/* -------------------------------------------------------------------------- * * 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) 2008-2015 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. * * -------------------------------------------------------------------------- */ #include "openmm/internal/AssertionUtilities.h" #include "openmm/Context.h" #include "ReferencePlatform.h" #include "openmm/NonbondedForce.h" #include "openmm/System.h" #include "openmm/LangevinIntegrator.h" #include "openmm/VerletIntegrator.h" #include "openmm/internal/ContextImpl.h" #include "openmm/internal/NonbondedForceImpl.h" #include "SimTKOpenMMRealType.h" #include "sfmt/SFMT.h" #include #include using namespace OpenMM; using namespace std; void testEwaldExact() { // Use a NaCl crystal to compare the calculated and Madelung energies const int numParticles = 1000; const double cutoff = 1.0; const double boxSize = 2.82; const double ewaldTol = 1e-5; System system; for (int i = 0; i < numParticles/2; i++) system.addParticle(22.99); for (int i = 0; i < numParticles/2; i++) system.addParticle(35.45); VerletIntegrator integrator(0.01); NonbondedForce* nonbonded = new NonbondedForce(); for (int i = 0; i < numParticles/2; i++) nonbonded->addParticle(1.0, 1.0,0.0); for (int i = 0; i < numParticles/2; i++) nonbonded->addParticle(-1.0, 1.0,0.0); nonbonded->setNonbondedMethod(NonbondedForce::Ewald); nonbonded->setCutoffDistance(cutoff); system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0, 0), Vec3(0, boxSize, 0), Vec3(0, 0, boxSize)); nonbonded->setEwaldErrorTolerance(ewaldTol); system.addForce(nonbonded); Context context(system, integrator, platform); vector positions(numParticles); #include "nacl_crystal.dat" context.setPositions(positions); State state = context.getState(State::Forces | State::Energy); const vector& forces = state.getForces(); // The potential energy of an ion in a crystal is // E = - (M*e^2/ 4*pi*epsilon0*a0), // where // M : Madelung constant (dimensionless, for FCC cells such as NaCl it is 1.7476) // e : 1.6022 × 10−19 C // 4*pi*epsilon0: 1.112 × 10−10 C²/(J m) // a0 : 0.282 x 10-9 m (perfect cell) // // E is then the energy per pair of ions, so for our case // E has to be divided by 2 (per ion), multiplied by N(avogadro), multiplied by number of particles, and divided by 1000 for kJ double exactEnergy = - (1.7476 * 1.6022e-19 * 1.6022e-19 * 6.02214e+23 * numParticles) / (1.112e-10 * 0.282e-9 * 2 * 1000); //cout << "exact\t\t: " << exactEnergy << endl; //cout << "calc\t\t: " << state.getPotentialEnergy() << endl; ASSERT_EQUAL_TOL(exactEnergy, state.getPotentialEnergy(), 100*ewaldTol); } void testEwaldPME(bool includeExceptions) { // Use amorphous NaCl system for the tests const int numParticles = 894; const double cutoff = 1.2; const double boxSize = 3.00646; double tol = 1e-5; ReferencePlatform reference; System system; NonbondedForce* nonbonded = new NonbondedForce(); nonbonded->setNonbondedMethod(NonbondedForce::Ewald); nonbonded->setCutoffDistance(cutoff); nonbonded->setEwaldErrorTolerance(tol); for (int i = 0; i < numParticles/2; i++) system.addParticle(22.99); for (int i = 0; i < numParticles/2; i++) system.addParticle(35.45); for (int i = 0; i < numParticles/2; i++) nonbonded->addParticle(1.0, 1.0,0.0); for (int i = 0; i < numParticles/2; i++) nonbonded->addParticle(-1.0, 1.0,0.0); system.setDefaultPeriodicBoxVectors(Vec3(boxSize, 0, 0), Vec3(0, boxSize, 0), Vec3(0, 0, boxSize)); system.addForce(nonbonded); vector positions(numParticles); #include "nacl_amorph.dat" if (includeExceptions) { // Add some exclusions. for (int i = 0; i < numParticles-1; i++) { Vec3 delta = positions[i]-positions[i+1]; if (sqrt(delta.dot(delta)) < 0.5*cutoff) nonbonded->addException(i, i+1, i%2 == 0 ? 