#define TILE_SIZE 32 #define WARPS_PER_GROUP (THREAD_BLOCK_SIZE/TILE_SIZE) typedef struct { real x, y, z; real q; real fx, fy, fz; ATOM_PARAMETER_DATA #ifndef PARAMETER_SIZE_IS_EVEN real padding; #endif } AtomData; /** * Compute nonbonded interactions. */ extern "C" __global__ void computeNonbonded( unsigned long long* __restrict__ forceBuffers, real* __restrict__ energyBuffer, const real4* __restrict__ posq, const unsigned int* __restrict__ exclusions, const unsigned int* __restrict__ exclusionIndices, const unsigned int* __restrict__ exclusionRowIndices, unsigned int startTileIndex, unsigned int numTileIndices #ifdef USE_CUTOFF , const ushort2* __restrict__ tiles, const unsigned int* __restrict__ interactionCount, real4 periodicBoxSize, real4 invPeriodicBoxSize, unsigned int maxTiles, const unsigned int* __restrict__ interactionFlags #endif PARAMETER_ARGUMENTS) { unsigned int totalWarps = (blockDim.x*gridDim.x)/TILE_SIZE; unsigned int warp = (blockIdx.x*blockDim.x+threadIdx.x)/TILE_SIZE; #ifdef USE_CUTOFF const unsigned int numTiles = interactionCount[0]; unsigned int pos = (numTiles > maxTiles ? startTileIndex+warp*numTileIndices/totalWarps : warp*numTiles/totalWarps); unsigned int end = (numTiles > maxTiles ? startTileIndex+(warp+1)*numTileIndices/totalWarps : (warp+1)*numTiles/totalWarps); #else const unsigned int numTiles = numTileIndices; unsigned int pos = startTileIndex+warp*numTiles/totalWarps; unsigned int end = startTileIndex+(warp+1)*numTiles/totalWarps; #endif real energy = 0.0f; __shared__ AtomData localData[THREAD_BLOCK_SIZE]; __shared__ real tempBuffer[3*THREAD_BLOCK_SIZE]; __shared__ unsigned int exclusionRange[2*WARPS_PER_GROUP]; __shared__ int exclusionIndex[WARPS_PER_GROUP]; do { // Extract the coordinates of this tile const unsigned int tgx = threadIdx.x & (TILE_SIZE-1); const unsigned int tbx = threadIdx.x - tgx; const unsigned int localGroupIndex = threadIdx.x/TILE_SIZE; unsigned int x, y; real3 force = make_real3(0); if (pos < end) { #ifdef USE_CUTOFF if (numTiles <= maxTiles) { ushort2 tileIndices = tiles[pos]; x = tileIndices.x; y = tileIndices.y; } else #endif { y = (unsigned 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); } } unsigned int atom1 = x*TILE_SIZE + tgx; real4 posq1 = posq[atom1]; LOAD_ATOM1_PARAMETERS // Locate the exclusion data for this tile. #ifdef USE_EXCLUSIONS if (tgx < 2) exclusionRange[2*localGroupIndex+tgx] = exclusionRowIndices[x+tgx]; if (tgx == 0) exclusionIndex[localGroupIndex] = -1; for (unsigned int i = exclusionRange[2*localGroupIndex]+tgx; i < exclusionRange[2*localGroupIndex+1]; i += TILE_SIZE) if (exclusionIndices[i] == y) exclusionIndex[localGroupIndex] = i*TILE_SIZE; bool hasExclusions = (exclusionIndex[localGroupIndex] > -1); #else bool hasExclusions = false; #endif if (pos >= end) ; // This warp is done. else if (x == y) { // This tile is on the diagonal. const unsigned int localAtomIndex = threadIdx.x; localData[localAtomIndex].x = posq1.x; localData[localAtomIndex].y = posq1.y; localData[localAtomIndex].z = posq1.z; localData[localAtomIndex].q = posq1.w; LOAD_LOCAL_PARAMETERS_FROM_1 #ifdef USE_EXCLUSIONS unsigned int excl = exclusions[exclusionIndex[localGroupIndex]+tgx]; #endif for (unsigned int j = 0; j < TILE_SIZE; j++) { #ifdef USE_EXCLUSIONS bool isExcluded = !