Exemplo n.º 1
0
double ReferenceIntegrateRPMDStepKernel::computeKineticEnergy(ContextImpl& context, const RPMDIntegrator& integrator) {
    const System& system = context.getSystem();
    int numParticles = system.getNumParticles();
    vector<RealVec>& velData = extractVelocities(context);
    double energy = 0.0;
    for (int i = 0; i < numParticles; ++i) {
        double mass = system.getParticleMass(i);
        if (mass > 0) {
            RealVec v = velData[i];
            energy += mass*(v.dot(v));
        }
    }
    return 0.5*energy;
}
Exemplo n.º 2
0
void ReferenceIntegrateDrudeSCFStepKernel::minimize(ContextImpl& context, double tolerance) {
    // Record the initial positions and determine a normalization constant for scaling the tolerance.

    vector<RealVec>& pos = extractPositions(context);
    int numDrudeParticles = drudeParticles.size();
    double norm = 0.0;
    for (int i = 0; i < numDrudeParticles; i++) {
        RealVec p = pos[drudeParticles[i]];
        minimizerPos[3*i] = p[0];
        minimizerPos[3*i+1] = p[1];
        minimizerPos[3*i+2] = p[2];
        norm += p.dot(p);
    }
    norm /= numDrudeParticles;
    norm = (norm < 1 ? 1 : sqrt(norm));
    minimizerParams.epsilon = tolerance/norm;
    
    // Perform the minimization.

    lbfgsfloatval_t fx;
    MinimizerData data(context, drudeParticles);
    lbfgs(numDrudeParticles*3, minimizerPos, &fx, evaluate, NULL, &data, &minimizerParams);
}
Exemplo n.º 3
0
double CpuCalcNonbondedForceKernel::execute(ContextImpl& context, bool includeForces, bool includeEnergy, bool includeDirect, bool includeReciprocal) {
    if (!hasInitializedPme) {
        hasInitializedPme = true;
        useOptimizedPme = false;
        if (nonbondedMethod == PME) {
            // If available, use the optimized PME implementation.

            try {
                optimizedPme = getPlatform().createKernel(CalcPmeReciprocalForceKernel::Name(), context);
                optimizedPme.getAs<CalcPmeReciprocalForceKernel>().initialize(gridSize[0], gridSize[1], gridSize[2], numParticles, ewaldAlpha);
                useOptimizedPme = true;
            }
            catch (OpenMMException& ex) {
                // The CPU PME plugin isn't available.
            }
        }
    }
    AlignedArray<float>& posq = data.posq;
    vector<RealVec>& posData = extractPositions(context);
    vector<RealVec>& forceData = extractForces(context);
    RealVec boxSize = extractBoxSize(context);
    float floatBoxSize[3] = {(float) boxSize[0], (float) boxSize[1], (float) boxSize[2]};
    double energy = (includeReciprocal ? ewaldSelfEnergy : 0.0);
    bool ewald  = (nonbondedMethod == Ewald);
    bool pme  = (nonbondedMethod == PME);
    if (nonbondedMethod != NoCutoff) {
        // Determine whether we need to recompute the neighbor list.
        
        double padding = 0.15*nonbondedCutoff;
        bool needRecompute = false;
        double closeCutoff2 = 0.25*padding*padding;
        double farCutoff2 = 0.5*padding*padding;
        int maxNumMoved = numParticles/10;
        vector<int> moved;
        for (int i = 0; i < numParticles; i++) {
            RealVec delta = posData[i]-lastPositions[i];
            double dist2 = delta.dot(delta);
            if (dist2 > closeCutoff2) {
                moved.push_back(i);
                if (dist2 > farCutoff2 || moved.size() > maxNumMoved) {
                    needRecompute = true;
                    break;
                }
            }
        }
        if (!needRecompute && moved.size() > 0) {
            // Some particles have moved further than half the padding distance.  Look for pairs
            // that are missing from the neighbor list.

            int numMoved = moved.size();
            double cutoff2 = nonbondedCutoff*nonbondedCutoff;
            double paddedCutoff2 = (nonbondedCutoff+padding)*(nonbondedCutoff+padding);
            for (int i = 1; i < numMoved && !needRecompute; i++)
                for (int j = 0; j < i; j++) {
                    RealVec delta = posData[moved[i]]-posData[moved[j]];
                    if (delta.dot(delta) < cutoff2) {
                        // These particles should interact.  See if they are in the neighbor list.
                        