0.0 : 0.5, 1.0, 0.0); } } // (1) Check whether this matches the Reference platform when using Ewald Method VerletIntegrator integrator1(0.01); VerletIntegrator integrator2(0.01); Context context(system, integrator1, platform); Context referenceContext(system, integrator2, reference); context.setPositions(positions); referenceContext.setPositions(positions); State state = context.getState(State::Forces | State::Energy); State referenceState = referenceContext.getState(State::Forces | State::Energy); tol = 1e-2; for (int i = 0; i < numParticles; i++) { ASSERT_EQUAL_VEC(referenceState.getForces()[i], state.getForces()[i], tol); } tol = 1e-5; ASSERT_EQUAL_TOL(referenceState.getPotentialEnergy(), state.getPotentialEnergy(), tol); if (!includeExceptions) ASSERT_EQUAL_TOL(-3.82047e+05, state.getPotentialEnergy(), 1e-5); // Value from Gromacs // (2) Check whether Ewald method is self-consistent double norm = 0.0; for (int i = 0; i < numParticles; ++i) { Vec3 f = state.getForces()[i]; norm += f[0]*f[0] + f[1]*f[1] + f[2]*f[2]; } norm = std::sqrt(norm); const double delta = 5e-3; double step = delta/norm; for (int i = 0; i < numParticles; ++i) { Vec3 p = positions[i]; Vec3 f = state.getForces()[i]; positions[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step); } VerletIntegrator integrator3(0.01); Context context2(system, integrator3, platform); context2.setPositions(positions); tol = 1e-2; State state2 = context2.getState(State::Energy); ASSERT_EQUAL_TOL(norm, (state2.getPotentialEnergy()-state.getPotentialEnergy())/delta, tol) // (3) Check whether this matches the Reference platform when using PME nonbonded->setNonbondedMethod(NonbondedForce::PME); context.reinitialize(); referenceContext.reinitialize(); context.setPositions(positions); referenceContext.setPositions(positions); state = context.getState(State::Forces | State::Energy); referenceState = referenceContext.getState(State::Forces | State::Energy); tol = 1e-2; for (int i = 0; i < numParticles; i++) { ASSERT_EQUAL_VEC(referenceState.getForces()[i], state.getForces()[i], tol); } tol = 1e-5; ASSERT_EQUAL_TOL(referenceState.getPotentialEnergy(), state.getPotentialEnergy(), tol); if (!includeExceptions) ASSERT_EQUAL_TOL(-3.82047e+05, state.getPotentialEnergy(), 1e-3); // Value from Gromacs // (4) Check whether PME method is self-consistent norm = 0.0; for (int i = 0; i < numParticles; ++i) { Vec3 f = state.getForces()[i]; norm += f[0]*f[0] + f[1]*f[1] + f[2]*f[2]; } norm = std::sqrt(norm); step = delta/norm; for (int i = 0; i < numParticles; ++i) { Vec3 p = positions[i]; Vec3 f = state.getForces()[i]; positions[i] = Vec3(p[0]-f[0]*step, p[1]-f[1]*step, p[2]-f[2]*step); } VerletIntegrator integrator4(0.01); Context context3(system, integrator4, platform); context3.setPositions(positions); tol = 1e-2; State state3 = context3.getState(State::Energy); ASSERT_EQUAL_TOL(norm, (state3.getPotentialEnergy()-state.getPotentialEnergy())/delta, tol) } void testTriclinic() { // Create a triclinic box containing eight particles. System system; system.setDefaultPeriodicBoxVectors(Vec3(2.5, 0, 0), Vec3(0.5, 3.0, 0), Vec3(0.7, 0.9, 3.5)); for (int i = 0; i < 8; i++) system.addParticle(1.0); NonbondedForce* force = new NonbondedForce(); system.addForce(force); force->setNonbondedMethod(NonbondedForce::PME); force->setCutoffDistance(1.0); force->setPMEParameters(3.45891, 32, 40, 48); for (int i = 0; i < 4; i++) force->addParticle(-1, 0.440104, 0.4184); // Cl parameters for (int i = 0; i < 4; i++) force->addParticle(1, 