//----------------------------------------------------------------------------------------- //----------------------------------------------------------------------------------------- #include "amoebaGpuTypes.h" #include "amoebaCudaKernels.h" #include "kCalculateAmoebaCudaUtilities.h" #include using namespace std; static __constant__ cudaGmxSimulation cSim; static __constant__ cudaAmoebaGmxSimulation cAmoebaSim; void SetCalculateAmoebaCudaPmeMutualInducedFieldSim(amoebaGpuContext amoebaGpu) { cudaError_t status; gpuContext gpu = amoebaGpu->gpuContext; status = cudaMemcpyToSymbol(cSim, &gpu->sim, sizeof(cudaGmxSimulation)); RTERROR(status, "SetCalculateAmoebaCudaPmeMutualInducedFieldSim: cudaMemcpyToSymbol: SetSim copy to cSim failed"); status = cudaMemcpyToSymbol(cAmoebaSim, &amoebaGpu->amoebaSim, sizeof(cudaAmoebaGmxSimulation)); RTERROR(status, "SetCalculateAmoebaCudaPmeMutualInducedFieldSim: cudaMemcpyToSymbol: SetSim copy to cAmoebaSim failed"); } void GetCalculateAmoebaCudaPmeMutualInducedFieldSim(amoebaGpuContext amoebaGpu) { cudaError_t status; gpuContext gpu = amoebaGpu->gpuContext; status = cudaMemcpyFromSymbol(&gpu->sim, cSim, sizeof(cudaGmxSimulation)); RTERROR(status, "GetCalculateAmoebaCudaPmeMutualInducedFieldSim: cudaMemcpyFromSymbol: SetSim copy from cSim failed"); status = cudaMemcpyFromSymbol(&amoebaGpu->amoebaSim, cAmoebaSim, sizeof(cudaAmoebaGmxSimulation)); RTERROR(status, "GetCalculateAmoebaCudaPmeMutualInducedFieldSim: cudaMemcpyFromSymbol: SetSim copy from cAmoebaSim failed"); } //#define AMOEBA_DEBUG #undef AMOEBA_DEBUG #undef INCLUDE_MI_FIELD_BUFFERS #define INCLUDE_MI_FIELD_BUFFERS #include "kCalculateAmoebaCudaMutualInducedParticle.h" #ifdef INCLUDE_MI_FIELD_BUFFERS __device__ void sumTempBuffer( MutualInducedParticle& atomI, MutualInducedParticle& atomJ ){ atomI.tempBuffer[0] += atomJ.tempBuffer[0]; atomI.tempBuffer[1] += atomJ.tempBuffer[1]; atomI.tempBuffer[2] += atomJ.tempBuffer[2]; atomI.tempBufferP[0] += atomJ.tempBufferP[0]; atomI.tempBufferP[1] += atomJ.tempBufferP[1]; atomI.tempBufferP[2] += atomJ.tempBufferP[2]; } #endif // file includes FixedFieldParticle struct definition/load/unload struct and body kernel for fixed E-field __device__ void setupMutualInducedFieldPairIxn_kernel( const MutualInducedParticle& atomI, const MutualInducedParticle& atomJ, const float uscale, float4* delta, float* preFactor2 ) { // compute thedelta->xeal space portion of the Ewald summation delta->x = atomJ.x - atomI.x; delta->y = atomJ.y - atomI.y; delta->z = atomJ.z - atomI.z; // pdelta->xiodic boundary conditions delta->x -= floor(delta->x*cSim.invPeriodicBoxSizeX+0.5f)*cSim.periodicBoxSizeX; delta->y -= floor(delta->y*cSim.invPeriodicBoxSizeY+0.5f)*cSim.periodicBoxSizeY; delta->z -= floor(delta->z*cSim.invPeriodicBoxSizeZ+0.5f)*cSim.periodicBoxSizeZ; float r2 = (delta->x*delta->x) + (delta->y*delta->y) + (delta->z*delta->z); if( r2 <= cSim.nonbondedCutoffSqr ){ float r = sqrtf(r2); // calculate the error function damping terms float