/* -------------------------------------------------------------------------- * * 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) 2008-2013 Stanford University and the Authors. * * Authors: Peter Eastman * * Contributors: * * * * Permission is hereby granted, free of charge, to any person obtaining a * * copy of this software and associated documentation files (the "Software"), * * to deal in the Software without restriction, including without limitation * * the rights to use, copy, modify, merge, publish, distribute, sublicense, * * and/or sell copies of the Software, and to permit persons to whom the * * Software is furnished to do so, subject to the following conditions: * * * * The above copyright notice and this permission notice shall be included in * * all copies or substantial portions of the Software. * * * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * * THE AUTHORS, CONTRIBUTORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, * * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR * * OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE * * USE OR OTHER DEALINGS IN THE SOFTWARE. * * -------------------------------------------------------------------------- */ /** * This tests all the different force terms in the reference implementation of CustomGBForce. */ #include "openmm/internal/AssertionUtilities.h" #include "sfmt/SFMT.h" #include "openmm/Context.h" #include "ReferencePlatform.h" #include "openmm/CustomGBForce.h" #include "openmm/GBSAOBCForce.h" #include "openmm/GBVIForce.h" #include "openmm/OpenMMException.h" #include "openmm/System.h" #include "openmm/VerletIntegrator.h" #include #include #include using namespace OpenMM; using namespace std; const double TOL = 1e-5; void testOBC(GBSAOBCForce::NonbondedMethod obcMethod, CustomGBForce::NonbondedMethod customMethod) { const int numMolecules = 70; const int numParticles = numMolecules*2; const double boxSize = 10.0; const double cutoff = 2.0; ReferencePlatform platform; // Create two systems: one with a GBSAOBCForce, and one using a CustomGBForce to implement the same interaction. System standardSystem; System customSystem; for (int i = 0; i < numParticles; i++) { standardSystem.addParticle(1.0); customSystem.addParticle(1.0); } standardSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize)); customSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize)); GBSAOBCForce* obc = new GBSAOBCForce(); CustomGBForce* custom = new CustomGBForce(); obc->setCutoffDistance(cutoff); custom->setCutoffDistance(cutoff); custom->addPerParticleParameter("q"); custom->addPerParticleParameter("radius"); custom->addPerParticleParameter("scale"); custom->addGlobalParameter("solventDielectric", obc->getSolventDielectric()); custom->addGlobalParameter("soluteDielectric", obc->getSoluteDielectric()); custom->addComputedValue("I", "step(r+sr2-or1)*0.5*(1/L-1/U+0.25*(1/U^2-1/L^2)*(r-sr2*sr2/r)+0.5*log(L/U)/r+C);" "U=r+sr2;" "C=2*(1/or1-1/L)*step(sr2-r-or1);" "L=max(or1, D);" "D=abs(r-sr2);" "sr2 = scale2*or2;" "or1 = radius1-0.009; or2 = radius2-0.009", CustomGBForce::ParticlePairNoExclusions); custom->addComputedValue("B", "1/(1/or-tanh(1*psi-0.8*psi^2+4.85*psi^3)/radius);" "psi=I*or; or=radius-0.009", CustomGBForce::SingleParticle); custom->addEnergyTerm("28.3919551*(radius+0.14)^2*(radius/B)^6-0.5*138.935485*(1/soluteDielectric-1/solventDielectric)*q^2/B", CustomGBForce::SingleParticle); string invCutoffString = ""; if (obcMethod != GBSAOBCForce::NoCutoff) { stringstream s; s<<(1.0/cutoff); invCutoffString = s.str(); } custom->addEnergyTerm("138.935485*(1/soluteDielectric-1/solventDielectric)*q1*q2*("+invCutoffString+"-1/f);" "f=sqrt(r^2+B1*B2*exp(-r^2/(4*B1*B2)))", CustomGBForce::ParticlePairNoExclusions); vector positions(numParticles); vector