                        RealVec oldDelta = lastPositions[moved[i]]-lastPositions[moved[j]];
                        if (oldDelta.dot(oldDelta) > paddedCutoff2) {
                            needRecompute = true;
                            break;
                        }
                    }
                }
        }
        if (needRecompute) {
            neighborList->computeNeighborList(numParticles, posq, exclusions, floatBoxSize, data.isPeriodic, nonbondedCutoff+padding, data.threads);
            lastPositions = posData;
        }
        nonbonded->setUseCutoff(nonbondedCutoff, *neighborList, rfDielectric);
    }
    if (data.isPeriodic) {
        double minAllowedSize = 1.999999*nonbondedCutoff;
        if (boxSize[0] < minAllowedSize || boxSize[1] < minAllowedSize || boxSize[2] < minAllowedSize)
            throw OpenMMException("The periodic box size has decreased to less than twice the nonbonded cutoff.");
        nonbonded->setPeriodic(floatBoxSize);
    }
    if (ewald)
        nonbonded->setUseEwald(ewaldAlpha, kmax[0], kmax[1], kmax[2]);
    if (pme)
        nonbonded->setUsePME(ewaldAlpha, gridSize);
    if (useSwitchingFunction)
        nonbonded->setUseSwitchingFunction(switchingDistance);
    double nonbondedEnergy = 0;
    if (includeDirect)
        nonbonded->calculateDirectIxn(numParticles, &posq[0], posData, particleParams, exclusions, data.threadForce, includeEnergy ? &nonbondedEnergy : NULL, data.threads);
    if (includeReciprocal) {
        if (useOptimizedPme) {
            PmeIO io(&posq[0], &data.threadForce[0][0], numParticles);
            Vec3 periodicBoxSize(boxSize[0], boxSize[1], boxSize[2]);
            optimizedPme.getAs<CalcPmeReciprocalForceKernel>().beginComputation(io, periodicBoxSize, includeEnergy);
            nonbondedEnergy += optimizedPme.getAs<CalcPmeReciprocalForceKernel>().finishComputation(io);
        }
        else
            nonbonded->calculateReciprocalIxn(numParticles, &posq[0], posData, particleParams, exclusions, forceData, includeEnergy ? &nonbondedEnergy : NULL);
    }
    energy += nonbondedEnergy;
    if (includeDirect) {
        ReferenceBondForce refBondForce;
        ReferenceLJCoulomb14 nonbonded14;
        refBondForce.calculateForce(num14, bonded14IndexArray, posData, bonded14ParamArray, forceData, includeEnergy ? &energy : NULL, nonbonded14);
        if (data.isPeriodic)
            energy += dispersionCoefficient/(boxSize[0]*boxSize[1]*boxSize[2]);
    }
    return energy;
}
Exemplo n.º 4
0
double ReferenceCalcDrudeForceKernel::execute(ContextImpl& context, bool includeForces, bool includeEnergy) {
    vector<RealVec>& pos = extractPositions(context);
    vector<RealVec>& force = extractForces(context);
    int numParticles = particle.size();
    double energy = 0;
    
    // Compute the interactions from the harmonic springs.
    
    for (int i = 0; i < numParticles; i++) {
        int p = particle[i];
        int p1 = particle1[i];
        int p2 = particle2[i];
        int p3 = particle3[i];
        int p4 = particle4[i];
        
        RealOpenMM a1 = (p2 == -1 ? 1 : aniso12[i]);
        RealOpenMM a2 = (p3 == -1 || p4 == -1 ? 1 : aniso34[i]);
        RealOpenMM a3 = 3-a1-a2;
        RealOpenMM k3 = charge[i]*charge[i]/(polarizability[i]*a3);
        RealOpenMM k1 = charge[i]*charge[i]/(polarizability[i]*a1) - k3;
        RealOpenMM k2 = charge[i]*charge[i]/(polarizability[i]*a2) - k3;
        
        // Compute the isotropic force.
        
        RealVec delta = pos[p]-pos[p1];
        RealOpenMM r2 = delta.dot(delta);
        energy += 0.5*k3*r2;
        force[p] -= delta*k3;
        force[p1] += delta*k3;
        
        // Compute the first anisotropic force.
        
        if (p2 != -1) {
            RealVec dir = pos[p1]-pos[p2];
            RealOpenMM invDist = 1.0/sqrt(dir.dot(dir));
            dir *= invDist;
            RealOpenMM rprime = dir.dot(delta);
            energy += 0.5*k1*rprime*rprime;
            RealVec f1 = dir*(k1*rprime); 
            RealVec f2 = (delta-dir*rprime)*(k1*rprime*invDist);
            force[p] -= f1;
            force[p1] += f1-f2;
            force[p2] += f2;
        }
        
        // Compute the second anisotropic force.
        