ralpha = cSim.alphaEwald*r; float bn0 = erfc(ralpha)/r; float alsq2 = 2.0f*cSim.alphaEwald*cSim.alphaEwald; float alsq2n = 1.0f/(cAmoebaSim.sqrtPi*cSim.alphaEwald); float exp2a = exp(-(ralpha*ralpha)); alsq2n *= alsq2; float bn1 = (bn0+alsq2n*exp2a)/r2; alsq2n *= alsq2; float bn2 = (3.0f*bn1+alsq2n*exp2a)/r2; // compute the error function scaled and unscaled terms float scale3 = 1.0f; float scale5 = 1.0f; float damp = atomI.damp*atomJ.damp; if( damp != 0.0f ){ float ratio = (r/damp); ratio = ratio*ratio*ratio; float pgamma = atomI.thole < atomJ.thole ? atomI.thole : atomJ.thole; damp = -pgamma*ratio; if( damp > -50.0f) { float expdamp = exp(damp); scale3 = 1.0f - expdamp; scale5 = 1.0f - expdamp*(1.0f-damp); } } float dsc3 = uscale*scale3; float dsc5 = uscale*scale5; float r3 = (r*r2); float r5 = (r3*r2); float rr3 = (1.0f-dsc3)/r3; float rr5 = 3.0f*(1.0f-dsc5)/r5; delta->w = rr3 - bn1; *preFactor2 = bn2 - rr5; } else { delta->w = *preFactor2 = 0.0f; } } __device__ void calculateMutualInducedFieldPairIxn_kernel( const float inducedDipole[3], const float4 delta, const float preFactor2, float fieldSum[3] ) { float preFactor3 = preFactor2*(inducedDipole[0]*delta.x + inducedDipole[1]*delta.y + inducedDipole[2]*delta.z); fieldSum[0] += preFactor3*delta.x + delta.w*inducedDipole[0]; fieldSum[1] += preFactor3*delta.y + delta.w*inducedDipole[1]; fieldSum[2] += preFactor3*delta.z + delta.w*inducedDipole[2]; } __device__ void calculateMutualInducedFieldPairIxnNoAdd_kernel( const float inducedDipole[3], const float4 delta, const float preFactor2, float fieldSum[3] ) { float preFactor3 = preFactor2*(inducedDipole[0]*delta.x + inducedDipole[1]*delta.y + inducedDipole[2]*delta.z); fieldSum[0] = preFactor3*delta.x + delta.w*inducedDipole[0]; fieldSum[1] = preFactor3*delta.y + delta.w*inducedDipole[1]; fieldSum[2] = preFactor3*delta.z + delta.w*inducedDipole[2]; } // file includes FixedFieldParticle struct definition/load/unload struct and body kernel for fixed E-field __device__ void calculatePmeDirectMutualInducedFieldPairIxn_kernel( MutualInducedParticle& atomI, MutualInducedParticle& atomJ, float uscale, float4 fields[3] ){ // compute the real space portion of the Ewald summation float xr = atomJ.x - atomI.x; float yr = atomJ.y - atomI.y; float zr = atomJ.z - atomI.z; // periodic boundary conditions xr -= floor(xr*cSim.invPeriodicBoxSizeX+0.5f)*cSim.periodicBoxSizeX; yr -= floor(yr*cSim.invPeriodicBoxSizeY+0.5f)*cSim.periodicBoxSizeY; zr -= floor(zr*cSim.invPeriodicBoxSizeZ+0.5f)*cSim.periodicBoxSizeZ; float r2 = xr*xr + yr* yr + zr*zr; if( r2 <= cSim.nonbondedCutoffSqr ){ float r = sqrtf(r2); // calculate the error function damping terms float ralpha = cSim.alphaEwald*r; float bn0 = erfc(ralpha)/r; float alsq2 = 2.0f*cSim.alphaEwald*cSim.alphaEwald; float alsq2n = 1.0f/(cAmoebaSim.sqrtPi*cSim.alphaEwald); float exp2a = exp(-(ralpha*ralpha)); alsq2n *= alsq2; float bn1 = (bn0+alsq2n*exp2a)/r2; alsq2n *= alsq2; float bn2 = (3.0f*bn1+alsq2n*exp2a)/r2; // compute the