/* -------------------------------------------------------------------------- * * OpenMM * * -------------------------------------------------------------------------- * * This is part of the OpenMM molecular simulation toolkit originating from * * Simbios, the NIH National Center for Physics-Based Simulation of * * Biological Structures at Stanford, funded under the NIH Roadmap for * * Medical Research, grant U54 GM072970. See https://simtk.org. * * * * Portions copyright (c) 2008-2009 Stanford University and the Authors. * * Authors: Peter Eastman * * Contributors: * * * * This program is free software: you can redistribute it and/or modify * * it under the terms of the GNU Lesser General Public License as published * * by the Free Software Foundation, either version 3 of the License, or * * (at your option) any later version. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU Lesser General Public License for more details. * * * * You should have received a copy of the GNU Lesser General Public License * * along with this program. If not, see . * * -------------------------------------------------------------------------- */ #include "OpenCLKernels.h" #include "OpenCLForceInfo.h" #include "openmm/LangevinIntegrator.h" #include "openmm/Context.h" #include "openmm/internal/ContextImpl.h" #include "OpenCLIntegrationUtilities.h" #include "OpenCLNonbondedUtilities.h" #include using namespace OpenMM; using namespace std; static const double KILO = 1e3; // Thousand static const double BOLTZMANN = 1.380658e-23; // (J/K) static const double AVOGADRO = 6.0221367e23; // () static const double RGAS = BOLTZMANN*AVOGADRO; // (J/(mol K)) static const double BOLTZ = (RGAS/KILO); // (kJ/(mol K)) void OpenCLCalcForcesAndEnergyKernel::initialize(const System& system) { } void OpenCLCalcForcesAndEnergyKernel::beginForceComputation(ContextImpl& context) { if (cl.getNonbondedUtilities().getUseCutoff() && cl.getComputeForceCount()%100 == 0) cl.reorderAtoms(); cl.setComputeForceCount(cl.getComputeForceCount()+1); cl.clearBuffer(cl.getForceBuffers()); cl.getNonbondedUtilities().prepareInteractions(); } void OpenCLCalcForcesAndEnergyKernel::finishForceComputation(ContextImpl& context) { cl.getNonbondedUtilities().computeInteractions(); cl.reduceBuffer(cl.getForceBuffers(), cl.getNumForceBuffers()); cl.getNonbondedUtilities().prepareInteractions(); } void OpenCLCalcForcesAndEnergyKernel::beginEnergyComputation(ContextImpl& context) { if (cl.getNonbondedUtilities().getUseCutoff() && cl.getComputeForceCount()%100 == 0) cl.reorderAtoms(); cl.setComputeForceCount(cl.getComputeForceCount()+1); cl.clearBuffer(cl.getEnergyBuffer()); cl.getNonbondedUtilities().prepareInteractions(); } double OpenCLCalcForcesAndEnergyKernel::finishEnergyComputation(ContextImpl& context) { cl.getNonbondedUtilities().computeInteractions(); OpenCLArray& energy = cl.getEnergyBuffer(); energy.download(); double sum = 0.0f; for (int i = 0; i < energy.getSize(); i++) sum += energy[i]; return sum; } void OpenCLUpdateStateDataKernel::initialize(const System& system) { } double OpenCLUpdateStateDataKernel::getTime(const ContextImpl& context) const { return cl.getTime(); } void OpenCLUpdateStateDataKernel::setTime(ContextImpl& context, double time) { cl.setTime(time); } void OpenCLUpdateStateDataKernel::getPositions(ContextImpl& context, std::vector& positions) { OpenCLArray& posq = cl.getPosq(); posq.download(); OpenCLArray& order = cl.getAtomIndex(); int numParticles = context.getSystem().getNumParticles(); positions.resize(numParticles); mm_float4 periodicBoxSize = cl.getNonbondedUtilities().getPeriodicBoxSize(); for (int i = 0; i < numParticles; ++i) { mm_float4 pos = posq[i]; mm_int4 offset = cl.getPosCellOffsets()[i]; positions[order[i]] = Vec3(pos.x-offset.x*periodicBoxSize.x, pos.y-offset.y*periodicBoxSize.y, pos.z-offset.z*periodicBoxSize.z); } } void OpenCLUpdateStateDataKernel::setPositions(ContextImpl& context, const std::vector& positions) { OpenCLArray& posq = cl.getPosq(); OpenCLArray& order = cl.getAtomIndex(); int numParticles = context.getSystem().getNumParticles(); for (int i = 0; i < numParticles; ++i) { mm_float4& pos = posq[i]; const Vec3& p = positions[order[i]]; pos.x = p[0]; pos.y = p[1]; pos.z = p[2]; } posq.upload(); for (int i = 0; i < cl.getPosCellOffsets().size(); i++) cl.getPosCellOffsets()[i] = (mm_int4) {0, 0, 0, 0}; } void OpenCLUpdateStateDataKernel::getVelocities(ContextImpl& context, std::vector& velocities) { OpenCLArray& velm = cl.getVelm(); velm.download(); OpenCLArray& order = cl.getAtomIndex(); int numParticles = context.getSystem().getNumParticles(); velocities.resize(numParticles); for (int i = 0; i < numParticles; ++i) { mm_float4 vel = velm[i]; velocities[order[i]] = Vec3(vel.x, vel.y, vel.z); } } void OpenCLUpdateStateDataKernel::setVelocities(ContextImpl& context, const std::vector& velocities) { OpenCLArray& velm = cl.getVelm(); OpenCLArray& order = cl.getAtomIndex(); int numParticles = context.getSystem().getNumParticles(); for (int i = 0; i < numParticles; ++i) { mm_float4& vel = velm[i]; const Vec3& p = velocities[order[i]]; vel.x = p[0]; vel.y = p[1]; vel.z = p[2]; } velm.upload(); } void OpenCLUpdateStateDataKernel::getForces(ContextImpl& context, std::vector& forces) { OpenCLArray& force = cl.getForce(); force.download(); OpenCLArray& order = cl.getAtomIndex(); int numParticles = context.getSystem().getNumParticles(); forces.resize(numParticles); for (int i = 0; i < numParticles; ++i) { mm_float4 f = force[i]; forces[order[i]] = Vec3(f.x, f.y, f.z); } } class OpenCLBondForceInfo : public OpenCLForceInfo { public: OpenCLBondForceInfo(int requiredBuffers, const HarmonicBondForce& force) : OpenCLForceInfo(requiredBuffers), force(force) { } int getNumParticleGroups() { return force.getNumBonds(); } void getParticlesInGroup(int index, std::vector& particles) { int particle1, particle2; double length, k; force.getBondParameters(index, particle1, particle2, length, k); particles.resize(2); particles[0] = particle1; particles[1] = particle2; } bool areGroupsIdentical(int group1, int group2) { int particle1, particle2; double length1, length2, k1, k2; force.getBondParameters(group1, particle1, particle2, length1, k1); force.getBondParameters(group2, particle1, particle2, length2, k2); return (length1 == length2 && k1 == k2); } private: const HarmonicBondForce& force; }; OpenCLCalcHarmonicBondForceKernel::~OpenCLCalcHarmonicBondForceKernel() { if (params != NULL) delete params; if (indices != NULL) delete indices; } void OpenCLCalcHarmonicBondForceKernel::initialize(const System& system, const HarmonicBondForce& force) { numBonds = force.getNumBonds(); params = new OpenCLArray(cl, numBonds, "bondParams"); indices = new OpenCLArray(cl, numBonds, "bondIndices"); vector forceBufferCounter(system.getNumParticles(), 0); vector paramVector(numBonds); vector indicesVector(numBonds); for (int i = 0; i < numBonds; i++) { int particle1, particle2; double length, k; force.getBondParameters(i, particle1, particle2, length, k); paramVector[i] = (mm_float2) {length, k}; indicesVector[i] = (mm_int4) {particle1, particle2, forceBufferCounter[particle1]++, forceBufferCounter[particle2]++}; } params->upload(paramVector); indices->upload(indicesVector); int maxBuffers = 1; for (int i = 0; i < forceBufferCounter.size(); i++) maxBuffers = max(maxBuffers, forceBufferCounter[i]); cl.addForce(new OpenCLBondForceInfo(maxBuffers, force)); cl::Program program = cl.createProgram(cl.loadSourceFromFile("harmonicBondForce.cl")); kernel = cl::Kernel(program, "calcHarmonicBondForce"); } void OpenCLCalcHarmonicBondForceKernel::executeForces(ContextImpl& context) { kernel.setArg(0, cl.getPaddedNumAtoms()); kernel.setArg(1, numBonds); kernel.setArg(2, cl.getForceBuffers().getDeviceBuffer()); kernel.setArg(3, cl.getEnergyBuffer().getDeviceBuffer()); kernel.setArg(4, cl.getPosq().getDeviceBuffer()); kernel.setArg(5, params->getDeviceBuffer()); kernel.setArg(6, indices->getDeviceBuffer()); cl.executeKernel(kernel, numBonds); } double OpenCLCalcHarmonicBondForceKernel::executeEnergy(ContextImpl& context) { executeForces(context); return 0.0; } class OpenCLAngleForceInfo : public OpenCLForceInfo { public: OpenCLAngleForceInfo(int requiredBuffers, const HarmonicAngleForce& force) : OpenCLForceInfo(requiredBuffers), force(force) { } int getNumParticleGroups() { return force.getNumAngles(); } void getParticlesInGroup(int index, std::vector& particles) { int particle1, particle2, particle3; double angle, k; force.getAngleParameters(index, particle1, particle2, particle3, angle, k); particles.resize(3); particles[0] = particle1; particles[1] = particle2; particles[2] = particle3; } bool areGroupsIdentical(int group1, int group2) { int particle1, particle2, particle3; double angle1, angle2, k1, k2; force.getAngleParameters(group1, particle1, particle2, particle3, angle1, k1); force.getAngleParameters(group2, particle1, particle2, particle3, angle2, k2); return (angle1 == angle2 && k1 == k2); } private: const HarmonicAngleForce& force; }; OpenCLCalcHarmonicAngleForceKernel::~OpenCLCalcHarmonicAngleForceKernel() { if (params != NULL) delete params; if (indices != NULL) delete indices; } void OpenCLCalcHarmonicAngleForceKernel::initialize(const System& system, const HarmonicAngleForce& force) { numAngles = force.getNumAngles(); params = new OpenCLArray(cl, numAngles, "angleParams"); indices = new OpenCLArray(cl, numAngles, "angleIndices"); vector forceBufferCounter(system.getNumParticles(), 0); vector paramVector(numAngles); vector indicesVector(numAngles); for (int i = 0; i < numAngles; i++) { int particle1, particle2, particle3; double angle, k; force.getAngleParameters(i, particle1, particle2, particle3, angle, k); paramVector[i] = (mm_float2) {angle, k}; indicesVector[i] = (mm_int8) {particle1, particle2, particle3, forceBufferCounter[particle1]++, forceBufferCounter[particle2]++, forceBufferCounter[particle3]++, 0, 0}; } params->upload(paramVector); indices->upload(indicesVector); int maxBuffers = 1; for (int i = 0; i < forceBufferCounter.size(); i++) maxBuffers = max(maxBuffers, forceBufferCounter[i]); cl.addForce(new OpenCLAngleForceInfo(maxBuffers, force)); cl::Program program = cl.createProgram(cl.loadSourceFromFile("harmonicAngleForce.cl")); kernel = cl::Kernel(program, "calcHarmonicAngleForce"); } void OpenCLCalcHarmonicAngleForceKernel::executeForces(ContextImpl& context) { kernel.setArg(0, cl.getPaddedNumAtoms()); kernel.setArg(1, numAngles); kernel.setArg(2, cl.getForceBuffers().getDeviceBuffer()); kernel.setArg(3, cl.getEnergyBuffer().getDeviceBuffer()); kernel.setArg(4, cl.getPosq().getDeviceBuffer()); kernel.setArg(5, params->getDeviceBuffer()); kernel.setArg(6, indices->getDeviceBuffer()); cl.executeKernel(kernel, numAngles); } double OpenCLCalcHarmonicAngleForceKernel::executeEnergy(ContextImpl& context) { executeForces(context); return 0.0; } class OpenCLPeriodicTorsionForceInfo : public OpenCLForceInfo { public: OpenCLPeriodicTorsionForceInfo(int requiredBuffers, const PeriodicTorsionForce& force) : OpenCLForceInfo(requiredBuffers), force(force) { } int getNumParticleGroups() { return force.getNumTorsions(); } void getParticlesInGroup(int index, std::vector& particles) { int particle1, particle2, particle3, particle4, periodicity; double phase, k; force.getTorsionParameters(index, particle1, particle2, particle3, particle4, periodicity, phase, k); particles.resize(4); particles[0] = particle1; particles[1] = particle2; particles[2] = particle3; particles[3] = particle4; } bool areGroupsIdentical(int group1, int group2) { int particle1, particle2, particle3, particle4, periodicity1, periodicity2; double phase1, phase2, k1, k2; force.getTorsionParameters(group1, particle1, particle2, particle3, particle4, periodicity1, phase1, k1); force.getTorsionParameters(group1, particle1, particle2, particle3, particle4, periodicity2, phase2, k2); return (periodicity1 == periodicity2 && phase1 == phase2 && k1 == k2); } private: const PeriodicTorsionForce& force; }; OpenCLCalcPeriodicTorsionForceKernel::~OpenCLCalcPeriodicTorsionForceKernel() { if (params != NULL) delete params; if (indices != NULL) delete indices; } void OpenCLCalcPeriodicTorsionForceKernel::initialize(const System& system, const PeriodicTorsionForce& force) { numTorsions = force.getNumTorsions(); params = new OpenCLArray(cl, numTorsions, "periodicTorsionParams"); indices = new OpenCLArray(cl, numTorsions, "periodicTorsionIndices"); vector