0.332840, 0.0115897); // Na parameters vector positions(8); positions[0] = Vec3(1.744, 2.788, 3.162); positions[1] = Vec3(1.048, 0.762, 2.340); positions[2] = Vec3(2.489, 1.570, 2.817); positions[3] = Vec3(1.027, 1.893, 3.271); positions[4] = Vec3(0.937, 0.825, 0.009); positions[5] = Vec3(2.290, 1.887, 3.352); positions[6] = Vec3(1.266, 1.111, 2.894); positions[7] = Vec3(0.933, 1.862, 3.490); // Compute the forces and energy. VerletIntegrator integ(0.001); Context context(system, integ, platform); context.setPositions(positions); State state = context.getState(State::Forces | State::Energy); // Compare them to values computed by Gromacs. double expectedEnergy = -963.370; vector expectedForce(8); expectedForce[0] = Vec3(4.25253e+01, -1.23503e+02, 1.22139e+02); expectedForce[1] = Vec3(9.74752e+01, 1.68213e+02, 1.93169e+02); expectedForce[2] = Vec3(-1.50348e+02, 1.29165e+02, 3.70435e+02); expectedForce[3] = Vec3(9.18644e+02, -3.52571e+00, -1.34772e+03); expectedForce[4] = Vec3(-1.61193e+02, 9.01528e+01, -7.12904e+01); expectedForce[5] = Vec3(2.82630e+02, 2.78029e+01, -3.72864e+02); expectedForce[6] = Vec3(-1.47454e+02, -2.14448e+02, -3.55789e+02); expectedForce[7] = Vec3(-8.82195e+02, -7.39132e+01, 1.46202e+03); for (int i = 0; i < 8; i++) { ASSERT_EQUAL_VEC(expectedForce[i], state.getForces()[i], 1e-4); } ASSERT_EQUAL_TOL(expectedEnergy, state.getPotentialEnergy(), 1e-4); } void testTriclinic2() { // Create a triclinic box containing a large molecule made up of randomly positioned particles and make sure the // results match the reference platform. if (platform.getName() == "Reference") return; const int numParticles = 1000; System system; system.setDefaultPeriodicBoxVectors(Vec3(3.2, 0, 0), Vec3(-1.1, 3.1, 0), Vec3(-1.1, -1.5, 2.7)); vector positions(numParticles); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); NonbondedForce* force = new NonbondedForce(); for (int i = 0; i < numParticles; i++) { system.addParticle(1.0); force->addParticle(i%2 == 0 ? -1.0 : 1.0, 1.0, 0.0); positions[i] = Vec3(10*genrand_real2(sfmt)-2, 10*genrand_real2(sfmt)-2, 10*genrand_real2(sfmt)-2); if (i > 0) { Vec3 delta = positions[i-1]-positions[i]; system.addConstraint(i-1, i, sqrt(delta.dot(delta))); } } system.addForce(force); force->setNonbondedMethod(NonbondedForce::PME); force->setCutoffDistance(1.0); force->setReciprocalSpaceForceGroup(1); force->setPMEParameters(2.62826, 27, 25, 24); // Compute the forces and energy. VerletIntegrator integ1(0.001); Context context1(system, integ1, platform); context1.setPositions(positions); VerletIntegrator integ2(0.001); Context context2(system, integ2, Platform::getPlatformByName("Reference")); context2.setPositions(positions); State state1 = context1.getState(State::Forces | State::Energy, false, 2); State state2 = context2.getState(State::Forces | State::Energy, false, 2); ASSERT_EQUAL_TOL(state2.getPotentialEnergy(), state1.getPotentialEnergy(), 1e-4); for (int i = 0; i < numParticles; i++) ASSERT_EQUAL_VEC(state2.getForces()[i], state1.getForces()[i], 1e-4); } void testErrorTolerance(NonbondedForce::NonbondedMethod method) { // Create a cloud of random point charges. const int numParticles = 51; const double boxWidth = 5.0; System system; system.setDefaultPeriodicBoxVectors(Vec3(boxWidth, 0, 0), Vec3(0, boxWidth, 0), Vec3(0, 0, boxWidth)); NonbondedForce* force = new NonbondedForce(); system.addForce(force); vector positions(numParticles); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); for (int i = 0; i < numParticles; i++) { system.addParticle(1.0); force->addParticle(-1.0+i*2.0/(numParticles-1), 1.0, 