velocities(numParticles); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); vector params(3); for (int i = 0; i < numMolecules; i++) { if (i < numMolecules/2) { obc->addParticle(1.0, 0.2, 0.5); params[0] = 1.0; params[1] = 0.2; params[2] = 0.5; custom->addParticle(params); obc->addParticle(-1.0, 0.1, 0.5); params[0] = -1.0; params[1] = 0.1; custom->addParticle(params); } else { obc->addParticle(1.0, 0.2, 0.8); params[0] = 1.0; params[1] = 0.2; params[2] = 0.8; custom->addParticle(params); obc->addParticle(-1.0, 0.1, 0.8); params[0] = -1.0; params[1] = 0.1; custom->addParticle(params); } positions[2*i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt)); positions[2*i+1] = Vec3(positions[2*i][0]+1.0, positions[2*i][1], positions[2*i][2]); velocities[2*i] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); velocities[2*i+1] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); } obc->setNonbondedMethod(obcMethod); custom->setNonbondedMethod(customMethod); standardSystem.addForce(obc); customSystem.addForce(custom); if (customMethod == CustomGBForce::CutoffPeriodic) { ASSERT(custom->usesPeriodicBoundaryConditions()); ASSERT(obc->usesPeriodicBoundaryConditions()); ASSERT(standardSystem.usesPeriodicBoundaryConditions()); ASSERT(customSystem.usesPeriodicBoundaryConditions()); } else { ASSERT(!custom->usesPeriodicBoundaryConditions()); ASSERT(!obc->usesPeriodicBoundaryConditions()); ASSERT(!standardSystem.usesPeriodicBoundaryConditions()); ASSERT(!customSystem.usesPeriodicBoundaryConditions()); } VerletIntegrator integrator1(0.01); VerletIntegrator integrator2(0.01); Context context1(standardSystem, integrator1, platform); context1.setPositions(positions); context1.setVelocities(velocities); State state1 = context1.getState(State::Forces | State::Energy); Context context2(customSystem, integrator2, platform); context2.setPositions(positions); context2.setVelocities(velocities); State state2 = context2.getState(State::Forces | State::Energy); ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), 1e-4); for (int i = 0; i < numParticles; i++) { ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], 1e-4); } // Try changing the particle parameters and make sure it's still correct. for (int i = 0; i < numMolecules/2; i++) { obc->setParticleParameters(2*i, 1.1, 0.3, 0.6); params[0] = 1.1; params[1] = 0.3; params[2] = 0.6; custom->setParticleParameters(2*i, params); obc->setParticleParameters(2*i+1, -1.1, 0.2, 0.4); params[0] = -1.1; params[1] = 0.2; params[2] = 0.4; custom->setParticleParameters(2*i+1, params); } obc->updateParametersInContext(context1); custom->updateParametersInContext(context2); state1 = context1.getState(State::Forces | State::Energy); state2 = context2.getState(State::Forces | State::Energy); ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), 1e-4); for (int i = 0; i < numParticles; i++) { ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], 1e-4); } } void testMembrane() { const int numMolecules = 70; const int numParticles = numMolecules*2; const double boxSize = 10.0; ReferencePlatform platform; // Create a system with an implicit membrane. System system; for (int i = 0; i < numParticles; i++) { system.addParticle(1.0); } system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize)); CustomGBForce* custom = new CustomGBForce(); custom->setCutoffDistance(2.0); custom->addPerParticleParameter("q"); custom->addPerParticleParameter("radius"); custom->addPerParticleParameter("scale"); custom->addGlobalParameter("thickness", 3); custom->addGlobalParameter("solventDielectric", 78.3); custom->addGlobalParameter("soluteDielectric", 1); custom->addComputedValue("Imol", "step(r+sr2-or1)*0.5*(1/L-1/U+0.25*(1/U^2-1/L^2)*(r-sr2*sr2/r)+0.5*log(L/U)/r+C);" "U=r+sr2;" "C=2*(1/or1-1/L)*step(sr2-r-or1);" "L=max(or1, D);" "D=abs(r-sr2);" "sr2 = scale2*or2;" "or1 = radius1-0.009; or2 = radius2-0.009", CustomGBForce::ParticlePairNoExclusions); custom->addComputedValue("Imem", "(1/radius+2*log(2)/thickness)/(1+exp(7.2*(abs(z)+radius-0.5*thickness)))", CustomGBForce::SingleParticle); custom->addComputedValue("B", "1/(1/or-tanh(1*psi-0.8*psi^2+4.85*psi^3)/radius);" "psi=max(Imol,Imem)*or; or=radius-0.009", CustomGBForce::SingleParticle); custom->addEnergyTerm("28.3919551*(radius+0.14)^2*(radius/B)^6-0.5*138.935456*(1/soluteDielectric-1/solventDielectric)*q^2/B", CustomGBForce::SingleParticle); custom->addEnergyTerm("-138.935456*(1/soluteDielectric-1/solventDielectric)*q1*q2/f;" "f=sqrt(r^2+B1*B2*exp(-r^2/(4*B1*B2)))", CustomGBForce::ParticlePairNoExclusions); vector positions(numParticles); vector velocities(numParticles); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); vector params(3); for (int i = 0; i < numMolecules; i++) { if (i < numMolecules/2) { params[0] = 1.0; params[1] = 0.2; params[2] = 0.5; custom->addParticle(params); params[0] = -1.0; params[1] = 0.1; custom->addParticle(params); } else { params[0] = 1.0; params[1] = 0.2; params[2] = 0.8; custom->addParticle(params); params[0] = -1.0; params[1] = 0.1; custom->addParticle(params); } positions[2*i] = Vec3(boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt), boxSize*genrand_real2(sfmt)); positions[2*i+1] = Vec3(positions[2*i][0]+1.0, positions[2*i][1], positions[2*i][2]); velocities[2*i] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); velocities[2*i+1] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); } system.addForce(custom); VerletIntegrator integrator(0.01); Context context(system, integrator, platform); context.setPositions(positions); context.setVelocities(velocities); State state = context.getState(State::Forces | State::Energy); const vector& forces = state.getForces(); // Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount. double norm = 0.0; for (int i = 0; i < (int) forces.size(); ++i) norm += forces[i].dot(forces[i]); norm = std::sqrt(norm); const double stepSize = 1e-2; double step = 0.5*stepSize/norm; vector positions2(numParticles), positions3(numParticles); for (int i = 0; i < (int) positions.size(); ++i) { Vec3 p = positions[i]; Vec3 f = forces[i]; positions2[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step); positions3[i] = Vec3(p[0]+f[0]*step, p[1]+f[1]*step, p[2]+f[2]*step); } context.setPositions(positions2); State state2 = context.getState(State::Energy); context.setPositions(positions3); State state3 = context.getState(State::Energy); ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state3.getPotentialEnergy())/stepSize, 1e-3); } void testTabulatedFunction() { ReferencePlatform platform; System system; system.addParticle(1.0); system.addParticle(1.0); VerletIntegrator integrator(0.01); CustomGBForce* force = new CustomGBForce(); force->addComputedValue("a", "0", CustomGBForce::ParticlePair); force->addEnergyTerm("fn(r)+1", CustomGBForce::ParticlePair); force->addParticle(vector()); force->addParticle(vector()); vector table; for (int i = 0; i < 21; i++) table.push_back(std::sin(0.25*i)); force->addTabulatedFunction("fn", new Continuous1DFunction(table, 1.0, 6.0)); system.addForce(force); Context context(system, integrator, platform); vector positions(2); positions[0] = Vec3(0, 0, 0); for (int i = 1; i < 30; i++) { double x = (7.0/30.0)*i; positions[1] = Vec3(x, 0, 0); context.setPositions(positions); State state = context.getState(State::Forces | State::Energy); const vector& forces = state.getForces(); double force = (x < 1.0 || x > 6.0 ? 0.0 : -std::cos(x-1.0)); double energy = (x < 1.0 || x > 6.0 ? 