forceBufferCounter(system.getNumParticles(), 0); vector paramVector(numTorsions); vector indicesVector(numTorsions); for (int i = 0; i < numTorsions; i++) { int particle1, particle2, particle3, particle4, periodicity; double phase, k; force.getTorsionParameters(i, particle1, particle2, particle3, particle4, periodicity, phase, k); paramVector[i] = (mm_float4) {k, phase, (float) periodicity}; indicesVector[i] = (mm_int8) {particle1, particle2, particle3, particle4, forceBufferCounter[particle1]++, forceBufferCounter[particle2]++, forceBufferCounter[particle3]++, forceBufferCounter[particle4]++}; } params->upload(paramVector); indices->upload(indicesVector); int maxBuffers = 1; for (int i = 0; i < forceBufferCounter.size(); i++) maxBuffers = max(maxBuffers, forceBufferCounter[i]); cl.addForce(new OpenCLPeriodicTorsionForceInfo(maxBuffers, force)); cl::Program program = cl.createProgram(cl.loadSourceFromFile("periodicTorsionForce.cl")); kernel = cl::Kernel(program, "calcPeriodicTorsionForce"); } void OpenCLCalcPeriodicTorsionForceKernel::executeForces(ContextImpl& context) { kernel.setArg(0, cl.getPaddedNumAtoms()); kernel.setArg(1, numTorsions); kernel.setArg(2, cl.getForceBuffers().getDeviceBuffer()); kernel.setArg(3, cl.getEnergyBuffer().getDeviceBuffer()); kernel.setArg(4, cl.getPosq().getDeviceBuffer()); kernel.setArg(5, params->getDeviceBuffer()); kernel.setArg(6, indices->getDeviceBuffer()); cl.executeKernel(kernel, numTorsions); } double OpenCLCalcPeriodicTorsionForceKernel::executeEnergy(ContextImpl& context) { executeForces(context); return 0.0; } class OpenCLRBTorsionForceInfo : public OpenCLForceInfo { public: OpenCLRBTorsionForceInfo(int requiredBuffers, const RBTorsionForce& force) : OpenCLForceInfo(requiredBuffers), force(force) { } int getNumParticleGroups() { return force.getNumTorsions(); } void getParticlesInGroup(int index, std::vector& particles) { int particle1, particle2, particle3, particle4; double c0, c1, c2, c3, c4, c5; force.getTorsionParameters(index, particle1, particle2, particle3, particle4, c0, c1, c2, c3, c4, c5); particles.resize(4); particles[0] = particle1; particles[1] = particle2; particles[2] = particle3; particles[3] = particle4; } bool areGroupsIdentical(int group1, int group2) { int particle1, particle2, particle3, particle4; double c0a, c0b, c1a, c1b, c2a, c2b, c3a, c3b, c4a, c4b, c5a, c5b; force.getTorsionParameters(group1, particle1, particle2, particle3, particle4, c0a, c1a, c2a, c3a, c4a, c5a); force.getTorsionParameters(group1, particle1, particle2, particle3, particle4, c0b, c1b, c2b, c3b, c4b, c5b); return (c0a == c0b && c1a == c1b && c2a == c2b && c3a == c3b && c4a == c4b && c5a == c5b); } private: const RBTorsionForce& force; }; OpenCLCalcRBTorsionForceKernel::~OpenCLCalcRBTorsionForceKernel() { if (params != NULL) delete params; if (indices != NULL) delete indices; } void OpenCLCalcRBTorsionForceKernel::initialize(const System& system, const RBTorsionForce& force) { numTorsions = force.getNumTorsions(); params = new OpenCLArray(cl, numTorsions, "rbTorsionParams"); indices = new OpenCLArray(cl, numTorsions, "rbTorsionIndices"); vector forceBufferCounter(system.getNumParticles(), 0); vector paramVector(numTorsions); vector indicesVector(numTorsions); for (int i = 0; i < numTorsions; i++) { int particle1, particle2, particle3, particle4; double c0, c1, c2, c3, c4, c5; force.getTorsionParameters(i, particle1, particle2, particle3, particle4, c0, c1, c2, c3, c4, c5); paramVector[i] = (mm_float8) {c0, c1, c2, c3, c4, c5}; indicesVector[i] = (mm_int8) {particle1, particle2, particle3, particle4, forceBufferCounter[particle1]++, forceBufferCounter[particle2]++, forceBufferCounter[particle3]++, forceBufferCounter[particle4]++}; } params->upload(paramVector); indices->upload(indicesVector); int maxBuffers = 1; for (int i = 0; i < forceBufferCounter.size(); i++) maxBuffers = max(maxBuffers, forceBufferCounter[i]); cl.addForce(new OpenCLRBTorsionForceInfo(maxBuffers, force)); cl::Program program = cl.createProgram(cl.loadSourceFromFile("rbTorsionForce.cl")); kernel = cl::Kernel(program, "calcRBTorsionForce"); } void OpenCLCalcRBTorsionForceKernel::executeForces(ContextImpl& context) { kernel.setArg(0, cl.getPaddedNumAtoms()); kernel.setArg(1, numTorsions); kernel.setArg(2, cl.getForceBuffers().getDeviceBuffer()); kernel.setArg(3, cl.getEnergyBuffer().getDeviceBuffer()); kernel.setArg(4, cl.getPosq().getDeviceBuffer()); kernel.setArg(5, params->getDeviceBuffer()); kernel.setArg(6, indices->getDeviceBuffer()); cl.executeKernel(kernel, numTorsions); } double OpenCLCalcRBTorsionForceKernel::executeEnergy(ContextImpl& context) { executeForces(context); return 0.0; } class OpenCLNonbondedForceInfo : public OpenCLForceInfo { public: OpenCLNonbondedForceInfo(int requiredBuffers, const NonbondedForce& force) : OpenCLForceInfo(requiredBuffers), force(force) { } bool areParticlesIdentical(int particle1, int particle2) { double charge1, charge2, sigma1, sigma2, epsilon1, epsilon2; force.getParticleParameters(particle1, charge1, sigma1, epsilon1); force.getParticleParameters(particle2, charge2, sigma2, epsilon2); return (charge1 == charge2 && sigma1 == sigma2 && epsilon1 == epsilon2); } int getNumParticleGroups() { return force.getNumExceptions(); } void getParticlesInGroup(int index, std::vector& particles) { int particle1, particle2; double chargeProd, sigma, epsilon; force.getExceptionParameters(index, particle1, particle2, chargeProd, sigma, epsilon); particles.resize(2); particles[0] = particle1; particles[1] = particle2; } bool areGroupsIdentical(int group1, int group2) { int particle1, particle2; double chargeProd1, chargeProd2, sigma1, sigma2, epsilon1, epsilon2; force.getExceptionParameters(group1, particle1, particle2, chargeProd1, sigma1, epsilon1); force.getExceptionParameters(group2, particle1, particle2, chargeProd2, sigma2, epsilon2); return (chargeProd1 == chargeProd2 && sigma1 == sigma2 && epsilon1 == epsilon2); } private: const NonbondedForce& force; }; OpenCLCalcNonbondedForceKernel::~OpenCLCalcNonbondedForceKernel() { if (sigmaEpsilon != NULL) delete sigmaEpsilon; if (exceptionParams != NULL) delete exceptionParams; if (exceptionIndices != NULL) delete