error function scaled and unscaled terms float scale3 = 1.0f; float scale5 = 1.0f; float damp = atomI.damp*atomJ.damp; if( damp != 0.0f ){ float ratio = (r/damp); ratio = ratio*ratio*ratio; float pgamma = atomI.thole < atomJ.thole ? atomI.thole : atomJ.thole; damp = -pgamma*ratio; if( damp > -50.0f) { float expdamp = exp(damp); scale3 = 1.0f - expdamp; scale5 = 1.0f - expdamp*(1.0f-damp); } } float dsc3 = uscale*scale3; float dsc5 = uscale*scale5; float r3 = (r*r2); float r5 = (r3*r2); float rr3 = (1.0f-dsc3)/r3; float rr5 = 3.0f*(1.0f-dsc5)/r5; float preFactor1 = rr3 - bn1; float preFactor2 = bn2 - rr5; float dukr = atomJ.inducedDipole[0]*xr + atomJ.inducedDipole[1]*yr + atomJ.inducedDipole[2]*zr; float preFactor3 = preFactor2*dukr; fields[0].x = preFactor3*xr + preFactor1*atomJ.inducedDipole[0]; fields[1].x = preFactor3*yr + preFactor1*atomJ.inducedDipole[1]; fields[2].x = preFactor3*zr + preFactor1*atomJ.inducedDipole[2]; float duir = atomI.inducedDipole[0]*xr + atomI.inducedDipole[1]*yr + atomI.inducedDipole[2]*zr; preFactor3 = preFactor2*duir; fields[0].y = preFactor3*xr + preFactor1*atomI.inducedDipole[0]; fields[1].y = preFactor3*yr + preFactor1*atomI.inducedDipole[1]; fields[2].y = preFactor3*zr + preFactor1*atomI.inducedDipole[2]; float pukr = atomJ.inducedDipolePolar[0]*xr + atomJ.inducedDipolePolar[1]*yr + atomJ.inducedDipolePolar[2]*zr; preFactor3 = preFactor2*pukr; fields[0].z = preFactor3*xr + preFactor1*atomJ.inducedDipolePolar[0]; fields[1].z = preFactor3*yr + preFactor1*atomJ.inducedDipolePolar[1]; fields[2].z = preFactor3*zr + preFactor1*atomJ.inducedDipolePolar[2]; float puir = atomI.inducedDipolePolar[0]*xr + atomI.inducedDipolePolar[1]*yr + atomI.inducedDipolePolar[2]*zr; preFactor3 = preFactor2*puir; fields[0].w = preFactor3*xr + preFactor1*atomI.inducedDipolePolar[0]; fields[1].w = preFactor3*yr + preFactor1*atomI.inducedDipolePolar[1]; fields[2].w = preFactor3*zr + preFactor1*atomI.inducedDipolePolar[2]; } else { fields[0].x = 0.0f; fields[0].y = 0.0f; fields[0].z = 0.0f; fields[0].w = 0.0f; fields[1].x = 0.0f; fields[1].y = 0.0f; fields[1].z = 0.0f; fields[1].w = 0.0f; fields[2].x = 0.0f; fields[2].y = 0.0f; fields[2].z = 0.0f; fields[2].w = 0.0f; } } // Include versions of the kernels for N^2 calculations. #define METHOD_NAME(a, b) a##Cutoff##b #include "kCalculateAmoebaCudaPmeMutualInducedField.h" #define USE_OUTPUT_BUFFER_PER_WARP #undef METHOD_NAME #define METHOD_NAME(a, b) a##CutoffByWarp##b #include "kCalculateAmoebaCudaPmeMutualInducedField.h" __global__ #if (__CUDA_ARCH__ >= 200) __launch_bounds__(GF1XX_THREADS_PER_BLOCK, 1) #elif (__CUDA_ARCH__ >= 120) __launch_bounds__(GT2XX_THREADS_PER_BLOCK, 1) #else __launch_bounds__(G8X_THREADS_PER_BLOCK, 1) #endif static void kInitializeMutualInducedField_kernel( int numberOfAtoms, float* fixedEField, float* fixedEFieldPolar, float* polarizability ) { int pos = blockIdx.x*blockDim.x + threadIdx.x; while( pos < 3*cSim.atoms ) { fixedEField[pos] *= polarizability[pos]; fixedEFieldPolar[pos] *= polarizability[pos]; pos += blockDim.x*gridDim.x; } } __global__ #if (__CUDA_ARCH__ >= 200) __launch_bounds__(GF1XX_THREADS_PER_BLOCK, 1) #elif (__CUDA_ARCH__ >= 120) __launch_bounds__(GT2XX_THREADS_PER_BLOCK, 1) #else __launch_bounds__(G8X_THREADS_PER_BLOCK, 1) #endif static void kReduceMutualInducedFieldDelta_kernel(int numberOfEntries, float* arrayOfDeltas1, float* arrayOfDeltas2, float* epsilon ) { extern __shared__ float2 delta[]; delta[threadIdx.x].x = 0.0f; delta[threadIdx.x].y = 0.0f; unsigned int pos = threadIdx.x; // load deltas while( pos < numberOfEntries ) { delta[threadIdx.x].x += arrayOfDeltas1[pos]; delta[threadIdx.x].y += arrayOfDeltas2[pos]; pos += blockDim.x*gridDim.x; } __syncthreads(); // sum the deltas for (int offset = 1; offset < blockDim.x; offset *= 2 ) { if (threadIdx.x + offset < blockDim.x && (threadIdx.x & (2*offset-1)) == 0) { delta[threadIdx.x].x += delta[threadIdx.x+offset].x; delta[threadIdx.x].y += delta[threadIdx.x+offset].y; } __syncthreads(); } // set epsilons if (threadIdx.x == 0) { epsilon[0] = delta[0].x > delta[0].y ? delta[0].x : delta[0].y; epsilon[0] = 48.033324f*sqrtf( epsilon[0]/( (float) (numberOfEntries/3)) ); #ifdef AMOEBA_DEBUG epsilon[1] = 48.033324f*sqrtf( delta[0].x/( (float) (numberOfEntries/3)) ); epsilon[2] = 48.033324f*sqrtf( delta[0].y/( (float) (numberOfEntries/3)) ); #endif } } /** matrixProduct/matrixProductP contains epsilon**2 on output */ __global__ #if (__CUDA_ARCH__ >= 200) __launch_bounds__(GF1XX_THREADS_PER_BLOCK, 1) #elif (__CUDA_ARCH__ >= 120) __launch_bounds__(GT2XX_THREADS_PER_BLOCK, 1) #else __launch_bounds__(G8X_THREADS_PER_BLOCK, 1) #endif static void kSorUpdateMutualInducedField_kernel( float* polarizability, float* inducedDipole, float* inducedDipoleP, float* fixedEField, float* fixedEFieldP, float* matrixProduct, float* matrixProductP ) { int pos = blockIdx.x*blockDim.x + threadIdx.x; const float term = (4.0f/3.0f)*(cSim.alphaEwald*cSim.alphaEwald*cSim.alphaEwald)/cAmoebaSim.sqrtPi; const float polarSOR = 0.70f; while( pos < 3*cSim.atoms ) { float previousDipole = inducedDipole[pos]; float previousDipoleP = inducedDipoleP[pos]; // add self terms to fields matrixProduct[pos] += term*previousDipole; matrixProductP[pos] += term*previousDipoleP; inducedDipole[pos] = fixedEField[pos] + polarizability[pos]*matrixProduct[pos]; inducedDipoleP[pos] = fixedEFieldP[pos] + polarizability[pos]*matrixProductP[pos]; inducedDipole[pos] = previousDipole + polarSOR*( inducedDipole[pos] - previousDipole ); inducedDipoleP[pos] = previousDipoleP + polarSOR*( inducedDipoleP[pos] - previousDipoleP ); matrixProduct[pos] = ( inducedDipole[pos] - previousDipole )*( inducedDipole[pos] - previousDipole ); matrixProductP[pos] = ( inducedDipoleP[pos] - previousDipoleP )*( inducedDipoleP[pos] - previousDipoleP ); pos += blockDim.x*gridDim.x; } } // reduce psWorkArray_3_1 // reduce psWorkArray_3_2 static void kReduceMutualInducedFields(amoebaGpuContext amoebaGpu, CUDAStream* outputArray, CUDAStream* outputPolarArray ) { gpuContext gpu = amoebaGpu->gpuContext; kReduceFields_kernel<<sim.nonbond_blocks, gpu->sim.bsf_reduce_threads_per_block>>>( gpu->sim.paddedNumberOfAtoms*3, gpu->sim.outputBuffers, amoebaGpu->psWorkArray_3_1->_pDevData, outputArray->_pDevData, 0 ); LAUNCHERROR("kReducePmeMI_Fields1"); kReduceFields_kernel<<sim.nonbond_blocks, gpu->sim.bsf_reduce_threads_per_block>>>( gpu->sim.paddedNumberOfAtoms*3, gpu->sim.outputBuffers, amoebaGpu->psWorkArray_3_2->_pDevData, outputPolarArray->_pDevData, 0 ); LAUNCHERROR("kReducePmeMI_Fields2"); } /**--------------------------------------------------------------------------------------- Compute mutual induce field @param amoebaGpu amoebaGpu context --------------------------------------------------------------------------------------- */ static void cudaComputeAmoebaPmeMutualInducedFieldMatrixMultiply( amoebaGpuContext amoebaGpu, CUDAStream* outputArray, CUDAStream* outputPolarArray ) { static unsigned int threadsPerBlock = 0; gpuContext gpu = amoebaGpu->gpuContext; #ifdef AMOEBA_DEBUG int targetAtom = 546; static const char* methodName = "cudaComputeAmoebaPmeMutualInducedFieldMatrixMultiply"; static int iteration = 1; if( 1 && amoebaGpu->log ){ (void) fprintf( amoebaGpu->log, "%s\n", methodName ); (void) fflush( amoebaGpu->log ); } #endif kClearFields_3( amoebaGpu, 2 ); // on first pass, set threads/block if( threadsPerBlock == 0 ){ unsigned int maxThreads; if (gpu->sm_version >= SM_20) maxThreads = 384; else if (gpu->sm_version >= SM_12) maxThreads = 128; else maxThreads = 64; threadsPerBlock = std::min(getThreadsPerBlock(amoebaGpu, sizeof(MutualInducedParticle), gpu->sharedMemoryPerBlock ), maxThreads); } #ifdef AMOEBA_DEBUG if( amoebaGpu->log ){ gpu->psInteractionCount->Download(); (void) fprintf( amoebaGpu->log, "cudaComputeAmoebaPmeMutualInducedFieldMatrixMultiply: numBlocks=%u numThreads=%u bufferPerWarp=%u atm=%lu shrd=%lu ixnCt=%lu workUnits=%u\n", gpu->sim.nonbond_blocks, threadsPerBlock, gpu->bOutputBufferPerWarp, sizeof(MutualInducedParticle), sizeof(MutualInducedParticle)*threadsPerBlock, (*gpu->psInteractionCount)[0], gpu->sim.workUnits ); (void) fflush( amoebaGpu->log ); } #endif if (gpu->bOutputBufferPerWarp){ kCalculateAmoebaPmeMutualInducedFieldCutoffByWarp_kernel<<sim.nonbond_blocks, threadsPerBlock, sizeof(MutualInducedParticle)*threadsPerBlock>>>( gpu->sim.pInteractingWorkUnit, amoebaGpu->psWorkArray_3_1->_pDevData, amoebaGpu->psWorkArray_3_2->_pDevData ); } else { kCalculateAmoebaPmeMutualInducedFieldCutoff_kernel<<sim.nonbond_blocks, threadsPerBlock, sizeof(MutualInducedParticle)*threadsPerBlock>>>( gpu->sim.pInteractingWorkUnit, amoebaGpu->psWorkArray_3_1->_pDevData, amoebaGpu->psWorkArray_3_2->_pDevData ); } LAUNCHERROR("kCalculateAmoebaPmeMutualInducedField"); kReduceMutualInducedFields( amoebaGpu, outputArray, outputPolarArray ); #ifdef AMOEBA_DEBUG if( amoebaGpu->log && iteration == 1 ){ (void) fprintf( amoebaGpu->log, "Finished maxtrixMultiply kernel execution %d -- Direct only -- self added in kSorUpdateMutualInducedField_kernel\n", iteration ); (void) fflush( amoebaGpu->log ); outputArray->Download(); outputPolarArray->Download(); //debugArray->Download(); int maxPrint = 5; for( int ii = 0; ii < gpu->natoms; ii++ ){ (void) fprintf( amoebaGpu->log, "%5d ", ii); int indexOffset = ii*3; // MI (void) fprintf( amoebaGpu->log,"Mult[%16.9e %16.9e %16.9e] ", outputArray->_pSysData[indexOffset], outputArray->_pSysData[indexOffset+1], outputArray->_pSysData[indexOffset+2] ); // MI polar (void) fprintf( amoebaGpu->log,"MultP[%16.9e %16.9e %16.9e]\n", outputPolarArray->_pSysData[indexOffset], outputPolarArray->_pSysData[indexOffset+1], outputPolarArray->_pSysData[indexOffset+2] ); if( ii == maxPrint && (gpu->natoms - maxPrint) > ii ){ ii = gpu->natoms - maxPrint; } } (void) fflush( amoebaGpu->log ); iteration++; } #endif } /**--------------------------------------------------------------------------------------- Compute mutual induce field @param amoebaGpu amoebaGpu context --------------------------------------------------------------------------------------- */ static void cudaComputeAmoebaPmeMutualInducedFieldBySOR( amoebaGpuContext amoebaGpu ) { // --------------------------------------------------------------------------------------- //#define AMOEBA_DEBUG #ifdef AMOEBA_DEBUG static const char* methodName = "cudaComputeAmoebaPmeMutualInducedFieldBySOR"; static int timestep = 0; std::vector fileId; timestep++; fileId.resize( 2 ); fileId[0] = timestep; fileId[1] = 1; #endif // --------------------------------------------------------------------------------------- int done; int iteration; gpuContext gpu = amoebaGpu->gpuContext; // --------------------------------------------------------------------------------------- // set E_Field & E_FieldPolar] to [ E_Field & E_FieldPolar]*Polarizability // initialize [ InducedDipole & InducedDipolePolar ] to [ E_Field & E_FieldPolar]*Polarizability kInitializeMutualInducedField_kernel<<< gpu->sim.blocks, gpu->sim.threads_per_block >>>( gpu->natoms, amoebaGpu->psE_Field->_pDevData, amoebaGpu->psE_FieldPolar->_pDevData, amoebaGpu->psPolarizability->_pDevData ); LAUNCHERROR("AmoebaPmeMutualInducedFieldSetup"); cudaMemcpy( amoebaGpu->psInducedDipole->_pDevData, amoebaGpu->psE_Field->_pDevData, 3*gpu->sim.paddedNumberOfAtoms*sizeof( float ), cudaMemcpyDeviceToDevice ); cudaMemcpy( amoebaGpu->psInducedDipolePolar->_pDevData, amoebaGpu->psE_FieldPolar->_pDevData, 3*gpu->sim.paddedNumberOfAtoms*sizeof( float ), cudaMemcpyDeviceToDevice ); #ifdef AMOEBA_DEBUG if( amoebaGpu->log ){ std::vector fileId; VectorOfDoubleVectors outputVector; cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psE_Field, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psE_FieldPolar, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipole, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipolePolar, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaWriteVectorOfDoubleVectorsToFile( "CudaPmeEFieldPolarity", fileId, outputVector ); } #endif // if polarization type is direct, set flags signalling done and return if( amoebaGpu->amoebaSim.polarizationType ) { amoebaGpu->mutualInducedDone = 1; amoebaGpu->mutualInducedConverged = 1; kCalculateAmoebaPMEInducedDipoleField( amoebaGpu ); return; } // --------------------------------------------------------------------------------------- done = 0; iteration = 1; while( !done ){ // matrix multiply cudaComputeAmoebaPmeMutualInducedFieldMatrixMultiply( amoebaGpu, amoebaGpu->psWorkVector[0], amoebaGpu->psWorkVector[1] ); kCalculateAmoebaPMEInducedDipoleField( amoebaGpu ); // post matrix multiply kSorUpdateMutualInducedField_kernel<<< gpu->sim.blocks, gpu->sim.threads_per_block >>>( amoebaGpu->psPolarizability->_pDevData, amoebaGpu->psInducedDipole->_pDevData, amoebaGpu->psInducedDipolePolar->_pDevData, amoebaGpu->psE_Field->_pDevData, amoebaGpu->psE_FieldPolar->_pDevData, amoebaGpu->psWorkVector[0]->_pDevData, amoebaGpu->psWorkVector[1]->_pDevData ); LAUNCHERROR("kSorUpdatePmeMutualInducedField"); // get total epsilon -- performing sums on gpu kReduceMutualInducedFieldDelta_kernel<<<1, amoebaGpu->epsilonThreadsPerBlock, 2*sizeof(float)*amoebaGpu->epsilonThreadsPerBlock>>>( 3*gpu->natoms, amoebaGpu->psWorkVector[0]->_pDevData, amoebaGpu->psWorkVector[1]->_pDevData, amoebaGpu->psCurrentEpsilon->_pDevData ); LAUNCHERROR("kReducePmeMutualInducedFieldDelta"); #ifdef AMOEBA_DEBUG if( 0 && amoebaGpu->log ){ // trackMutualInducedIterations trackMutualInducedIterations( amoebaGpu, iteration); } #endif // Debye=48.033324f amoebaGpu->psCurrentEpsilon->Download(); float currentEpsilon = amoebaGpu->psCurrentEpsilon->_pSysData[0]; amoebaGpu->mutualInducedCurrentEpsilon = currentEpsilon; if( iteration > amoebaGpu->mutualInducedMaxIterations || amoebaGpu->mutualInducedCurrentEpsilon < amoebaGpu->mutualInducedTargetEpsilon ){ done = 1; } #ifdef AMOEBA_DEBUG if( amoebaGpu->log ){ amoebaGpu->psInducedDipole->Download(); amoebaGpu->psInducedDipolePolar->Download(); #if 1 (void) fprintf( amoebaGpu->log, "cudaComputeAmoebaPmeMutualInducedFieldBySOR iteration=%3d eps %14.6e [%14.6e %14.6e] done=%d\n", iteration, amoebaGpu->mutualInducedCurrentEpsilon, amoebaGpu->psCurrentEpsilon->_pSysData[1], amoebaGpu->psCurrentEpsilon->_pSysData[2], done ); #else (void) fprintf( amoebaGpu->log, "%s iteration=%3d eps %14.6e %14.6e crrntEps=%14.6e %14.6e %14.6e %14.6e done=%d\n", methodName, iteration, sum1, sum2, amoebaGpu->mutualInducedCurrentEpsilon, amoebaGpu->psCurrentEpsilon->_pSysData[0], amoebaGpu->psCurrentEpsilon->_pSysData[1], amoebaGpu->psCurrentEpsilon->_pSysData[2], done ); #endif (void) fflush( amoebaGpu->log ); if( 0 ){ gpuContext gpu = amoebaGpu->gpuContext; std::vector fileId; fileId.push_back( iteration ); VectorOfDoubleVectors outputVector; cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psE_Field, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psE_FieldPolar, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipole, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipolePolar, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaWriteVectorOfDoubleVectorsToFile( "CudaPmeMI", fileId, outputVector ); } /* int offset = 0; int maxPrint = 10; for( int ii = 0; ii < gpu->natoms; ii++ ){ (void) fprintf( amoebaGpu->log, "%4d ", ii ); (void) fprintf( amoebaGpu->log," Mi[%14.6e %14.6e %14.6e] ", amoebaGpu->psInducedDipole->_pSysData[offset], amoebaGpu->psInducedDipole->_pSysData[offset+1], amoebaGpu->psInducedDipole->_pSysData[offset+2] ); (void) fprintf( amoebaGpu->log,"Mip[%14.6e %14.6e %14.6e]\n", amoebaGpu->psInducedDipolePolar->_pSysData[offset], amoebaGpu->psInducedDipolePolar->_pSysData[offset+1], amoebaGpu->psInducedDipolePolar->_pSysData[offset+2] ); if( ii == maxPrint && (ii < (gpu->natoms - maxPrint) ) ){ ii = (gpu->natoms - maxPrint); offset = 3*(ii+1); } else { offset += 3; } } (void) fflush( amoebaGpu->log ); */ if( 0 ){ std::vector fileId; fileId.push_back( iteration ); VectorOfDoubleVectors outputVector; cudaLoadCudaFloat4Array( gpu->natoms, 3, gpu->psPosq4, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipole, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipolePolar, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaWriteVectorOfDoubleVectorsToFile( "CudaPmeMI", fileId, outputVector ); } } (void) fprintf( amoebaGpu->log, "MI iteration=%3d eps %14.6e [%14.6e %14.6e] done=%d\n", iteration, amoebaGpu->mutualInducedCurrentEpsilon, amoebaGpu->psCurrentEpsilon->_pSysData[1], amoebaGpu->psCurrentEpsilon->_pSysData[2], done ); (void) fflush( amoebaGpu->log ); #endif // exit if nan if( amoebaGpu->mutualInducedCurrentEpsilon != amoebaGpu->mutualInducedCurrentEpsilon ){ (void) fprintf( stderr, "PME MI iteration=%3d eps is nan -- exiting.\n", iteration ); exit(0); } iteration++; } amoebaGpu->mutualInducedDone = done; amoebaGpu->mutualInducedConverged = ( !done || iteration > amoebaGpu->mutualInducedMaxIterations ) ? 0 : 1; #ifdef AMOEBA_DEBUG if( 0 ){ std::vector fileId; //fileId.push_back( 0 ); VectorOfDoubleVectors outputVector; cudaLoadCudaFloat4Array( gpu->natoms, 3, gpu->psPosq4, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipole, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaLoadCudaFloatArray( gpu->natoms, 3, amoebaGpu->psInducedDipolePolar, outputVector, gpu->psAtomIndex->_pSysData, 1.0f ); cudaWriteVectorOfDoubleVectorsToFile( "CudaPmeMI", fileId, outputVector ); } if( 0 ){ static int iteration = 0; checkForNans( gpu->natoms, 3, amoebaGpu->psInducedDipole, gpu->psAtomIndex->_pSysData, ++iteration, "CudaPmeMI", stderr ); checkForNans( gpu->natoms, 3, amoebaGpu->psInducedDipolePolar, gpu->psAtomIndex->_pSysData, iteration, "CudaPmeMIPolar", stderr ); } #endif // --------------------------------------------------------------------------------------- } void cudaComputeAmoebaPmeMutualInducedField( amoebaGpuContext amoebaGpu ) { if( amoebaGpu->mutualInducedIterativeMethod == 0 ){ cudaComputeAmoebaPmeMutualInducedFieldBySOR( amoebaGpu ); } }