0.0 : std::sin(x-1.0))+1.0; ASSERT_EQUAL_VEC(Vec3(-force, 0, 0), forces[0], 0.1); ASSERT_EQUAL_VEC(Vec3(force, 0, 0), forces[1], 0.1); ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 0.02); } } void testMultipleChainRules() { ReferencePlatform platform; System system; system.addParticle(1.0); system.addParticle(1.0); VerletIntegrator integrator(0.01); CustomGBForce* force = new CustomGBForce(); force->addComputedValue("a", "2*r", CustomGBForce::ParticlePair); force->addComputedValue("b", "a+1", CustomGBForce::SingleParticle); force->addComputedValue("c", "2*b+a", CustomGBForce::SingleParticle); force->addEnergyTerm("0.1*a+1*b+10*c", CustomGBForce::SingleParticle); // 0.1*(2*r) + 2*r+1 + 10*(3*a+2) = 0.2*r + 2*r+1 + 40*r+20+20*r = 62.2*r+21 force->addParticle(vector()); force->addParticle(vector()); system.addForce(force); Context context(system, integrator, platform); vector positions(2); positions[0] = Vec3(0, 0, 0); for (int i = 1; i < 5; i++) { positions[1] = Vec3(i, 0, 0); context.setPositions(positions); State state = context.getState(State::Forces | State::Energy); const vector& forces = state.getForces(); ASSERT_EQUAL_VEC(Vec3(124.4, 0, 0), forces[0], 1e-4); ASSERT_EQUAL_VEC(Vec3(-124.4, 0, 0), forces[1], 1e-4); ASSERT_EQUAL_TOL(2*(62.2*i+21), state.getPotentialEnergy(), 0.02); } } void testPositionDependence() { ReferencePlatform platform; System system; system.addParticle(1.0); system.addParticle(1.0); VerletIntegrator integrator(0.01); CustomGBForce* force = new CustomGBForce(); force->addComputedValue("a", "r", CustomGBForce::ParticlePair); force->addComputedValue("b", "a+x*y", CustomGBForce::SingleParticle); force->addEnergyTerm("b*z", CustomGBForce::SingleParticle); force->addEnergyTerm("b1+b2", CustomGBForce::ParticlePair); // = 2*r+x1*y1+x2*y2 force->addParticle(vector()); force->addParticle(vector()); system.addForce(force); Context context(system, integrator, platform); vector positions(2); vector forces(2); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); for (int i = 0; i < 5; i++) { positions[0] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); positions[1] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); context.setPositions(positions); State state = context.getState(State::Forces | State::Energy); const vector& forces = state.getForces(); Vec3 delta = positions[0]-positions[1]; double r = sqrt(delta.dot(delta)); double energy = 2*r+positions[0][0]*positions[0][1]+positions[1][0]*positions[1][1]; for (int j = 0; j < 2; j++) energy += positions[j][2]*(r+positions[j][0]*positions[j][1]); Vec3 force1(-(1+positions[0][2])*delta[0]/r-(1+positions[0][2])*positions[0][1]-(1+positions[1][2])*delta[0]/r, -(1+positions[0][2])*delta[1]/r-(1+positions[0][2])*positions[0][0]-(1+positions[1][2])*delta[1]/r, -(1+positions[0][2])*delta[2]/r-(r+positions[0][0]*positions[0][1])-(1+positions[1][2])*delta[2]/r); Vec3 force2((1+positions[0][2])*delta[0]/r+(1+positions[1][2])*delta[0]/r-(1+positions[1][2])*positions[1][1], (1+positions[0][2])*delta[1]/r+(1+positions[1][2])*delta[1]/r-(1+positions[1][2])*positions[1][0], (1+positions[0][2])*delta[2]/r+(1+positions[1][2])*delta[2]/r-(r+positions[1][0]*positions[1][1])); ASSERT_EQUAL_VEC(force1, forces[0], 1e-4); ASSERT_EQUAL_VEC(force2, forces[1], 1e-4); ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 0.02); // Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount. double norm = 0.0; for (int i = 0; i < (int) forces.size(); ++i) norm += forces[i].dot(forces[i]); norm = std::sqrt(norm); const double stepSize = 1e-3; double step = 0.5*stepSize/norm; vector positions2(2), positions3(2); for (int i = 0; i < (int) positions.size(); ++i) { Vec3 p = positions[i]; Vec3 f = forces[i]; positions2[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step); positions3[i] = Vec3(p[0]+f[0]*step, p[1]+f[1]*step, p[2]+f[2]*step); } context.setPositions(positions2); State state2 = context.getState(State::Energy); context.setPositions(positions3); State state3 = context.getState(State::Energy); ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state3.getPotentialEnergy())/stepSize, 1e-3); } } void testExclusions() { ReferencePlatform platform; for (int i = 3; i < 4; i++) { System system; system.addParticle(1.0); system.addParticle(1.0); VerletIntegrator integrator(0.01); CustomGBForce* force = new CustomGBForce(); force->addComputedValue("a", "r", i < 2 ? CustomGBForce::ParticlePair : CustomGBForce::ParticlePairNoExclusions); force->addEnergyTerm("a", CustomGBForce::SingleParticle); force->addEnergyTerm("(1+a1+a2)*r", i%2 == 0 ? CustomGBForce::ParticlePair : CustomGBForce::ParticlePairNoExclusions); force->addParticle(vector()); force->addParticle(vector()); force->addExclusion(0, 1); system.addForce(force); Context context(system, integrator, platform); vector positions(2); positions[0] = Vec3(0, 0, 0); positions[1] = Vec3(1, 0, 0); context.setPositions(positions); State state = context.getState(State::Forces | State::Energy); const vector& forces = state.getForces(); double f, energy; switch (i) { case 0: // e = 0 f = 0; energy = 0; break; case 1: // e = r f = 1; energy = 1; break; case 2: // e = 2r f = 2; energy = 2; break; case 3: // e = 3r + 2r^2 f = 7; energy = 5; break; default: ASSERT(false); } ASSERT_EQUAL_VEC(Vec3(f, 0, 0), forces[0], 1e-4); ASSERT_EQUAL_VEC(Vec3(-f, 0, 0), forces[1], 1e-4); ASSERT_EQUAL_TOL(energy, state.getPotentialEnergy(), 1e-4); // Take a small step in the direction of the energy gradient and see whether the potential energy changes by the expected amount. double norm = 0.0; for (int i = 0; i < (int) forces.size(); ++i) norm += forces[i].dot(forces[i]); norm = std::sqrt(norm); const double stepSize = 1e-3; double step = stepSize/norm; for (int i = 0; i < (int) positions.size(); ++i) { Vec3 p = positions[i]; Vec3 f = forces[i]; positions[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step); } context.setPositions(positions); State state2 = context.getState(State::Energy); ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state.getPotentialEnergy())/stepSize, 1e-3*abs(state.getPotentialEnergy())); } } // create custom GB/VI force static CustomGBForce* createCustomGBVI(double solventDielectric, double soluteDielectric) { CustomGBForce* customGbviForce = new CustomGBForce(); customGbviForce->setCutoffDistance(2.0); customGbviForce->addPerParticleParameter("q"); customGbviForce->addPerParticleParameter("radius"); customGbviForce->addPerParticleParameter("scaleFactor"); // derived in GBVIForce implmentation, but parameter here customGbviForce->addPerParticleParameter("gamma"); customGbviForce->addGlobalParameter("solventDielectric", solventDielectric); customGbviForce->addGlobalParameter("soluteDielectric", soluteDielectric); customGbviForce->addComputedValue("V", " uL - lL + factor3/(radius1*radius1*radius1);" "uL = 1.5*x2uI*(0.25*rI-0.33333*xuI+0.125*(r2-S2)*rI*x2uI);" "lL = 1.5*x2lI*(0.25*rI-0.33333*xlI+0.125*(r2-S2)*rI*x2lI);" "x2lI = 1.0/(xl*xl);" "xlI = 1.0/(xl);" "xuI = 1.0/(xu);" "x2uI = 1.0/(xu*xu);" "xu = (r+scaleFactor2);" "rI = 1.0/(r);" "r2 = (r*r);" "xl = factor1*lMax + factor2*xuu + factor3*(r-scaleFactor2);" "xuu = (r+scaleFactor2);" "S2 = (scaleFactor2*scaleFactor2);" "factor1 = step(r-absRadiusScaleDiff);" "absRadiusScaleDiff = abs(radiusScaleDiff);" "radiusScaleDiff = (radius1-scaleFactor2);" "factor2 = step(radius1-scaleFactor2-r);" "factor3 = step(scaleFactor2-radius1-r);" "lMax = max(radius1,r-scaleFactor2);" , CustomGBForce::ParticlePairNoExclusions); customGbviForce->addComputedValue("B", "(1.0/(radius*radius*radius)-V)^(-0.33333333)", CustomGBForce::SingleParticle); // nonpolar term + polar self energy