exceptionIndices; } void OpenCLCalcNonbondedForceKernel::initialize(const System& system, const NonbondedForce& force) { // Identify which exceptions are 1-4 interactions. vector > exclusions; vector exceptions; for (int i = 0; i < force.getNumExceptions(); i++) { int particle1, particle2; double chargeProd, sigma, epsilon; force.getExceptionParameters(i, particle1, particle2, chargeProd, sigma, epsilon); exclusions.push_back(pair(particle1, particle2)); if (chargeProd != 0.0 || epsilon != 0.0) exceptions.push_back(i); } // Initialize nonbonded interactions. int numParticles = force.getNumParticles(); sigmaEpsilon = new OpenCLArray(cl, numParticles, "sigmaEpsilon"); OpenCLArray& posq = cl.getPosq(); vector sigmaEpsilonVector(numParticles); vector > exclusionList(numParticles); for (int i = 0; i < numParticles; i++) { double charge, sigma, epsilon; force.getParticleParameters(i, charge, sigma, epsilon); posq[i].w = (float) charge; sigmaEpsilonVector[i] = (mm_float2) {(float) (0.5*sigma), (float) (2.0*sqrt(epsilon))}; exclusionList[i].push_back(i); } for (int i = 0; i < (int) exclusions.size(); i++) { exclusionList[exclusions[i].first].push_back(exclusions[i].second); exclusionList[exclusions[i].second].push_back(exclusions[i].first); } posq.upload(); sigmaEpsilon->upload(sigmaEpsilonVector); bool useCutoff = (force.getNonbondedMethod() != NonbondedForce::NoCutoff); bool usePeriodic = (force.getNonbondedMethod() != NonbondedForce::NoCutoff && force.getNonbondedMethod() != NonbondedForce::CutoffNonPeriodic); map defines; if (useCutoff) { double reactionFieldK = pow(force.getCutoffDistance(), -3.0)*(force.getReactionFieldDielectric()-1.0)/(2.0*force.getReactionFieldDielectric()+1.0); double reactionFieldC = (1.0 / force.getCutoffDistance())*(3.0*force.getReactionFieldDielectric())/(2.0*force.getReactionFieldDielectric()+1.0); stringstream k, c; k.precision(8); c.precision(8); k << scientific << reactionFieldK << "f"; c << scientific << reactionFieldC << "f"; defines["REACTION_FIELD_K"] = k.str(); defines["REACTION_FIELD_C"] = c.str(); } // if (force.getNonbondedMethod() != NonbondedForce::NoCutoff) { // method = CUTOFF; // } // if (force.getNonbondedMethod() == NonbondedForce::CutoffPeriodic) { // method = PERIODIC; // } // if (force.getNonbondedMethod() == NonbondedForce::Ewald || force.getNonbondedMethod() == NonbondedForce::PME) { // double ewaldErrorTol = force.getEwaldErrorTolerance(); // double alpha = (1.0/force.getCutoffDistance())*std::sqrt(-std::log(ewaldErrorTol)); // double mx = boxVectors[0][0]/force.getCutoffDistance(); // double my = boxVectors[1][1]/force.getCutoffDistance(); // double mz = boxVectors[2][2]/force.getCutoffDistance(); // double pi = 3.1415926535897932385; // int kmaxx = (int)std::ceil(-(mx/pi)*std::log(ewaldErrorTol)); // int kmaxy = (int)std::ceil(-(my/pi)*std::log(ewaldErrorTol)); // int kmaxz = (int)std::ceil(-(mz/pi)*std::log(ewaldErrorTol)); // if (force.getNonbondedMethod() == NonbondedForce::Ewald) { // if (kmaxx%2 == 0) // kmaxx++; // if (kmaxy%2 == 0) // kmaxy++; // if (kmaxz%2 == 0) // kmaxz++; // gpuSetEwaldParameters(gpu, (float) alpha, kmaxx, kmaxy, kmaxz); // method = EWALD; // } // else { // int gridSizeX = -0.5*kmaxx*std::log(ewaldErrorTol); // int gridSizeY = -0.5*kmaxy*std::log(ewaldErrorTol); // int gridSizeZ = -0.5*kmaxz*std::log(ewaldErrorTol); // gpuSetPMEParameters(gpu, (float) alpha, gridSizeX, gridSizeY, gridSizeZ); // method = PARTICLE_MESH_EWALD; // } // } // data.nonbondedMethod = method; // gpuSetCoulombParameters(gpu, 138.935485f, particle, c6, c12, q, symbol, exclusionList, method); string source = cl.loadSourceFromFile("coulombLennardJones.cl", defines); cl.getNonbondedUtilities().addInteraction(useCutoff, usePeriodic, true, force.getCutoffDistance(), exclusionList, source); cl.getNonbondedUtilities().addParameter(OpenCLNonbondedUtilities::ParameterInfo("sigmaEpsilon", "float2", sizeof(cl_float2), sigmaEpsilon->getDeviceBuffer())); cutoffSquared = force.getCutoffDistance()*force.getCutoffDistance(); // Compute the Ewald self energy. ewaldSelfEnergy = 0.0; if (force.getNonbondedMethod() == NonbondedForce::Ewald || force.getNonbondedMethod() == NonbondedForce::PME) { // double selfEnergyScale = gpu->sim.epsfac*gpu->sim.alphaEwald/std::sqrt(PI); // for (int i = 0; i < numParticles; i++) // ewaldSelfEnergy -= selfEnergyScale*q[i]*q[i]; } // Initialize the exceptions. int numExceptions = exceptions.size(); int maxBuffers = cl.getNonbondedUtilities().getNumForceBuffers(); if (numExceptions > 0) { exceptionParams = new OpenCLArray(cl, numExceptions, "exceptionParams"); exceptionIndices = new OpenCLArray(cl, numExceptions, "exceptionIndices"); vector exceptionParamsVector(numExceptions); vector exceptionIndicesVector(numExceptions); vector forceBufferCounter(system.getNumParticles(), 0); for (int i = 0; i < numExceptions; i++) { int particle1, particle2; double chargeProd, sigma, epsilon; force.getExceptionParameters(exceptions[i], particle1, particle2, chargeProd, sigma, epsilon); exceptionParamsVector[i] = (mm_float4) {(float) (138.935485*chargeProd), (float) sigma, (float) (4.0*epsilon), 0.0f}; exceptionIndicesVector[i] = (mm_int4) {particle1, particle2, forceBufferCounter[particle1]++, forceBufferCounter[particle2]++}; } exceptionParams->upload(exceptionParamsVector); exceptionIndices->upload(exceptionIndicesVector); for (int i = 0; i < forceBufferCounter.size(); i++) maxBuffers = max(maxBuffers, forceBufferCounter[i]); } cl.addForce(new OpenCLNonbondedForceInfo(maxBuffers, force)); if (useCutoff) { defines["USE_CUTOFF"] = "1"; } if (usePeriodic) defines["USE_PERIODIC"] = "1"; cl::Program program = cl.createProgram(cl.loadSourceFromFile("nonbondedExceptions.cl"), defines); exceptionsKernel = cl::Kernel(program, "computeNonbondedExceptions"); } void OpenCLCalcNonbondedForceKernel::executeForces(ContextImpl& context) { if (exceptionIndices != NULL) { int numExceptions = exceptionIndices->getSize(); exceptionsKernel.setArg(0, cl.getPaddedNumAtoms()); exceptionsKernel.setArg(1, numExceptions); exceptionsKernel.setArg(2, cutoffSquared); exceptionsKernel.setArg(3, cl.getNonbondedUtilities().getPeriodicBoxSize()); exceptionsKernel.setArg(4, cl.getForceBuffers().getDeviceBuffer()); exceptionsKernel.setArg(5, cl.getEnergyBuffer().getDeviceBuffer()); exceptionsKernel.setArg(6, cl.getPosq().getDeviceBuffer()); exceptionsKernel.setArg(7, exceptionParams->getDeviceBuffer()); exceptionsKernel.setArg(8, exceptionIndices->getDeviceBuffer()); cl.executeKernel(exceptionsKernel, numExceptions); } } double OpenCLCalcNonbondedForceKernel::executeEnergy(ContextImpl& context) { executeForces(context); return ewaldSelfEnergy; } //OpenCLCalcCustomNonbondedForceKernel::~OpenCLCalcCustomNonbondedForceKernel() { //} // //void OpenCLCalcCustomNonbondedForceKernel::initialize(const System& system, const CustomNonbondedForce& force) { // data.primaryKernel = this; // This must always be the primary kernel so it can update the global parameters // data.hasCustomNonbonded = true; // numParticles = force.getNumParticles(); // _gpuContext* gpu = data.gpu; // // // Identify which exceptions are actual interactions. // // vector > exclusions; // vector exceptions; // { // vector parameters; // for (int i = 0; i < force.getNumExceptions(); i++) { // int particle1, particle2; // force.getExceptionParameters(i, particle1, particle2, parameters); // exclusions.push_back(pair(particle1, particle2)); // if (parameters.size() > 0) // exceptions.push_back(i); // } // } // // // Initialize nonbonded interactions. // // vector particle(numParticles); // vector > parameters(numParticles); // vector > exclusionList(numParticles); // for (int i = 0; i < numParticles; i++) { // force.getParticleParameters(i, parameters[i]); // particle[i] = i; // exclusionList[i].push_back(i); // } // for (int i = 0; i < (int)exclusions.size(); i++) { // exclusionList[exclusions[i].first].push_back(exclusions[i].second); // exclusionList[exclusions[i].second].push_back(exclusions[i].first); // } // Vec3 boxVectors[3]; // system.getPeriodicBoxVectors(boxVectors[0], boxVectors[1], boxVectors[2]); // gpuSetPeriodicBoxSize(gpu, (float)boxVectors[0][0], (float)boxVectors[1][1], (float)boxVectors[2][2]); // OpenCLNonbondedMethod method = NO_CUTOFF; // if (force.getNonbondedMethod() != CustomNonbondedForce::NoCutoff) // method = CUTOFF; // if (force.getNonbondedMethod() == CustomNonbondedForce::CutoffPeriodic) { // method = PERIODIC; // } // data.customNonbondedMethod = method; // // // Initialize exceptions. // // int numExceptions = exceptions.size(); // vector exceptionParticle1(numExceptions); // vector exceptionParticle2(numExceptions); // vector > exceptionParams(numExceptions); // for (int i = 0; i < numExceptions; i++) // force.getExceptionParameters(exceptions[i], exceptionParticle1[i], exceptionParticle2[i], exceptionParams[i]); // // // Record the tabulated functions. // // for (int i = 0; i < force.getNumFunctions(); i++) { // string name; // vector values; // double min, max; // bool interpolating; // force.getFunctionParameters(i, name, values, min, max, interpolating); // gpuSetTabulatedFunction(gpu, i, name, values, min, max, interpolating); // } // // // Record information for the expressions. // // vector paramNames; // vector combiningRules; // for (int i = 0; i < force.getNumParameters(); i++) { // paramNames.push_back(force.getParameterName(i)); // combiningRules.push_back(force.getParameterCombiningRule(i)); // } // globalParamNames.resize(force.getNumGlobalParameters()); // globalParamValues.resize(force.getNumGlobalParameters()); // for (int i = 0; i < force.getNumGlobalParameters(); i++) { // globalParamNames[i] = force.getGlobalParameterName(i); // globalParamValues[i] = force.getGlobalParameterDefaultValue(i); // } // gpuSetCustomNonbondedParameters(gpu, parameters, exclusionList, exceptionParticle1, exceptionParticle2, exceptionParams, method, // (float)force.getCutoffDistance(), force.getEnergyFunction(), combiningRules, paramNames, globalParamNames); // if (globalParamValues.size() > 0) // SetCustomNonbondedGlobalParams(&globalParamValues[0]); //} // //void OpenCLCalcCustomNonbondedForceKernel::executeForces(ContextImpl& context) { // if (data.primaryKernel == this) { // updateGlobalParams(context); // calcForces(context, data); // } //} // //double OpenCLCalcCustomNonbondedForceKernel::executeEnergy(ContextImpl& context) { // if (data.primaryKernel == this) { // updateGlobalParams(context); // return calcEnergy(context, data, system); // } // return 0.0; //} // //void OpenCLCalcCustomNonbondedForceKernel::updateGlobalParams(ContextImpl& context) { // bool changed = false; // for (int i = 0; i < globalParamNames.size(); i++) { // float value = (float) context.getParameter(globalParamNames[i]); // if (value != globalParamValues[i]) // changed = true; // globalParamValues[i] = value; // } // if (changed) // SetCustomNonbondedGlobalParams(&globalParamValues[0]); //} // class OpenCLGBSAOBCForceInfo : public OpenCLForceInfo { public: OpenCLGBSAOBCForceInfo(int requiredBuffers, const GBSAOBCForce& force) : OpenCLForceInfo(requiredBuffers), force(force) { } bool areParticlesIdentical(int particle1, int particle2) { double charge1, charge2, radius1, radius2, scale1, scale2; force.getParticleParameters(particle1, charge1, radius1, scale1); force.getParticleParameters(particle2, charge2, radius2, scale2); return (charge1 == charge2 && radius1 == radius2 && scale1 == scale2); } private: const GBSAOBCForce& force; }; OpenCLCalcGBSAOBCForceKernel::~OpenCLCalcGBSAOBCForceKernel() { if (params != NULL) delete params; if (bornSum != NULL) delete bornSum; if (bornRadii != NULL) delete bornRadii; if (bornForce != NULL) delete bornForce; if (obcChain != NULL) delete obcChain; } void OpenCLCalcGBSAOBCForceKernel::initialize(const System& system, const GBSAOBCForce& force) { OpenCLNonbondedUtilities& nb = cl.getNonbondedUtilities(); params = new OpenCLArray(cl, cl.getPaddedNumAtoms(), "gbsaObcParams"); bornRadii = new OpenCLArray(cl, cl.getPaddedNumAtoms(), "bornRadii"); obcChain = new OpenCLArray(cl, cl.getPaddedNumAtoms(), "obcChain"); bornSum = new OpenCLArray(cl, cl.getPaddedNumAtoms()*nb.getNumForceBuffers(), "bornSum"); bornForce = new OpenCLArray(cl, cl.getPaddedNumAtoms()*nb.getNumForceBuffers(), "bornForce"); OpenCLArray& posq = cl.getPosq(); int numParticles = force.getNumParticles(); vector paramsVector(numParticles); const double dielectricOffset = 0.009; for (int i = 0; i < numParticles; i++) { double charge, radius, scalingFactor; force.getParticleParameters(i, charge, radius, scalingFactor); radius -= dielectricOffset; paramsVector[i] = (mm_float2) {(float) radius, (float) (scalingFactor*radius)}; posq[i].w = (float) charge; } posq.upload(); params->upload(paramsVector); prefactor = 2.0*-166.02691*0.4184*((1.0/force.getSoluteDielectric())-(1.0/force.getSolventDielectric())); bool useCutoff = (force.getNonbondedMethod() != GBSAOBCForce::NoCutoff); bool usePeriodic = (force.getNonbondedMethod() != GBSAOBCForce::NoCutoff && force.getNonbondedMethod() != GBSAOBCForce::CutoffNonPeriodic); string source = cl.loadSourceFromFile("gbsaObc2.cl"); nb.addInteraction(useCutoff, usePeriodic, false, force.getCutoffDistance(), vector >(), source); nb.addParameter(OpenCLNonbondedUtilities::ParameterInfo("obcParams", "float2", sizeof(cl_float2), params->getDeviceBuffer()));; nb.addParameter(OpenCLNonbondedUtilities::ParameterInfo("bornForce", "float", sizeof(cl_float), bornForce->getDeviceBuffer()));; cl.addForce(new OpenCLGBSAOBCForceInfo(nb.getNumForceBuffers(), force)); } void OpenCLCalcGBSAOBCForceKernel::executeForces(ContextImpl& context) { OpenCLNonbondedUtilities& nb = cl.getNonbondedUtilities(); if (!hasCreatedKernels) { // These Kernels cannot be created in initialize(), because the OpenCLNonbondedUtilities has not been initialized yet then. hasCreatedKernels = true; map defines; if (nb.getForceBufferPerAtomBlock()) defines["USE_OUTPUT_BUFFER_PER_BLOCK"] = "1"; if (nb.getUseCutoff()) defines["USE_CUTOFF"] = "1"; if (nb.getUsePeriodic()) defines["USE_PERIODIC"] = "1"; stringstream xsize, ysize, zsize, cutoffSquared, prefac; xsize.precision(8); ysize.precision(8); zsize.precision(8); cutoffSquared.precision(8); prefac.precision(8); xsize << scientific << nb.getPeriodicBoxSize().x << "f"; ysize << scientific << nb.getPeriodicBoxSize().y << "f"; zsize << scientific << nb.getPeriodicBoxSize().z << "f"; cutoffSquared << scientific << (nb.getCutoffDistance()*nb.getCutoffDistance()) << "f"; prefac << scientific << prefactor << "f"; defines["PERIODIC_BOX_SIZE_X"] = xsize.str(); defines["PERIODIC_BOX_SIZE_Y"] = ysize.str(); defines["PERIODIC_BOX_SIZE_Z"] = zsize.str(); defines["CUTOFF_SQUARED"] = cutoffSquared.str(); defines["PREFACTOR"] = prefac.str(); stringstream natom, padded; natom << cl.getNumAtoms(); padded << cl.getPaddedNumAtoms(); defines["NUM_ATOMS"] = natom.str(); defines["PADDED_NUM_ATOMS"] = padded.str(); cl::Program program = cl.createProgram(cl.loadSourceFromFile("gbsaObc.cl"), defines); computeBornSumKernel = cl::Kernel(program, "computeBornSum"); computeBornSumKernel.setArg(0, bornSum->getDeviceBuffer()); computeBornSumKernel.setArg(1, OpenCLContext::ThreadBlockSize*sizeof(cl_float), NULL); computeBornSumKernel.setArg(2, cl.getPosq().getDeviceBuffer()); computeBornSumKernel.setArg(3, OpenCLContext::ThreadBlockSize*sizeof(cl_float4), NULL); computeBornSumKernel.setArg(4, params->getDeviceBuffer()); computeBornSumKernel.setArg(5, OpenCLContext::ThreadBlockSize*sizeof(cl_float2), NULL); if (nb.getUseCutoff()) { computeBornSumKernel.setArg(6, nb.getInteractingTiles().getDeviceBuffer()); computeBornSumKernel.setArg(7, nb.getInteractionFlags().getDeviceBuffer()); computeBornSumKernel.setArg(8, nb.getInteractionCount().getDeviceBuffer()); computeBornSumKernel.setArg(9, OpenCLContext::ThreadBlockSize*sizeof(cl_float), NULL); } else { computeBornSumKernel.setArg(6, nb.getTiles().getDeviceBuffer()); computeBornSumKernel.setArg(7, nb.getTiles().getSize()); } reduceBornSumKernel = cl::Kernel(program, "reduceBornSum"); reduceBornSumKernel.setArg(0, cl.getPaddedNumAtoms()); reduceBornSumKernel.setArg(1, cl.getNumForceBuffers()); reduceBornSumKernel.setArg(2, 1.0f); reduceBornSumKernel.setArg(3, 0.8f); reduceBornSumKernel.setArg(4, 4.85f); reduceBornSumKernel.setArg(5, bornSum->getDeviceBuffer()); reduceBornSumKernel.setArg(6, params->getDeviceBuffer()); reduceBornSumKernel.setArg(7, bornRadii->getDeviceBuffer()); reduceBornSumKernel.setArg(8, obcChain->getDeviceBuffer()); force1Kernel = cl::Kernel(program, "computeGBSAForce1"); force1Kernel.setArg(0, cl.getForceBuffers().getDeviceBuffer()); force1Kernel.setArg(1, cl.getEnergyBuffer().getDeviceBuffer()); force1Kernel.setArg(2, cl.getPosq().getDeviceBuffer()); force1Kernel.setArg(3, OpenCLContext::ThreadBlockSize*sizeof(cl_float4), NULL); force1Kernel.setArg(4, OpenCLContext::ThreadBlockSize*sizeof(cl_float4), NULL); force1Kernel.setArg(5, bornRadii->getDeviceBuffer()); force1Kernel.setArg(6, OpenCLContext::ThreadBlockSize*sizeof(cl_float), NULL); force1Kernel.setArg(7, bornForce->getDeviceBuffer()); force1Kernel.setArg(8, OpenCLContext::ThreadBlockSize*sizeof(cl_float), NULL); if (nb.getUseCutoff()) { force1Kernel.setArg(9, nb.getInteractingTiles().getDeviceBuffer()); force1Kernel.setArg(10, nb.getInteractionFlags().getDeviceBuffer()); force1Kernel.setArg(11, nb.getInteractionCount().getDeviceBuffer()); force1Kernel.setArg(12, OpenCLContext::ThreadBlockSize*sizeof(mm_float4), NULL); } else { force1Kernel.setArg(9, nb.getTiles().getDeviceBuffer()); force1Kernel.setArg(10, nb.getTiles().getSize()); } reduceBornForceKernel = cl::Kernel(program, "reduceBornForce"); reduceBornForceKernel.setArg(0, cl.getPaddedNumAtoms()); reduceBornForceKernel.setArg(1, cl.getNumForceBuffers()); reduceBornForceKernel.setArg(2, bornForce->getDeviceBuffer()); reduceBornForceKernel.setArg(3, cl.getEnergyBuffer().getDeviceBuffer()); reduceBornForceKernel.setArg(4, params->getDeviceBuffer()); reduceBornForceKernel.setArg(5, bornRadii->getDeviceBuffer()); reduceBornForceKernel.setArg(6, obcChain->getDeviceBuffer()); } cl.clearBuffer(*bornSum); cl.clearBuffer(*bornForce); cl.executeKernel(computeBornSumKernel, nb.getTiles().getSize()*OpenCLContext::TileSize); cl.executeKernel(reduceBornSumKernel, cl.getPaddedNumAtoms()); cl.executeKernel(force1Kernel, cl.getPaddedNumAtoms()); cl.executeKernel(reduceBornForceKernel, cl.getPaddedNumAtoms()); } double OpenCLCalcGBSAOBCForceKernel::executeEnergy(ContextImpl& context) { executeForces(context); return 0.0; } OpenCLIntegrateVerletStepKernel::~OpenCLIntegrateVerletStepKernel() { } void