0.0); positions[i] = Vec3(boxWidth*genrand_real2(sfmt), boxWidth*genrand_real2(sfmt), boxWidth*genrand_real2(sfmt)); } force->setNonbondedMethod(method); // For various values of the cutoff and error tolerance, see if the actual error is reasonable. for (double cutoff = 1.0; cutoff < boxWidth/2; cutoff *= 1.2) { force->setCutoffDistance(cutoff); vector refForces; double norm = 0.0; for (double tol = 5e-5; tol < 1e-3; tol *= 2.0) { force->setEwaldErrorTolerance(tol); VerletIntegrator integrator(0.01); Context context(system, integrator, platform); context.setPositions(positions); State state = context.getState(State::Forces); if (refForces.size() == 0) { refForces = state.getForces(); for (int i = 0; i < numParticles; i++) norm += refForces[i].dot(refForces[i]); norm = sqrt(norm); } else { double diff = 0.0; for (int i = 0; i < numParticles; i++) { Vec3 delta = refForces[i]-state.getForces()[i]; diff += delta.dot(delta); } diff = sqrt(diff)/norm; ASSERT(diff < 2*tol); } if (method == NonbondedForce::PME) { // See if the PME parameters were calculated correctly. double expectedAlpha, actualAlpha; int expectedSize[3], actualSize[3]; NonbondedForceImpl::calcPMEParameters(system, *force, expectedAlpha, expectedSize[0], expectedSize[1], expectedSize[2], false); force->getPMEParametersInContext(context, actualAlpha, actualSize[0], actualSize[1], actualSize[2]); ASSERT_EQUAL_TOL(expectedAlpha, actualAlpha, 1e-5); for (int i = 0; i < 3; i++) { ASSERT(actualSize[i] >= expectedSize[i]); ASSERT(actualSize[i] < expectedSize[i]+10); } } } } } void testPMEParameters() { // Create a cloud of random point charges. const int numParticles = 51; const double boxWidth = 4.7; System system; system.setDefaultPeriodicBoxVectors(Vec3(boxWidth, 0, 0), Vec3(0, boxWidth, 0), Vec3(0, 0, boxWidth)); NonbondedForce* force = new NonbondedForce(); system.addForce(force); vector positions(numParticles); OpenMM_SFMT::SFMT sfmt; init_gen_rand(0, sfmt); for (int i = 0; i < numParticles; i++) { system.addParticle(1.0); force->addParticle(-1.0+i*2.0/(numParticles-1), 1.0, 0.0); positions[i] = Vec3(boxWidth*genrand_real2(sfmt), boxWidth*genrand_real2(sfmt), boxWidth*genrand_real2(sfmt)); } force->setNonbondedMethod(NonbondedForce::PME); // Compute the energy with an error tolerance of 1e-3. force->setEwaldErrorTolerance(1e-3); VerletIntegrator integrator1(0.01); Context context1(system, integrator1, platform); context1.setPositions(positions); double energy1 = context1.getState(State::Energy).getPotentialEnergy(); // Try again with an error tolerance of 1e-4. force->setEwaldErrorTolerance(1e-4); VerletIntegrator integrator2(0.01); Context context2(system, integrator2, platform); context2.setPositions(positions); double energy2 = context2.getState(State::Energy).getPotentialEnergy(); // Now explicitly set the parameters. These should match the values that were // used for tolerance 1e-3. force->setPMEParameters(2.49291157051793, 32, 32, 32); VerletIntegrator integrator3(0.01); Context context3(system, integrator3, platform); context3.setPositions(positions); double energy3 = context3.getState(State::Energy).getPotentialEnergy(); ASSERT_EQUAL_TOL(energy1, energy3, 1e-6); ASSERT(fabs((energy1-energy2)/energy1) > 1e-5); } void runPlatformTests(); int main(int argc, char* argv[]) { try { initializeTests(argc, argv); testEwaldExact(); testEwaldPME(false); testEwaldPME(true); testTriclinic(); testTriclinic2(); testErrorTolerance(NonbondedForce::Ewald); testErrorTolerance(NonbondedForce::PME); testPMEParameters(); runPlatformTests(); } catch(const exception& e) { cout << "exception: " << e.what() << endl; return 1; } cout << "Done" << endl; return 0; }