customGbviForce->addEnergyTerm("(-138.935485*0.5*((1.0/soluteDielectric)-(1.0/solventDielectric))*q^2/B)-((1.0/soluteDielectric)-(1.0/solventDielectric))*((gamma*(radius/B)^3))", CustomGBForce::SingleParticle); // polar pair energy customGbviForce->addEnergyTerm("-138.935485*(1/soluteDielectric-1/solventDielectric)*q1*q2/f;" "f=sqrt(r^2+B1*B2*exp(-r^2/(4*B1*B2)))", CustomGBForce::ParticlePairNoExclusions); return customGbviForce; } // ethance GB/VI test case static void buildEthane(GBVIForce* gbviForce, std::vector& positions) { const int numParticles = 8; double C_HBondDistance = 0.1097; double C_CBondDistance = 0.1504; double C_radius, C_gamma, C_charge, H_radius, H_gamma, H_charge; int AM1_BCC = 1; H_charge = -0.053; C_charge = -3.0*H_charge; if (AM1_BCC) { C_radius = 0.180; C_gamma = -0.2863; H_radius = 0.125; H_gamma = 0.2437; } else { C_radius = 0.215; C_gamma = -1.1087; H_radius = 0.150; H_gamma = 0.1237; } for (int i = 0; i < numParticles; i++) { gbviForce->addParticle(H_charge, H_radius, H_gamma); } gbviForce->setParticleParameters(1, C_charge, C_radius, C_gamma); gbviForce->setParticleParameters(4, C_charge, C_radius, C_gamma); gbviForce->addBond(0, 1, C_HBondDistance); gbviForce->addBond(2, 1, C_HBondDistance); gbviForce->addBond(3, 1, C_HBondDistance); gbviForce->addBond(1, 4, C_CBondDistance); gbviForce->addBond(5, 4, C_HBondDistance); gbviForce->addBond(6, 4, C_HBondDistance); gbviForce->addBond(7, 4, C_HBondDistance); std::vector > bondExceptions; std::vector bondDistances; bondExceptions.push_back(pair(0, 1)); bondDistances.push_back(C_HBondDistance); bondExceptions.push_back(pair(2, 1)); bondDistances.push_back(C_HBondDistance); bondExceptions.push_back(pair(3, 1)); bondDistances.push_back(C_HBondDistance); bondExceptions.push_back(pair(1, 4)); bondDistances.push_back(C_CBondDistance); bondExceptions.push_back(pair(5, 4)); bondDistances.push_back(C_HBondDistance); bondExceptions.push_back(pair(6, 4)); bondDistances.push_back(C_HBondDistance); bondExceptions.push_back(pair(7, 4)); bondDistances.push_back(C_HBondDistance); positions.resize(numParticles); positions[0] = Vec3(0.5480, 1.7661, 0.0000); positions[1] = Vec3(0.7286, 0.8978, 0.6468); positions[2] = Vec3(0.4974, 0.0000, 0.0588); positions[3] = Vec3(0.0000, 0.9459, 1.4666); positions[4] = Vec3(2.1421, 0.8746, 1.1615); positions[5] = Vec3(2.3239, 0.0050, 1.8065); positions[6] = Vec3(2.8705, 0.8295, 0.3416); positions[7] = Vec3(2.3722, 1.7711, 1.7518); } // dimer GB/VI test case static void buildDimer(GBVIForce* gbviForce, std::vector& positions) { const int numParticles = 2; double C_HBondDistance = 0.1097; double C_CBondDistance = 0.1504; double C_radius, C_gamma, C_charge, H_radius, H_gamma, H_charge; int AM1_BCC = 1; H_charge = -0.053; C_charge = -3.0*H_charge; H_charge = 0.0; C_charge = 0.0; if (AM1_BCC) { C_radius = 0.180; C_gamma = -0.2863; H_radius = 0.125; H_gamma = 0.2437; } else { C_radius = 0.215; C_gamma = -1.1087; H_radius = 0.150; H_gamma = 0.1237; } for (int i = 0; i < numParticles; i++) { gbviForce->addParticle(H_charge, H_radius, H_gamma); } gbviForce->setParticleParameters(1, C_charge, C_radius, C_gamma); gbviForce->addBond(0, 1, C_HBondDistance); std::vector > bondExceptions; std::vector bondDistances; bondExceptions.push_back(pair(0, 1)); bondDistances.push_back(C_HBondDistance); positions.resize(numParticles); positions[0] = Vec3(0.0, 0.0, 0.0); positions[1] = Vec3(0.15, 0.0, 0.0); } // monomer GB/VI test case static void buildMonomer(GBVIForce* gbviForce, std::vector& positions) { const int numParticles = 1; double H_radius, H_gamma, H_charge; H_charge = 1.0; H_radius = 0.125; H_gamma = 0.2437; for (int i = 0; i < numParticles; i++) { gbviForce->addParticle(H_charge, H_radius, H_gamma); } positions.resize(numParticles); positions[0] = Vec3(0.0, 0.0, 0.0); } // taken from gbviForceImpl class // computes the scaled radii based on covalent info and atomic radii static void findScaledRadii(GBVIForce& gbviForce, std::vector & scaledRadii) { int numberOfParticles = gbviForce.getNumParticles(); int numberOfBonds = gbviForce.getNumBonds(); // load 1-2 atom pairs along w/ bond distance using HarmonicBondForce & constraints // numberOfBonds < 1, indicating they were not set by the user if (numberOfBonds < 1 && numberOfParticles > 1) { (void) fprintf(stderr, "Warning: no covalent bonds set for GB/VI force!