OpenCLIntegrateVerletStepKernel::initialize(const System& system, const VerletIntegrator& integrator) { cl.initialize(system); cl::Program program = cl.createProgram(cl.loadSourceFromFile("verlet.cl")); kernel1 = cl::Kernel(program, "integrateVerletPart1"); kernel2 = cl::Kernel(program, "integrateVerletPart2"); } void OpenCLIntegrateVerletStepKernel::execute(ContextImpl& context, const VerletIntegrator& integrator) { OpenCLIntegrationUtilities& integration = cl.getIntegrationUtilties(); int numAtoms = cl.getNumAtoms(); double dt = integrator.getStepSize(); // Call the first integration kernel. kernel1.setArg(0, numAtoms); kernel1.setArg(1, dt); kernel1.setArg(2, cl.getPosq().getDeviceBuffer()); kernel1.setArg(3, cl.getVelm().getDeviceBuffer()); kernel1.setArg(4, cl.getForce().getDeviceBuffer()); kernel1.setArg(5, integration.getPosDelta().getDeviceBuffer()); cl.executeKernel(kernel1, numAtoms); // Apply constraints. integration.applyConstraints(integrator.getConstraintTolerance()); // Call the second integration kernel. kernel2.setArg(0, numAtoms); kernel2.setArg(1, dt); kernel2.setArg(2, cl.getPosq().getDeviceBuffer()); kernel2.setArg(3, cl.getVelm().getDeviceBuffer()); kernel2.setArg(4, integration.getPosDelta().getDeviceBuffer()); cl.executeKernel(kernel2, numAtoms); // Update the time and step count. cl.setTime(cl.getTime()+dt); cl.setStepCount(cl.getStepCount()+1); } OpenCLIntegrateLangevinStepKernel::~OpenCLIntegrateLangevinStepKernel() { if (params != NULL) delete params; if (xVector != NULL) delete xVector; if (vVector != NULL) delete vVector; } void OpenCLIntegrateLangevinStepKernel::initialize(const System& system, const LangevinIntegrator& integrator) { cl.initialize(system); cl.getIntegrationUtilties().initRandomNumberGenerator(integrator.getRandomNumberSeed()); cl::Program program = cl.createProgram(cl.loadSourceFromFile("langevin.cl")); kernel1 = cl::Kernel(program, "integrateLangevinPart1"); kernel2 = cl::Kernel(program, "integrateLangevinPart2"); kernel3 = cl::Kernel(program, "integrateLangevinPart3"); params = new OpenCLArray(cl, 11, "langevinParams"); xVector = new OpenCLArray(cl, cl.getPaddedNumAtoms(), "xVector"); vVector = new OpenCLArray(cl, cl.getPaddedNumAtoms(), "vVector"); vector initialXVector(xVector->getSize(), (mm_float4) {0.0f, 0.0f, 0.0f, 0.0f}); xVector->upload(initialXVector); prevStepSize = -1.0; } void OpenCLIntegrateLangevinStepKernel::execute(ContextImpl& context, const LangevinIntegrator& integrator) { OpenCLIntegrationUtilities& integration = cl.getIntegrationUtilties(); int numAtoms = cl.getNumAtoms(); int numThreads = cl.getNumThreadBlocks()*cl.ThreadBlockSize; double temperature = integrator.getTemperature(); double friction = integrator.getFriction(); double stepSize = integrator.getStepSize(); if (temperature != prevTemp || friction != prevFriction || stepSize != prevStepSize) { // Calculate the integration parameters. double tau = (friction == 0.0 ? 0.0 : 1.0/friction); double kT = BOLTZ*temperature; double GDT = stepSize/tau; double EPH = exp(0.5*GDT); double EMH = exp(-0.5*GDT); double EP = exp(GDT); double EM = exp(-GDT); double B, C, D; if (GDT >= 0.1) { double term1 = EPH - 1.0; term1 *= term1; B = GDT*(EP - 1.0) - 4.0*term1; C = GDT - 3.0 + 4.0*EMH - EM; D = 2.0 - EPH - EMH; } else { double term1 = 0.5*GDT; double term2 = term1*term1; double term4 = term2*term2; double third = 1.0/3.0; double o7_9 = 7.0/9.0; double o1_12 = 1.0/12.0; double o17_90 = 17.0/90.0; double o7_30 = 7.0/30.0; double o31_1260 = 31.0/1260.0; double o_360 = 1.0/360.0; B = term4*(third + term1*(third + term1*(o17_90 + term1*o7_9))); C = term2*term1*(2.0*third + term1*(-0.5 + term1*(o7_30 + term1*(-o1_12 + term1*o31_1260)))); D = term2*(-1.0 + term2*(-o1_12 - term2*o_360)); } double DOverTauC = D/(tau*C); double TauOneMinusEM = tau*(1.0-EM); double TauDOverEMMinusOne = tau*D/(EM - 1.0); double fix1 = tau*(EPH - EMH); if (fix1 == 0.0) fix1 = stepSize; double oneOverFix1 = 1.0/fix1; double V = sqrt(kT*(1.0 - EM)); double X = tau*sqrt(kT*C); double Yv = sqrt(kT*B/C); double Yx = tau*sqrt(kT*B/(1.0 - EM)); vector p(params->getSize()); p[0] = EM; p[1] = EM; p[2] = DOverTauC; p[3] = TauOneMinusEM; p[4] = TauDOverEMMinusOne; p[5] = V; p[6] = X; p[7] = Yv; p[8] = Yx; p[9] = fix1; p[10] = oneOverFix1; params->upload(p); prevTemp = temperature; prevFriction = friction; prevStepSize = stepSize; } // Call the first integration kernel. kernel1.setArg(0, numAtoms); kernel1.setArg(1, cl.getVelm().getDeviceBuffer()); kernel1.setArg(2, cl.getForce().getDeviceBuffer()); kernel1.setArg(3, integration.getPosDelta().getDeviceBuffer()); kernel1.setArg(4, params->getDeviceBuffer()); kernel1.setArg(5, params->getSize()*sizeof(cl_float), NULL); kernel1.setArg(6, xVector->getDeviceBuffer()); kernel1.setArg(7, vVector->getDeviceBuffer()); kernel1.setArg(8,integration.getRandom().getDeviceBuffer()); kernel1.setArg(9, integration.prepareRandomNumbers(2*numThreads)); cl.executeKernel(kernel1, numAtoms); // Apply constraints. integration.applyConstraints(integrator.getConstraintTolerance()); // Call the second integration kernel. kernel2.setArg(0, numAtoms); kernel2.setArg(1, cl.getVelm().getDeviceBuffer()); kernel2.setArg(2, integration.getPosDelta().getDeviceBuffer()); kernel2.setArg(3, params->getDeviceBuffer()); kernel2.setArg(4, params->getSize()*sizeof(cl_float), NULL); kernel2.setArg(5, xVector->getDeviceBuffer()); kernel2.setArg(6, vVector->getDeviceBuffer()); kernel2.setArg(7,integration.getRandom().getDeviceBuffer()); kernel2.setArg(8, integration.prepareRandomNumbers(2*numThreads)); cl.executeKernel(kernel2, numAtoms); // Reapply constraints. integration.applyConstraints(integrator.getConstraintTolerance()); // Call the third integration kernel. kernel3.setArg(0, numAtoms); kernel3.setArg(1, cl.getPosq().getDeviceBuffer()); kernel3.setArg(2, integration.getPosDelta().getDeviceBuffer()); cl.executeKernel(kernel3, numAtoms); // Update the time and step count. cl.setTime(cl.getTime()+stepSize); cl.setStepCount(cl.getStepCount()+1); } // //OpenCLIntegrateBrownianStepKernel::~OpenCLIntegrateBrownianStepKernel() { //} // //void OpenCLIntegrateBrownianStepKernel::initialize(const System& system, const BrownianIntegrator& integrator) { // initializeIntegration(system, data, integrator); // _gpuContext* gpu = data.gpu; // gpu->seed = (unsigned long) integrator.getRandomNumberSeed(); // gpuInitializeRandoms(gpu); // prevStepSize = -1.0; //} // //void OpenCLIntegrateBrownianStepKernel::execute(ContextImpl& context, const BrownianIntegrator& integrator) { // _gpuContext* gpu = data.gpu; // double temperature = integrator.getTemperature(); // double friction = integrator.getFriction(); // double stepSize = integrator.getStepSize(); // if (temperature != prevTemp || friction != prevFriction || stepSize != prevStepSize) { // // Initialize the GPU parameters. // // double tau = (friction == 0.0 ? 