excl & 0x1); #endif if (atom1 < NUM_ATOMS && atom2 < NUM_ATOMS && atom1 != atom2) { COMPUTE_INTERACTION dEdR /= -r; } energy += 0.5f*tempEnergy; delta *= dEdR; force.x -= delta.x; force.y -= delta.y; force.z -= delta.z; #ifdef USE_CUTOFF } #endif #ifdef USE_EXCLUSIONS excl >>= 1; #endif } // Write results. unsigned int offset = atom1; ATOMIC_ADD(&forceBuffers[offset], (mm_ulong) realToFixedPoint(force.x)); ATOMIC_ADD(&forceBuffers[offset+PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.y)); ATOMIC_ADD(&forceBuffers[offset+2*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.z)); STORE_DERIVATIVES_1 } } else { // This is an off-diagonal tile. for (int localAtomIndex = 0; localAtomIndex < TILE_SIZE; localAtomIndex++) { local_force[localAtomIndex] = 0; CLEAR_LOCAL_DERIVATIVES } for (unsigned int tgx = 0; tgx < TILE_SIZE; tgx++) { #ifdef USE_EXCLUSIONS unsigned int excl = exclusions[pos*TILE_SIZE+tgx]; #endif unsigned int atom1 = x*TILE_SIZE+tgx; real4 force = 0; DECLARE_ATOM1_DERIVATIVES real3 pos1 = trimTo3(posq[atom1]); LOAD_ATOM1_PARAMETERS for (unsigned int j = 0; j < TILE_SIZE; j++) { real3 pos2 = local_pos[j]; real3 delta = make_real3(pos2.x-pos1.x, pos2.y-pos1.y, pos2.z-pos1.z); #ifdef USE_PERIODIC APPLY_PERIODIC_TO_DELTA(delta) #endif real r2 = dot(delta.xyz, delta.xyz); #ifdef USE_CUTOFF if (r2 < CUTOFF_SQUARED) { #endif real invR = RSQRT(r2); real r = r2*invR; unsigned int atom2 = j; LOAD_ATOM2_PARAMETERS atom2 = y*TILE_SIZE+j; real dEdR = 0; real tempEnergy = 0; const real interactionScale = 1.0f; #ifdef USE_EXCLUSIONS bool isExcluded = (atom1 >= NUM_ATOMS || atom2 >= NUM_ATOMS || !(excl & 0x1)); if (!isExcluded) { #else if (atom1 < NUM_ATOMS && atom2 < NUM_ATOMS) { #endif COMPUTE_INTERACTION dEdR /= -r; } energy += tempEnergy; delta *= dEdR; force.x -= delta.x; force.y -= delta.y; force.z -= delta.z; atom2 = j; local_force[atom2].xyz += delta.xyz; RECORD_DERIVATIVE_2 #ifdef USE_CUTOFF } #endif #ifdef USE_EXCLUSIONS excl >>= 1; #endif } // Write results for atom1. unsigned int offset = atom1; ATOMIC_ADD(&forceBuffers[offset], (mm_ulong) realToFixedPoint(force.x)); ATOMIC_ADD(&forceBuffers[offset+PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.y)); ATOMIC_ADD(&forceBuffers[offset+2*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.z)); STORE_DERIVATIVES_1 } // Write results. for (int tgx = 0; tgx < TILE_SIZE; tgx++) { unsigned int offset = y*TILE_SIZE+tgx; ATOMIC_ADD(&forceBuffers[offset], (mm_ulong) realToFixedPoint(local_force[tgx].x)); ATOMIC_ADD(&forceBuffers[offset+PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(local_force[tgx].y)); ATOMIC_ADD(&forceBuffers[offset+2*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(local_force[tgx].z)); STORE_DERIVATIVES_2 } } } // Second loop: tiles without exclusions, either from the neighbor list (with cutoff) or just