        if (p3 != -1 && p4 != -1) {
            RealVec dir = pos[p3]-pos[p4];
            RealOpenMM invDist = 1.0/sqrt(dir.dot(dir));
            dir *= invDist;
            RealOpenMM rprime = dir.dot(delta);
            energy += 0.5*k2*rprime*rprime;
            RealVec f1 = dir*(k2*rprime);
            RealVec f2 = (delta-dir*rprime)*(k2*rprime*invDist);
            force[p] -= f1;
            force[p1] += f1;
            force[p3] -= f2;
            force[p4] += f2;
        }
    }
    
    // Compute the screened interaction between bonded dipoles.
    
    int numPairs = pair1.size();
    for (int i = 0; i < numPairs; i++) {
        int dipole1 = pair1[i];
        int dipole2 = pair2[i];
        int dipole1Particles[] = {particle[dipole1], particle1[dipole1]};
        int dipole2Particles[] = {particle[dipole2], particle1[dipole2]};
        for (int j = 0; j < 2; j++)
            for (int k = 0; k < 2; k++) {
                int p1 = dipole1Particles[j];
                int p2 = dipole2Particles[k];
                RealOpenMM chargeProduct = charge[dipole1]*charge[dipole2]*(j == k ? 1 : -1);
                RealVec delta = pos[p1]-pos[p2];
                RealOpenMM r = sqrt(delta.dot(delta));
                RealOpenMM u = r*pairThole[i]/pow(polarizability[dipole1]*polarizability[dipole2], 1.0/6.0);
                RealOpenMM screening = 1.0 - (1.0+0.5*u)*exp(-u);
                energy += ONE_4PI_EPS0*chargeProduct*screening/r;
                RealVec f = delta*(ONE_4PI_EPS0*chargeProduct*screening/(r*r*r));
                force[p1] += f;
                force[p2] -= f;
            }
    }
    return energy;
}
Exemplo n.º 5
0
void ReferenceIntegrateDrudeLangevinStepKernel::execute(ContextImpl& context, const DrudeLangevinIntegrator& integrator) {
    vector<RealVec>& pos = extractPositions(context);
    vector<RealVec>& vel = extractVelocities(context);
    vector<RealVec>& force = extractForces(context);
    
    // Update velocities of ordinary particles.
    
    const RealOpenMM vscale = exp(-integrator.getStepSize()*integrator.getFriction());
    const RealOpenMM fscale = (1-vscale)/integrator.getFriction();
    const RealOpenMM kT = BOLTZ*integrator.getTemperature();
    const RealOpenMM noisescale = sqrt(2*kT*integrator.getFriction())*sqrt(0.5*(1-vscale*vscale)/integrator.getFriction());
    for (int i = 0; i < (int) normalParticles.size(); i++) {
        int index = normalParticles[i];
        RealOpenMM invMass = particleInvMass[index];
        if (invMass != 0.0) {
            RealOpenMM sqrtInvMass = sqrt(invMass);
            for (int j = 0; j < 3; j++)
                vel[index][j] = vscale*vel[index][j] + fscale*invMass*force[index][j] + noisescale*sqrtInvMass*SimTKOpenMMUtilities::getNormallyDistributedRandomNumber();
        }
    }
    
    // Update velocities of Drude particle pairs.
    
    const RealOpenMM vscaleDrude = exp(-integrator.getStepSize()*integrator.getDrudeFriction());
    const RealOpenMM fscaleDrude = (1-vscaleDrude)/integrator.getDrudeFriction();
    const RealOpenMM kTDrude = BOLTZ*integrator.getDrudeTemperature();
    const RealOpenMM noisescaleDrude = sqrt(2*kTDrude*integrator.getDrudeFriction())*sqrt(0.5*(1-vscaleDrude*vscaleDrude)/integrator.getDrudeFriction());
    for (int i = 0; i < (int) pairParticles.size(); i++) {
        int p1 = pairParticles[i].first;
        int p2 = pairParticles[i].second;
        RealOpenMM mass1fract = pairInvTotalMass[i]/particleInvMass[p1];
        RealOpenMM mass2fract = pairInvTotalMass[i]/particleInvMass[p2];
        RealOpenMM sqrtInvTotalMass = sqrt(pairInvTotalMass[i]);
        RealOpenMM sqrtInvReducedMass = sqrt(pairInvReducedMass[i]);
        RealVec cmVel = vel[p1]*mass1fract+vel[p2]*mass2fract;
        RealVec relVel = vel[p2]-vel[p1];
        RealVec cmForce = force[p1]+force[p2];
        RealVec relForce = force[p2]*mass1fract - force[p1]*mass2fract;
        for (int j = 0; j < 3; j++) {
            cmVel[j] = vscale*cmVel[j] + fscale*pairInvTotalMass[i]*cmForce[j] + noisescale*sqrtInvTotalMass*SimTKOpenMMUtilities::getNormallyDistributedRandomNumber();
            relVel[j] = vscaleDrude*relVel[j] + fscaleDrude*pairInvReducedMass[i]*relForce[j] + noisescaleDrude*sqrtInvReducedMass*SimTKOpenMMUtilities::getNormallyDistributedRandomNumber();
        }
        vel[p1] = cmVel-relVel*mass2fract;
        vel[p2] = cmVel+relVel*mass1fract;
    }