0.0 : 1.0/friction); // gpuSetBrownianIntegrationParameters(gpu, (float) tau, (float) stepSize, (float) temperature); // gpuSetConstants(gpu); // kGenerateRandoms(gpu); // prevTemp = temperature; // prevFriction = friction; // prevStepSize = stepSize; // } // kBrownianUpdatePart1(gpu); // kApplyFirstShake(gpu); // kApplyFirstSettle(gpu); // kApplyFirstCCMA(gpu); // if (data.removeCM) // if (data.stepCount%data.cmMotionFrequency == 0) // gpu->bCalculateCM = true; // kBrownianUpdatePart2(gpu); // data.time += stepSize; // data.stepCount++; //} // //OpenCLIntegrateVariableVerletStepKernel::~OpenCLIntegrateVariableVerletStepKernel() { //} // //void OpenCLIntegrateVariableVerletStepKernel::initialize(const System& system, const VariableVerletIntegrator& integrator) { // initializeIntegration(system, data, integrator); // prevErrorTol = -1.0; //} // //void OpenCLIntegrateVariableVerletStepKernel::execute(ContextImpl& context, const VariableVerletIntegrator& integrator, double maxTime) { // _gpuContext* gpu = data.gpu; // double errorTol = integrator.getErrorTolerance(); // if (errorTol != prevErrorTol) { // // Initialize the GPU parameters. // // gpuSetVerletIntegrationParameters(gpu, 0.0f, (float) errorTol); // gpuSetConstants(gpu); // prevErrorTol = errorTol; // } // float maxStepSize = (float)(maxTime-data.time); // kSelectVerletStepSize(gpu, maxStepSize); // kVerletUpdatePart1(gpu); // kApplyFirstShake(gpu); // kApplyFirstSettle(gpu); // kApplyFirstCCMA(gpu); // if (data.removeCM) // if (data.stepCount%data.cmMotionFrequency == 0) // gpu->bCalculateCM = true; // kVerletUpdatePart2(gpu); // gpu->psStepSize->Download(); // data.time += (*gpu->psStepSize)[0].y; // if ((*gpu->psStepSize)[0].y == maxStepSize) // data.time = maxTime; // Avoid round-off error // data.stepCount++; //} // //OpenCLIntegrateVariableLangevinStepKernel::~OpenCLIntegrateVariableLangevinStepKernel() { //} // //void OpenCLIntegrateVariableLangevinStepKernel::initialize(const System& system, const VariableLangevinIntegrator& integrator) { // initializeIntegration(system, data, integrator); // _gpuContext* gpu = data.gpu; // gpu->seed = (unsigned long) integrator.getRandomNumberSeed(); // gpuInitializeRandoms(gpu); // prevErrorTol = -1.0; //} // //void OpenCLIntegrateVariableLangevinStepKernel::execute(ContextImpl& context, const VariableLangevinIntegrator& integrator, double maxTime) { // _gpuContext* gpu = data.gpu; // double temperature = integrator.getTemperature(); // double friction = integrator.getFriction(); // double errorTol = integrator.getErrorTolerance(); // if (temperature != prevTemp || friction != prevFriction || errorTol != prevErrorTol) { // // Initialize the GPU parameters. // // double tau = (friction == 0.0 ? 0.0 : 1.0/friction); // gpuSetLangevinIntegrationParameters(gpu, (float) tau, 0.0f, (float) temperature, errorTol); // gpuSetConstants(gpu); // kGenerateRandoms(gpu); // prevTemp = temperature; // prevFriction = friction; // prevErrorTol = errorTol; // } // float maxStepSize = (float)(maxTime-data.time); // kSelectLangevinStepSize(gpu, maxStepSize); // kLangevinUpdatePart1(gpu); // kApplyFirstShake(gpu); // kApplyFirstSettle(gpu); // kApplyFirstCCMA(gpu); // if (data.removeCM) // if (data.stepCount%data.cmMotionFrequency == 0) // gpu->bCalculateCM = true; // kLangevinUpdatePart2(gpu); // kApplySecondShake(gpu); // kApplySecondSettle(gpu); // kApplySecondCCMA(gpu); // gpu->psStepSize->Download(); // data.time += (*gpu->psStepSize)[0].y; // if ((*gpu->psStepSize)[0].y == maxStepSize) // data.time = maxTime; // Avoid round-off error // data.stepCount++; //} // //OpenCLApplyAndersenThermostatKernel::~OpenCLApplyAndersenThermostatKernel() { //} // //void OpenCLApplyAndersenThermostatKernel::initialize(const System& system, const AndersenThermostat& thermostat) { // _gpuContext* gpu = data.gpu; // gpu->seed = (unsigned long) thermostat.getRandomNumberSeed(); // gpuInitializeRandoms(gpu); // prevStepSize = -1.0; //} // //void OpenCLApplyAndersenThermostatKernel::execute(ContextImpl& context) { // _gpuContext* gpu = data.gpu; // double temperature = context.getParameter(AndersenThermostat::Temperature()); // double frequency = context.getParameter(AndersenThermostat::CollisionFrequency()); // double stepSize = context.getIntegrator().getStepSize(); // if (temperature != prevTemp || frequency != prevFrequency || stepSize != prevStepSize) { // // Initialize the GPU parameters. // // gpuSetAndersenThermostatParameters(gpu, (float) temperature, frequency); // gpuSetConstants(gpu); // kGenerateRandoms(gpu); // prevTemp = temperature; // prevFrequency = frequency; // prevStepSize = stepSize; // } // kCalculateAndersenThermostat(gpu); //} // void OpenCLCalcKineticEnergyKernel::initialize(const System& system) { int numParticles = system.getNumParticles(); masses.resize(numParticles); for (int i = 0; i < numParticles; ++i) masses[i] = system.getParticleMass(i); } double OpenCLCalcKineticEnergyKernel::execute(ContextImpl& context) { // We don't currently have a GPU kernel to do this, so we retrieve the velocities and calculate the energy // on the CPU. OpenCLArray& velm = cl.getVelm(); velm.download(); double energy = 0.0; for (size_t i = 0; i < masses.size(); ++i) { mm_float4 v = velm[i]; energy += masses[i]*(v.x*v.x+v.y*v.y+v.z*v.z); } return 0.5*energy; } // //void OpenCLRemoveCMMotionKernel::initialize(const System& system, const CMMotionRemover& force) { // data.removeCM = true; // data.cmMotionFrequency = force.getFrequency(); //} // //void OpenCLRemoveCMMotionKernel::execute(ContextImpl& context) { //}