enumerating all // of them (no cutoff). #ifdef USE_CUTOFF const unsigned int numTiles = interactionCount[0]; if (numTiles > maxTiles) return; // There wasn't enough memory for the neighbor list. int pos = (int) (GROUP_ID*(numTiles > maxTiles ? NUM_BLOCKS*((mm_long)NUM_BLOCKS+1)/2 : numTiles)/NUM_GROUPS); int end = (int) ((GROUP_ID+1)*(numTiles > maxTiles ? NUM_BLOCKS*((mm_long)NUM_BLOCKS+1)/2 : numTiles)/NUM_GROUPS); #else int pos = (int) (GROUP_ID*(mm_long)numTiles/NUM_GROUPS); int end = (int) ((GROUP_ID+1)*(mm_long)numTiles/NUM_GROUPS); #endif int nextToSkip = -1; int currentSkipIndex = 0; LOCAL int atomIndices[TILE_SIZE]; while (pos < end) { const bool isExcluded = false; bool includeTile = true; // Extract the coordinates of this tile. int x, y; bool singlePeriodicCopy = false; #ifdef USE_CUTOFF x = tiles[pos]; real4 blockSizeX = blockSize[x]; singlePeriodicCopy = (0.5f*periodicBoxSize.x-blockSizeX.x >= CUTOFF && 0.5f*periodicBoxSize.y-blockSizeX.y >= CUTOFF && 0.5f*periodicBoxSize.z-blockSizeX.z >= CUTOFF); #else y = (int) floor(NUM_BLOCKS+0.5f-SQRT((NUM_BLOCKS+0.5f)*(NUM_BLOCKS+0.5f)-2*pos)); x = (pos-y*NUM_BLOCKS+y*(y+1)/2); if (x < y || x >= NUM_BLOCKS) { // Occasionally happens due to roundoff error. y += (x < y ? -1 : 1); x = (pos-y*NUM_BLOCKS+y*(y+1)/2); } // Skip over tiles that have exclusions, since they were already processed. while (nextToSkip < pos) { if (currentSkipIndex < NUM_TILES_WITH_EXCLUSIONS) { int2 tile = exclusionTiles[currentSkipIndex++]; nextToSkip = tile.x + tile.y*NUM_BLOCKS - tile.y*(tile.y+1)/2; } else nextToSkip = end; } includeTile = (nextToSkip != pos); #endif if (includeTile) { // Load the data for this tile. for (int localAtomIndex = 0; localAtomIndex < TILE_SIZE; localAtomIndex++) { #ifdef USE_CUTOFF unsigned int j = interactingAtoms[pos*TILE_SIZE+localAtomIndex]; #else unsigned int j = y*TILE_SIZE+localAtomIndex; #endif atomIndices[localAtomIndex] = j; if (j < PADDED_NUM_ATOMS) { local_pos[localAtomIndex] = trimTo3(posq[j]); LOAD_LOCAL_PARAMETERS_FROM_GLOBAL local_force[localAtomIndex] = 0; CLEAR_LOCAL_DERIVATIVES } } #ifdef USE_PERIODIC if (singlePeriodicCopy) { // The box is small enough that we can just translate all the atoms into a single periodic // box, then skip having to apply periodic boundary conditions later. real4 blockCenterX = blockCenter[x]; for (unsigned int tgx = 0; tgx < TILE_SIZE; tgx++) APPLY_PERIODIC_TO_POS_WITH_CENTER(local_pos[tgx], blockCenterX) for (unsigned int tgx = 0; tgx < TILE_SIZE; tgx++) { unsigned int atom1 = x*TILE_SIZE+tgx; real4 force = 0; DECLARE_ATOM1_DERIVATIVES real3 pos1 = trimTo3(posq[atom1]); APPLY_PERIODIC_TO_POS_WITH_CENTER(pos1, blockCenterX) LOAD_ATOM1_PARAMETERS for (unsigned int j = 0; j < TILE_SIZE; j++) { real3 pos2 = local_pos[j]; real3 delta = make_real3(pos2.x-pos1.x, pos2.y-pos1.y, pos2.z-pos1.z); real r2 = dot(delta.xyz, delta.xyz); if (atom1 < NUM_ATOMS && atomIndices[j] < NUM_ATOMS && r2 < CUTOFF_SQUARED) { real invR = RSQRT(r2); real r = r2*invR; unsigned int atom2 = j; LOAD_ATOM2_PARAMETERS atom2 = atomIndices[j]; real dEdR = 0; real tempEnergy = 0; const real interactionScale = 1.0f; COMPUTE_INTERACTION dEdR /= -r; energy += tempEnergy; delta *= dEdR; force.x -= delta.x; force.y -= delta.y; force.z -= delta.z; atom2 = j; local_force[atom2].xyz += delta.xyz; RECORD_DERIVATIVE_2 } } // Write results for atom1. unsigned int offset = atom1; ATOMIC_ADD(&forceBuffers[offset], (mm_ulong) realToFixedPoint(force.x)); ATOMIC_ADD(&forceBuffers[offset+PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.y)); ATOMIC_ADD(&forceBuffers[offset+2*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.z)); STORE_DERIVATIVES_1 } } else #endif { // We need to apply periodic boundary conditions separately for each interaction. for (unsigned int tgx = 0; tgx < TILE_SIZE; tgx++) { unsigned int atom1 = x*TILE_SIZE+tgx; real4 force = 0; DECLARE_ATOM1_DERIVATIVES real3 pos1 = trimTo3(posq[atom1]); LOAD_ATOM1_PARAMETERS for (unsigned int j = 0; j < TILE_SIZE; j++) { real3 pos2 = local_pos[j]; real3 delta = make_real3(pos2.x-pos1.x, pos2.y-pos1.y, pos2.z-pos1.z); #ifdef USE_PERIODIC APPLY_PERIODIC_TO_DELTA(delta) #endif real r2 = dot(delta.xyz, delta.xyz); #ifdef USE_CUTOFF if (atom1 < NUM_ATOMS && atomIndices[j] < NUM_ATOMS && r2 < CUTOFF_SQUARED) { #else if (atom1 < NUM_ATOMS && atomIndices[j] < NUM_ATOMS) { #endif real invR = RSQRT(r2); real r = r2*invR; unsigned int atom2 = j; LOAD_ATOM2_PARAMETERS atom2 = atomIndices[j]; real dEdR = 0; real tempEnergy = 0; const real interactionScale = 1.0f; COMPUTE_INTERACTION dEdR /= -r; energy += tempEnergy; delta *= dEdR; force.x -= delta.x; force.y -= delta.y; force.z -= delta.z; atom2 = j; local_force[atom2] += delta; RECORD_DERIVATIVE_2 } } // Write results for atom1. unsigned int offset = atom1; ATOMIC_ADD(&forceBuffers[offset], (mm_ulong) realToFixedPoint(force.x)); ATOMIC_ADD(&forceBuffers[offset+PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.y)); ATOMIC_ADD(&forceBuffers[offset+2*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(force.z)); STORE_DERIVATIVES_1 } } // Write results. for (int tgx = 0; tgx < TILE_SIZE; tgx++) { #ifdef USE_CUTOFF unsigned int atom2 = atomIndices[tgx]; #else unsigned int atom2 = y*TILE_SIZE + tgx; #endif if (atom2 < PADDED_NUM_ATOMS) { ATOMIC_ADD(&forceBuffers[atom2], (mm_ulong) realToFixedPoint(local_force[tgx].x)); ATOMIC_ADD(&forceBuffers[atom2+PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(local_force[tgx].y)); ATOMIC_ADD(&forceBuffers[atom2+2*PADDED_NUM_ATOMS], (mm_ulong) realToFixedPoint(local_force[tgx].z)); unsigned int offset = atom2; STORE_DERIVATIVES_2 } } } pos++; } energyBuffer[GLOBAL_ID] += energy; SAVE_PARAM_DERIVS }