(excl & 0x1); #endif int atom2 = tbx+j; real4 posq2 = make_real4(localData[atom2].x, localData[atom2].y, localData[atom2].z, localData[atom2].q); real3 delta = make_real3(posq2.x-posq1.x, posq2.y-posq1.y, posq2.z-posq1.z); #ifdef USE_PERIODIC delta.x -= floor(delta.x*invPeriodicBoxSize.x+0.5f)*periodicBoxSize.x; delta.y -= floor(delta.y*invPeriodicBoxSize.y+0.5f)*periodicBoxSize.y; delta.z -= floor(delta.z*invPeriodicBoxSize.z+0.5f)*periodicBoxSize.z; #endif real r2 = delta.x*delta.x + delta.y*delta.y + delta.z*delta.z; real invR = RSQRT(r2); real r = RECIP(invR); LOAD_ATOM2_PARAMETERS atom2 = y*TILE_SIZE+j; #ifdef USE_SYMMETRIC real dEdR = 0.0f; #else real3 dEdR1 = make_real3(0); real3 dEdR2 = make_real3(0); #endif real tempEnergy = 0.0f; COMPUTE_INTERACTION energy += 0.5f*tempEnergy; #ifdef USE_SYMMETRIC force -= delta*dEdR; #else force -= dEdR1; #endif #ifdef USE_EXCLUSIONS excl >>= 1; #endif } } else { // This is an off-diagonal tile. const unsigned int localAtomIndex = threadIdx.x; unsigned int j = y*TILE_SIZE + tgx; real4 tempPosq = posq[j]; localData[localAtomIndex].x = tempPosq.x; localData[localAtomIndex].y = tempPosq.y; localData[localAtomIndex].z = tempPosq.z; localData[localAtomIndex].q = tempPosq.w; LOAD_LOCAL_PARAMETERS_FROM_GLOBAL localData[localAtomIndex].fx = 0.0f; localData[localAtomIndex].fy = 0.0f; localData[localAtomIndex].fz = 0.0f; #ifdef USE_CUTOFF unsigned int flags = (numTiles <= maxTiles ? interactionFlags[pos] : 0xFFFFFFFF); if (!hasExclusions && flags != 0xFFFFFFFF) { if (flags == 0) { // No interactions in this tile. } else { // Compute only a subset of the interactions in this tile. for (j = 0; j < TILE_SIZE; j++) { if ((flags&(1<> tgx) | (excl << (TILE_SIZE - tgx)); #endif unsigned int tj = tgx; for (j = 0; j < TILE_SIZE; j++) { #ifdef USE_EXCLUSIONS bool isExcluded = !(excl & 0x1); #endif int atom2 = tbx+tj; real4 posq2 = make_real4(localData[atom2].x, localData[atom2].y, localData[atom2].z, localData[atom2].q); real3 delta = make_real3(posq2.x-posq1.x, posq2.y-posq1.y, posq2.z-posq1.z); #ifdef USE_PERIODIC delta.x -= floor(delta.x*invPeriodicBoxSize.x+0.5f)*periodicBoxSize.x; delta.y -= floor(delta.y*invPeriodicBoxSize.y+0.5f)*periodicBoxSize.y; delta.z -= floor(delta.z*invPeriodicBoxSize.z+0.5f)*periodicBoxSize.z; #endif real r2 = delta.x*delta.x + delta.y*delta.y + delta.z*delta.z; #ifdef USE_CUTOFF if (r2 < CUTOFF_SQUARED) { #endif real invR = RSQRT(r2); real r = RECIP(invR); LOAD_ATOM2_PARAMETERS atom2 = y*TILE_SIZE+tj; #ifdef USE_SYMMETRIC real dEdR = 0.0f; #else real3 dEdR1 = make_real3(0); real3 dEdR2 = make_real3(0); #endif real tempEnergy = 0.0f; COMPUTE_INTERACTION energy += tempEnergy; #ifdef USE_SYMMETRIC delta *= dEdR; force -= delta; localData[tbx+tj].fx += delta.x; localData[tbx+tj].fy += delta.y; localData[tbx+tj].fz += delta.z; #else force -= dEdR1; localData[tbx+tj].fx += dEdR2.x; localData[tbx+tj].fy += dEdR2.y; localData[tbx+tj].fz += dEdR2.z; #endif #ifdef USE_CUTOFF } #endif #ifdef USE_EXCLUSIONS excl >>= 1; #endif tj = (tj + 1) & (TILE_SIZE - 1); } } } } // Write results. if (pos < end) { const unsigned int offset = x*TILE_SIZE + tgx; atomicAdd(&forceBuffers[offset], static_cast((long long) (force.x*0xFFFFFFFF))); atomicAdd(&forceBuffers[offset+PADDED_NUM_ATOMS], static_cast((long long) (force.y*0xFFFFFFFF))); atomicAdd(&forceBuffers[offset+2*PADDED_NUM_ATOMS], static_cast((long long) (force.z*0xFFFFFFFF))); __threadfence_block(); } if (pos < end && x != y) { const unsigned int offset = y*TILE_SIZE + tgx; atomicAdd(&forceBuffers[offset], static_cast((long long) (localData[threadIdx.x].fx*0xFFFFFFFF))); atomicAdd(&forceBuffers[offset+PADDED_NUM_ATOMS], static_cast((long long) (localData[threadIdx.x].fy*0xFFFFFFFF))); atomicAdd(&forceBuffers[offset+2*PADDED_NUM_ATOMS], static_cast((long long) (localData[threadIdx.x].fz*0xFFFFFFFF))); __threadfence_block(); } pos++; } while (pos < end); energyBuffer[blockIdx.x*blockDim.x+threadIdx.x] += energy; }