    // Update the particle positions.
    
    int numParticles = particleInvMass.size();
    vector<RealVec> xPrime(numParticles);
    RealOpenMM dt = integrator.getStepSize();
    for (int i = 0; i < numParticles; i++)
        if (particleInvMass[i] != 0.0)
            xPrime[i] = pos[i]+vel[i]*dt;
    
    // Apply constraints.
    
    extractConstraints(context).apply(pos, xPrime, particleInvMass, integrator.getConstraintTolerance());
    
    // Record the constrained positions and velocities.
    
    RealOpenMM dtInv = 1.0/dt;
    for (int i = 0; i < numParticles; i++) {
        if (particleInvMass[i] != 0.0) {
            vel[i] = (xPrime[i]-pos[i])*dtInv;
            pos[i] = xPrime[i];
        }
    }

    // Apply hard wall constraints.

    const RealOpenMM maxDrudeDistance = integrator.getMaxDrudeDistance();
    if (maxDrudeDistance > 0) {
        const RealOpenMM hardwallscaleDrude = sqrt(kTDrude);
        for (int i = 0; i < (int) pairParticles.size(); i++) {
            int p1 = pairParticles[i].first;
            int p2 = pairParticles[i].second;
            RealVec delta = pos[p1]-pos[p2];
            RealOpenMM r = sqrt(delta.dot(delta));
            RealOpenMM rInv = 1/r;
            if (rInv*maxDrudeDistance < 1.0) {
                // The constraint has been violated, so make the inter-particle distance "bounce"
                // off the hard wall.
                
                if (rInv*maxDrudeDistance < 0.5)
                    throw OpenMMException("Drude particle moved too far beyond hard wall constraint");
                RealVec bondDir = delta*rInv;
                RealVec vel1 = vel[p1];
                RealVec vel2 = vel[p2];
                RealOpenMM mass1 = particleMass[p1];
                RealOpenMM mass2 = particleMass[p2];
                RealOpenMM deltaR = r-maxDrudeDistance;
                RealOpenMM deltaT = dt;
                RealOpenMM dotvr1 = vel1.dot(bondDir);
                RealVec vb1 = bondDir*dotvr1;
                RealVec vp1 = vel1-vb1;
                if (mass2 == 0) {
                    // The parent particle is massless, so move only the Drude particle.

                    if (dotvr1 != 0.0)
                        deltaT = deltaR/abs(dotvr1);
                    if (deltaT > dt)
                        deltaT = dt;
                    dotvr1 = -dotvr1*hardwallscaleDrude/(abs(dotvr1)*sqrt(mass1));
                    RealOpenMM dr = -deltaR + deltaT*dotvr1;
                    pos[p1] += bondDir*dr;
                    vel[p1] = vp1 + bondDir*dotvr1;
                }
                else {
                    // Move both particles.

                    RealOpenMM invTotalMass = pairInvTotalMass[i];
                    RealOpenMM dotvr2 = vel2.dot(bondDir);
                    RealVec vb2 = bondDir*dotvr2;
                    RealVec vp2 = vel2-vb2;
                    RealOpenMM vbCMass = (mass1*dotvr1 + mass2*dotvr2)*invTotalMass;
                    dotvr1 -= vbCMass;
                    dotvr2 -= vbCMass;
                    if (dotvr1 != dotvr2)
                        deltaT = deltaR/abs(dotvr1-dotvr2);
                    if (deltaT > dt)
                        deltaT = dt;
                    RealOpenMM vBond = hardwallscaleDrude/sqrt(mass1);
                    dotvr1 = -dotvr1*vBond*mass2*invTotalMass/abs(dotvr1);
                    dotvr2 = -dotvr2*vBond*mass1*invTotalMass/abs(dotvr2);
                    RealOpenMM dr1 = -deltaR*mass2*invTotalMass + deltaT*dotvr1;
                    RealOpenMM dr2 = deltaR*mass1*invTotalMass + deltaT*dotvr2;
                    dotvr1 += vbCMass;
                    dotvr2 += vbCMass;
                    pos[p1] += bondDir*dr1;
                    pos[p2] += bondDir*dr2;
                    vel[p1] = vp1 + bondDir*dotvr1;
                    vel[p2] = vp2 + bondDir*dotvr2;
                }
            }
        }
    }
    ReferenceVirtualSites::computePositions(context.getSystem(), pos);
    data.time += integrator.getStepSize();
    data.stepCount++;
}