\n"); } std::vector< std::vector > bondIndices; bondIndices.resize(numberOfBonds); std::vector bondLengths; bondLengths.resize(numberOfBonds); scaledRadii.resize(numberOfParticles); for (int i = 0; i < numberOfParticles; i++) { double charge, radius, gamma; gbviForce.getParticleParameters(i, charge, radius, gamma); scaledRadii[i] = radius; } for (int i = 0; i < numberOfBonds; i++) { int particle1, particle2; double bondLength; gbviForce.getBondParameters(i, particle1, particle2, bondLength); if (particle1 < 0 || particle1 >= gbviForce.getNumParticles()) { std::stringstream msg; msg << "GBVISoftcoreForce: Illegal particle index: "; msg << particle1; throw OpenMMException(msg.str()); } if (particle2 < 0 || particle2 >= gbviForce.getNumParticles()) { std::stringstream msg; msg << "GBVISoftcoreForce: Illegal particle index: "; msg << particle2; throw OpenMMException(msg.str()); } if (bondLength < 0) { std::stringstream msg; msg << "GBVISoftcoreForce: negative bondlength: "; msg << bondLength; throw OpenMMException(msg.str()); } bondIndices[i].push_back(particle1); bondIndices[i].push_back(particle2); bondLengths[i] = bondLength; } // load 1-2 indicies for each atom std::vector > bonded12(numberOfParticles); for (int i = 0; i < (int) bondIndices.size(); ++i) { bonded12[bondIndices[i][0]].push_back(i); bonded12[bondIndices[i][1]].push_back(i); } int errors = 0; // compute scaled radii (Eq. 5 of Labute paper [JCC 29 p. 1693-1698 2008]) for (int j = 0; j < (int) bonded12.size(); ++j) { double charge; double gamma; double radiusJ; double scaledRadiusJ; gbviForce.getParticleParameters(j, charge, radiusJ, gamma); if ( bonded12[j].size() == 0) { if (numberOfParticles > 1) { (void) fprintf(stderr, "Warning GBVIForceImpl::findScaledRadii atom %d has no covalent bonds; using atomic radius=%.3f.\n", j, radiusJ); } scaledRadiusJ = radiusJ; // errors++; } else { double rJ2 = radiusJ*radiusJ; // loop over bonded neighbors of atom j, applying Eq. 5 in Labute scaledRadiusJ = 0.0; for (int i = 0; i < (int) bonded12[j].size(); ++i) { int index = bonded12[j][i]; int bondedAtomIndex = (j == bondIndices[index][0]) ? bondIndices[index][1] : bondIndices[index][0]; double radiusI; gbviForce.getParticleParameters(bondedAtomIndex, charge, radiusI, gamma); double rI2 = radiusI*radiusI; double a_ij = (radiusI - bondLengths[index]); a_ij *= a_ij; a_ij = (rJ2 - a_ij)/(2.0*bondLengths[index]); double a_ji = radiusJ - bondLengths[index]; a_ji *= a_ji; a_ji = (rI2 - a_ji)/(2.0*bondLengths[index]); scaledRadiusJ += a_ij*a_ij*(3.0*radiusI - a_ij) + a_ji*a_ji*(3.0*radiusJ - a_ji); } scaledRadiusJ = (radiusJ*radiusJ*radiusJ) - 0.125*scaledRadiusJ; if (scaledRadiusJ > 0.0) { scaledRadiusJ = 0.95*pow(scaledRadiusJ, (1.0/3.0)); } else { scaledRadiusJ = 0.0; } } //(void) fprintf(stderr, "scaledRadii %d %12.4f\n", j, scaledRadiusJ); scaledRadii[j] = scaledRadiusJ; } // abort if errors if (errors) { throw OpenMMException("GBVIForceImpl::findScaledRadii errors -- aborting"); } #if GBVIDebug (void) fprintf(stderr, " R q gamma scaled radii no. bnds\n"); double totalQ = 0.0; for (int i = 0; i < (int) scaledRadii.size(); i++) { double charge; double gamma; double radiusI; gbviForce.getParticleParameters(i, charge, radiusI, gamma); totalQ += charge; (void) fprintf(stderr, "%4d %14.5e %14.5e %14.5e %14.5e %d\n", i, radiusI, charge, gamma, scaledRadii[i], (int) bonded12[i].size()); } (void) fprintf(stderr, "Total charge=%e\n", totalQ); (void) fflush(stderr); #endif #undef GBVIDebug } // load parameters from gbviForce to customGbviForce // findScaledRadii() is called to calculate the scaled radii (S) // S is derived quantity in GBVIForce, not a parameter is the case here static void loadGbviParameters(GBVIForce* gbviForce, CustomGBForce* customGbviForce) { int numParticles = gbviForce->getNumParticles(); // charge, radius, scale factor, gamma vector params(4); std::vector scaledRadii; findScaledRadii(*gbviForce, scaledRadii); for (int ii = 0; ii < numParticles; ii++) { double charge, radius, gamma; gbviForce->getParticleParameters(ii, charge, radius, gamma); params[0] = charge; params[1] = radius; params[2] = scaledRadii[ii]; params[3] = gamma; customGbviForce->addParticle(params); } } void testGBVI(GBVIForce::NonbondedMethod gbviMethod, CustomGBForce::NonbondedMethod customGbviMethod, std::string molecule) { const int numMolecules = 1; const double boxSize = 10.0; ReferencePlatform platform; GBVIForce* gbvi = new GBVIForce(); std::vector positions; // select molecule if (molecule == "Monomer") { buildMonomer(gbvi, positions); } else if (molecule == "Dimer") { buildDimer(gbvi, positions); } else { buildEthane(gbvi, positions); } int numParticles = gbvi->getNumParticles(); System standardSystem; System customGbviSystem; for (int i = 0; i < numParticles; i++) { standardSystem.addParticle(1.0); customGbviSystem.addParticle(1.0); } standardSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize)); customGbviSystem.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0.0, 0.0), Vec3(0.0, boxSize, 0.0), Vec3(0.0, 0.0, boxSize)); gbvi->setCutoffDistance(2.0); // create customGbviForce GBVI force CustomGBForce* customGbviForce = createCustomGBVI(gbvi->getSolventDielectric(), gbvi->getSoluteDielectric()); customGbviForce->setCutoffDistance(2.0); // load parameters from gbvi to customGbviForce loadGbviParameters(gbvi, customGbviForce); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); vector velocities(numParticles); for (int ii = 0; ii < numParticles; ii++) { velocities[ii] = Vec3(genrand_real2(sfmt), genrand_real2(sfmt), genrand_real2(sfmt)); } gbvi->setNonbondedMethod(gbviMethod); customGbviForce->setNonbondedMethod(customGbviMethod); standardSystem.addForce(gbvi); customGbviSystem.addForce(customGbviForce); VerletIntegrator integrator1(0.01); VerletIntegrator integrator2(0.01); Context context1(standardSystem, integrator1, platform); context1.setPositions(positions); context1.setVelocities(velocities); State state1 = context1.getState(State::Forces | State::Energy); Context context2(customGbviSystem, integrator2, platform); context2.setPositions(positions); context2.setVelocities(velocities); State state2 = context2.getState(State::Forces | State::Energy); ASSERT_EQUAL_TOL(state1.getPotentialEnergy(), state2.getPotentialEnergy(), 1e-4); for (int i = 0; i < numParticles; i++) { ASSERT_EQUAL_VEC(state1.getForces()[i], state2.getForces()[i], 1e-4); } } int main() { try { testOBC(GBSAOBCForce::NoCutoff, CustomGBForce::NoCutoff); testOBC(GBSAOBCForce::CutoffNonPeriodic, CustomGBForce::CutoffNonPeriodic); testOBC(GBSAOBCForce::CutoffPeriodic, CustomGBForce::CutoffPeriodic); testMembrane(); testTabulatedFunction(); testMultipleChainRules(); testPositionDependence(); testExclusions(); // GBVI tests testGBVI(GBVIForce::NoCutoff, CustomGBForce::NoCutoff, "Monomer"); testGBVI(GBVIForce::NoCutoff, CustomGBForce::NoCutoff, "Dimer"); testGBVI(GBVIForce::NoCutoff, CustomGBForce::NoCutoff, "Ethane"); } catch(const exception& e) { cout << "exception: " << e.what() << endl; return 1; } cout << "Done" << endl; return 0; }